EP3759247A1

EP3759247A1 - Method for primer extension reaction with improved specificity

Info

Publication number: EP3759247A1
Application number: EP19711506.6A
Authority: EP
Inventors: Dmitry Cherkasov; Christian GRUNWALD
Original assignee: AGCT GmbH
Current assignee: AGCT GmbH
Priority date: 2018-02-26
Filing date: 2019-02-26
Publication date: 2021-01-06
Also published as: WO2019162529A1; US20210071243A1

Abstract

The invention relates to a method for extending a primer oligonucleotide having improved specificity using a particular primer oligonucleotide and a controller nucleotide sequence, wherein the controller oligonucleotide enables a strand opening in a double strand of the extension product and die in a sequence-specific manner. The invention furthermore relates to a corresponding kit for carrying out the method according to the invention.

Description

Method for primer extension reaction with improved specificity

The present invention relates to a method for the template-dependent primer extension reaction by means of a template-dependent polymerase. In the method, primer extension products can be prepared which can be used in an amplification of nucleic acids. The method may thus help to improve the specificity of analyzes involving a primer extension step.

The present application claims priority from the following applications: European Patent Applications EP18158720.5 dated 26.02.18; EP18195189.8 from 18.09.2018; German Patent Application 10 2018 001639.1 dated 28.02.2018; These and all other patent documents mentioned herein are to be incorporated by reference into the present specification (incorporation by reference).

background

The primer extension reaction plays a role in many genetic analyzes, e.g. in amplification methods, such as PCR, or in individual steps of the analyzes. An enzymatic primer extension is carried out by means of a polymerase, whereby a synthesized strand is formed. In many processes, this strand is detached from the template by various means, independently of the sequence, and used in further process steps. Such agents include, for example, temperature or denaturing agents such as alkalis or formamide. Furthermore, strands can be separated by enzymes using chemical energy sources such as dNTP or ATP. These include helicases or polymerases with strand-displacing action. Such separations are predominantly sequence-unspecific.

Many reactions in genetic analyzes require single-stranded or double-stranded, complementary states of nucleic acid chains or nucleic acid chain segments to achieve certain effects. Switching between the single-stranded form and the double-stranded form is often required to turn on / off a reaction or to provide functionality. The binding of certain elements of the reactions (eg, primer / template or probe / template, etc.) depend on the generation of a permanent or transient sequence-specific binding of components to each other. This bonding occurs in many cases with formation of hydrogen bonds under complementary strands (in Watson-Crick base pairing). In this case, a strand at a particular position at a specific time can only be accompanied by a bond with another strand. A third strand is thus excluded from the interaction at this time. Thus, the availability of free complementary positions may play a role in potential interactions with other reaction components in many processes. Furthermore, the frequency and duration of binding of reactants to each other via complementary positions may be one Play role for the speed or yield of a certain reaction step. Many reactions in the field of molecular analysis are based on the creation of more or less stable bonds between individual reaction components. The effects achieved can have an influence on the specificity of reactions.

Primer extension is used in many genetic analyzes. The result of a correct priming (formation of a primer-template complex) as well as the continuation of the template-dependent enzymatic synthesis by means of a polymerase plays a role. With the preparation of the product of a sequence-specific primer extension reaction (primer extension product), the synthesis phase is complete. Upon completion of primer extension, the primer extension product can be detached from the template and used in other procedures.

In each of these steps, errors or deviations may take place which may influence the specificity of the respective methods and ultimately also impose certain limits on the applicability of respective methods. Many examples are known, e.g. incorrect priming, polymerase-related defects, defective binding of probes, etc.

Genetic analysis methods must often differentiate among several variants of a known sequence (e.g., allele-specific detection methods or mutation analysis in the presence of wild-type sequences). The presence of multiple sequences in the same reaction mixture often leads to interference (unwanted interactions or parallel side reactions, etc.) can occur between the sequences. Such interferences can arise at different times of a process, from the production of the first copies to detection. In general, interference between very similar sequences can lead to misinterpretation of results. High specificity in such processes therefore plays a major role.

Especially with minor genetic differences, such as single nucleotide changes (SNV) and short insertions / deletions (2-10 nucleotides), it would be advantageous if the specificity of primer extension-dependent methods or procedures can be improved.

In this case, both the synthesis of the primer extension product per se and the provision of the synthesized primer extension product can be improved to a further use.

The primer extension reaction is currently optimized in most cases by adjusting the primer binding (eg, by using optimal reaction temperatures, buffer conditions and complementarity of the primers to a primer binding site). Some tools have been developed to improve primer binding. These are limited only to the improvement of primer binding and do not go beyond the primer length. Using a polymerase with 3 ^' exonuclease activity (polymerases with proofreading) one can achieve a further improvement in the quality of the synthesis result. The 3 ^' end of the synthesized strand is checked by polymerase-associated exonuclease.

Except for these phases of primer extension reaction (priming and proofreading by the polymerase), in most cases the primer extension reaction is not further evaluated for quality.

In particular, for trace analysis in the presence of strong interference (e.g., detection of ctDNA in liquid biopsy methods), current methods are reaching their limits, making it difficult to increase the specificity of analyzes.

It is therefore an object of the present invention to provide means and methods for improving specificity in genetic analysis methods which include or presuppose a primer extension reaction.

It is another object of the present invention to provide methods and components for improving specificity, particularly in methods involving enzymatic, template-dependent synthesis in a primer extension reaction.

It is a further object of the present invention to provide methods and components for improving specificity in methods involving separation of a synthesized nucleic acid strand from its template.

It is more particularly an object of the present invention to provide methods and components for sequence-specific or selective separation of a synthesized nucleic acid strand from its template in a template-dependent primer extension reaction, especially in the coexistence of very similar template sequences.

These objects are fulfilled by the subject matters of the independent claims. Further advantageous embodiments of the invention are set forth in the dependent claims and the following description.

Summary of the invention

According to a first aspect, a method for extension of a primer oligonucleotide is provided. The method of specifically extending a primer oligonucleotide comprises the steps (Figures 1, 2):

a) providing a nucleic acid chain comprising a target sequence

(Matrix strand) (M1)

b) hybridizing a primer oligonucleotide (P1 .1) to a segment comprising a portion of the target sequence (primer binding site) of the provided

Nucleic acid chain (M1), wherein the primer oligonucleotide (P1 .1) comprises the following ranges: a first region, essentially sequence-specific, to a

complementary segment (primer binding site) comprising a portion of the target sequence can bind within a provided nucleic acid chain (M1),

a second region (overhang) connected to the 5 'end of the first region or connected via a linker, which second region can be bound by a controller oligonucleotide (C1 .1); c) extension of the primer oligonucleotide (P.1.1) by a template-dependent polymerase to give a primer extension product (primer extension product, P1 .1 -Ext) which has a synthesized region in addition to the primer oligonucleotide (P1.1) which is substantially complementary to a nucleic acid chain comprising a target sequence (M1), wherein the primer extension product (P1 .1 -Ext) and the nucleic acid chain (M1) form a double strand under reaction conditions;

d) binding of a controller oligonucleotide (C1.1) to the primer extension product (P1.1-Tex), wherein the controller oligonucleotide (C1.1) comprises the following ranges:

a first region that can bind to the second region (overhang) of the first primer extension product (P1 .1 -Ext),

a second region complementary to the first region of the primer oligonucleotide (P1 .1), and

a third region which is substantially complementary to at least a portion of the synthesized region of the primer extension product (P1 1-Ext); and

wherein the controller oligonucleotide (C1 .1) does not serve as a template for a primer extension of the primer oligonucleotide (P1 .1) and the controller oligonucleotide (C1 .1) with its first, second and third regions to the primer extension product (P1 1 -Ext) with displacement of complementary segments of the nucleic acid chain (M1) can bind.

The second region of the primer oligonucleotide is in particular a polynucleotide tail.

The term "essentially sequence-specific" in the context of the invention means in particular that the mutually complementary regions of the primer oligonucleotide and the nucleic acid to be amplified have not more than 5, 4, 3, 2, or 1 mismatches. The term "substantially complementary" in the sense of the invention means in particular that the mutually complementary regions of nucleic acids have not more than 5, 4, 3, 2, or 1 mismatches.

The above steps can be carried out in one approach or in separate approaches. If the operations are to be carried out in one batch, they may be treated under the same conditions, e.g. isothermal, or under different conditions, e.g. as thermocycling. In certain embodiments, primer oligonucleotides and controller oligonucleotide are present at the beginning of the reaction. However, sequential addition of individual reagents is also possible.

Also, combinations with other amplification methods are possible, e.g. with PCR, wherein the PCR, for example, first carried out for 1 to 10 cycles and then further, for example, under isothermal conditions.

In certain embodiments of the method according to the invention, it is provided that the first region of the primer oligonucleotide is completely sequence-specific, i. in particular without mismatches, to which the nucleic acid to be amplified can bind.

In certain embodiments of the method according to the invention, it is provided that the second region (overhang) of the primer oligonucleotide remains essentially uncoupled from a polymerase used for the primer extension under the chosen reaction conditions.

In certain embodiments of the method according to the invention (FIGS. 3, 4) it is provided that the method further comprises the following step: hybridizing a block oligonucleotide to a region of the nucleic acid chain comprising a target sequence

(Template strand) (M1) located in the 5 ^' direction of the region bound by the first region (primer binding site) of the primer oligonucleotide, the block oligonucleotide being designed to inhibit extension of the primer oligonucleotide at the bound region to block.

In certain embodiments of the invention, it is provided that the block oligonucleotide is characterized by a length of about 15 nucleotides to about 60 nucleotides, and optionally modifications (eg PTO or LNA (locked nucleic acid, 2Ό, 4'C methylenverbrückte ribosyl residues in the polymer) or PNA (peptide nucleic acid, N- (2-aminoethyl) glycine backbone).

In certain embodiments of the method according to the invention, it is provided that the third region of the controller oligonucleotide is substantially complementary to the part of the synthesized region of the primer extension product which directly adjoins the primer oligonucleotide portion of the primer extension product. Advantageously, this improves the sequence-specific displacement of the nucleic acid to be amplified. In certain embodiments of the method of the invention, the portion of the synthesized region that is substantially complementary to the third region of the controller nucleotide has a length in the range of 5 nucleotides to 50 nucleotides.

In certain embodiments of the method according to the invention, the part of the synthesized region which is substantially complementary to the third region of the controller nucleotide has a length in the range from 3 nucleotides to 70 nucleotides, in particular 5 nucleotides to 50 nucleotides, in particular 5 nucleotides to 50 Nucleotides, in particular 5 nucleotides to 30 nucleotides, in particular 5 nucleotides to 20 nucleotides.

In certain embodiments of the method of the invention, it is contemplated that the method further comprises the step of: hybridizing a probe to a portion of the primer extension product that is not bound by the controller oligonucleotide.

In certain embodiments of the method according to the invention, it is provided that the method is carried out essentially isothermally.

The term "substantially isothermal" in the sense of the present description means in particular that the reaction temperature is carried out within a temperature range of 10 K temperature difference between the highest and the lowest temperature.

In certain embodiments of the method according to the invention, it is provided that the target sequence of a nucleic acid has a length in the range from about 20 nucleotides to about 300 nucleotides.

In certain embodiments of the method according to the invention it is provided that the primer oligonucleotide has a length in the range of 15 nucleotides to 100 nucleotides.

In certain embodiments of the method according to the invention, it is provided that the controller oligonucleotide has a length in the range from 20 nucleotides to 100 nucleotides.

In certain embodiments of the process according to the invention, it is provided that the chosen reaction conditions comprise a reaction temperature in the range from 50 ° C to 70 ° C.

In certain embodiments of the method according to the invention, it is provided that the primer oligonucleotide has one or more modifications in the second region, in particular immediately following the first region of the primer oligonucleotide (FIG. 26), which stops the polymerase used at the second region , Advantageously, only the first region of the primer oligonucleotide is optionally amplified in later process steps.

This can preferably be achieved by using nucleotide modifications which, although capable of complementary binding to the primer extension product, are not accepted by the polymerase as a template. Examples of such nucleotide Modifications provide nucleotide compounds with modified phosphate-sugar backbone units, for example 2 ^{'-0-alkyl-RNA} modifications (eg ^2' OMe), LNA modifications or morpholino modifications. The presence of such modifications in a strand prevents a DNA dependent polymerase reading such a strand. The number of such modifications may be different, usually few modifications (between 1 and 20) may be sufficient to prevent a polymerase from reading such a strand. Such nucleotide modifications can be used, for example, at or around the binding site of the primer oligonucleotide to the controller oligonucleotide and / or as constituents of the second region of the primer oligonucleotide.

Thanks to the use of such modifications, there is a local inhibition of the polymerase function, so that certain segments of the structures used can not be copied by the polymerase and remain predominantly single-stranded. In this single-stranded form they can bind further reaction components and thus perform their function.

The second primer region is uncopiable only in one of several alternative embodiments. This embodiment allows, for example, the use of identical primers in the primer extension and in an optionally subsequent amplification.

Only when short matrices are used, should this second primer region be uncopiable, since the 3 ^' end of such short matrices can be immediately before the second region and thus prime a synthesis (template strand is thus also extended, see FIGS. 16-18: the 3 ^' end of a template may be just before the 2nd range). To prevent copying the second area of the primer, primers must have a "protection". This may consist of a "first blocking unit" before the second area or the entire second area consists of modifications that are uncopiable.

However, this second primer region can be quite copiable when using long matrices (see FIGS. 1-3), since the 3 ^' end of the template is not immediately in front of the second region and thus can not prime a synthesis. In this embodiment, the primer extension primer can not be used as an amplification primer.

Furthermore, it is important that the second region is not allowed to bind to the template and thus is present for the interaction with the controller single-stranded.

Some aspects of the invention are summarized below:

1 . The method of specifically extending a primer oligonucleotide, comprising the steps of:

a) providing a nucleic acid chain comprising a target sequence

(Matrix strand) (M1) b) hybridizing a primer oligonucleotide (P1 .1) to a segment comprising a portion of the target sequence (primer binding site) of the provided

Nucleic acid chain (M1), wherein the primer oligonucleotide (P1 .1) comprises the following ranges:

a first region, substantially sequence-specific, capable of binding to a complementary segment (primer binding site) comprising a portion of the target sequence within a provided nucleic acid sequence (M1),

a second region (overhang) connected to the 5 'end of the first region or connected via a linker, which second region can be bound by a controller oligonucleotide (C1 .1); c) extension of the primer oligonucleotide (P.1.1) by a template-dependent polymerase to give a primer extension product (primer extension product, P1 .1 -Ext) which has a synthesized region in addition to the primer oligonucleotide (P1.1) which is substantially complementary to the nucleic acid chain comprising a target sequence (M1), wherein the primer extension product (P1 .1 -Ext) and the nucleic acid chain (M1) form a double strand under reaction conditions;

In certain embodiments, a target sequence comprises a polymorphic locus comprising at least one nucleotide position comprising at least two characteristic sequence variants in a target sequence. In certain embodiments, a target sequence comprises a polymorphic locus comprising at least two nucleotide positions comprising at least two characteristic sequence variants in a target sequence.

In certain embodiments, a target sequence comprises a polymorphic locus comprising a length between one nucleotide to 100 nucleotides, such locus comprising at least two characteristic sequence variants of a target sequence.

In certain embodiments in step (1), at least two template strands are provided, each template strand comprising a variant of a target sequence having a specific and characteristic sequence variant of a polymorphic locus.

In certain embodiments, at least two template strands are provided in step (1), each template strand comprising its own target sequence and these

Target sequences of the first and another start nucleic acid chain are different.

2. The method according to no. 1, characterized in that the second region (overhang) of the primer oligonucleotide (P1 .1) of a used for the primer extension

Polymerase remains essentially unkopiert under the selected reaction conditions.

3. Method according to one of the preceding numbers, wherein the primer extension of the hybridized to the nucleic acid chain (M 1) primer (P1 .1) by a template-dependent polymerase in the presence of the controller oligonucleotide (C 1 .1) in the same

Reaction approach takes place.

4. Method according to one of the preceding numbers, wherein the primer extension product formed is separated from the nucleic acid chain (M 1) with the assistance of the controller oligonucleotide (C1 .1).

5. The method according to any one of the preceding numbers, wherein steps (b) to (d) are repeated at least once.

6. The method according to any one of the preceding numbers, characterized in that the method further comprises the following step:

Hybridizing a block oligonucleotide (B1 .1) to a sequence segment of the nucleic acid chain (M1) that is in the 5 ^' direction of the segment (primer binding site) bound by the first region of the primer oligonucleotide (P1 .1), wherein the block oligonucleotide (B1 .1) is designed to prevent the synthesis of the primer extension product (P1 1 -Ext) on the bound segment, thereby reducing the length of the

is limited to the synthesized region of the primer extension product.

7. The method of claim 6, wherein the step of hybridizing a block oligonucleotide (B1 .1) occurs prior to the step of primer extension. 8. Method according to one of the preceding numbers, characterized in that the third region of the controller oligonucleotide (C1.1) is substantially complementary to the part of the synthesized region of the primer extension product and is directly connected to the primer oligonucleotide portion of the primer. Extension product (P1 1-Ext) connects.

9. The method according to any one of the preceding numbers, characterized in that the method is carried out substantially isothermally.

10. The method according to any one of the preceding numbers, characterized in that the target sequence of the nucleic acid chain (M1) comprises a length of 20 nucleotides to 200 nucleotides.

1 1. Method according to one of the preceding numbers, characterized in that the primer oligonucleotide (P1 .1) has a length in the range of 15 nucleotides to 100 nucleotides.

12. The method according to any one of the preceding numbers, characterized in that the controller oligonucleotide (C1 .1) has a length in the range of 20 nucleotides to 100 nucleotides.

13. The method according to any one of the preceding numbers, characterized in that the selected reaction conditions include a reaction temperature in the range of 25 ° C to 80 ° C.

14. The method according to any one of the preceding numbers, characterized in that the primer oligonucleotide (P1 .1) in the second region has a modification or several modifications, in particular immediately after the first region of the primer oligonucleotide (P1 .1), which prevents the polymerase used from copying the second area.

15. kit for carrying out a method according to one of the preceding numbers,

full:

a primer oligonucleotide (P1 .1) comprising the following ranges:

o a first region that can bind substantially sequence-specifically to a complementary segment (primer binding site) within a provided nucleic acid sequence (M1) comprising a target sequence,

o a second region (overhang) connected to the 5 'end of the first region or connected via a linker, which second region can be bound by a controller oligonucleotide (C1 .1);

wherein the first primer oligonucleotide (P1 .1), when hybridized to the complementary segment of the target sequence, is replaced by a template-dependent polymerase can be extended to a primer extension product (P1 1-Ext) comprising a synthesized region in addition to the primer oligonucleotide (P1 .1);

a controller oligonucleotide (C1 .1) comprising the following ranges:

o a first region that can bind to the second region (overhang) of the first primer extension product (P1 .1 -Ext), o a second region that is complementary to the first region of the primer oligonucleotide (P1 .1), and

o a third region which is substantially complementary to at least part of the synthesized region of the primer extension product (P1 1-Ext); and

wherein the controller oligonucleotide (C1 .1) is not used as a template for a

Primer extension of the primer oligonucleotide (P1 .1), and the controller oligonucleotide (C1 .1) with its first, second and third region to the primer extension product (P1 1 -Ext) with displacement of complementary segments of the nucleic acid chain (M1 ) can bind; and optional

a block oligonucleotide (B1 .1) that can bind to a segment of the nucleic acid chain (M1) that is in the 5 ^' direction from the segment (primer binding site) that is located in the first region of the primer oligonucleotide (P1 .1) wherein the block oligonucleotide (B1 .1) is adapted to block the synthesis of the primer extension product (P1 1 -Ext) at the bound region and thereby to limit the length of the synthesized region of the primer extension product.

Kit according to No. 15, characterized in that the second region of the primer oligonucleotide (P1 .1) remains substantially uncoated by a polymerase used for the primer extension under the chosen reaction conditions.

Use of a kit according to No. 15 or 16 for carrying out a method according to one of the No. 1 to 14.

A method for the specific extension of a primer oligonucleotide, comprising the steps:

a) providing at least two nucleic acid chains comprising variants of a target sequence (template strand) (M 1 .1 and M 1 .2), wherein provided

nucleic acid chains

comprise at least one unitary segment which is specific for M 1 .1 and M 1 .2 and is identical for M 1 .1 and M 1 .2, and at least one characteristic segment specific for each nucleic acid chain

b) providing a first primer oligonucleotide (P1 .1) attached to the

unitary segment of at least two provided nucleic acid chains can complementarily bind, wherein the primer oligonucleotide

a first region, substantially sequence-specific, capable of binding to a complementary segment (primer binding site) comprising a portion of the target sequence within a unitary segment of nucleic acid chains provided (M 1 .1 and M 1 .2), a second region (overhang) which connects to the 5 'end of the first region or is linked via a linker, which second region can be bound by a controller oligonucleotide (C 1 .1 or C 1 .2);

being the binding to the unitary segment of the provided

Nucleic acid chains carried out so that each characteristic and specific segment in the 5 ^' direction of the nucleic acid chain provided by the hybridized primer (P 1 .1);

c) providing at least two controller oligonucleotides (C1 .1 and C1 .2), each comprising the following ranges:

a first region which can bind to the second region of the primer oligonucleotide (P1 .1) (overhang), and

a third region which is complementary to at least part of the synthesized region of at least one expected first primer extension product (P1 .1 -Ext or P1 2-Ext); and wherein the controller oligonucleotides (C1 .1 and C1 .2) do not serve as template for primer extension of the primer oligonucleotide (P1 .1), and the controller oligonucleotide (C1 .1) with its first, second and third regions to the complementary segments of the primer extension product (P1 1 -Ext) with displacement of the

Nucleic acid chain (M 1 .1) can bind and

the controller oligonucleotide (C1 .2) with its first, second and third region to the complementary segments of the primer Extension product (P1 2-Ext) with displacement of

Nucleic acid chain (M 1 .2) can bind.

d) hybridizing a primer oligonucleotide (P1 .1) to a segment comprising a portion of the target sequence (primer binding site) of at least two nucleic acid chains provided (M 1 .1 and M 1 .2),

e) extension of the primer oligonucleotide (P.1.1) by a template-dependent polymerase using provided nucleic acid chains as templates for primer extension to give specific primer extension products (primer extension products, P1 .1-Ext and P1 2 Each) in addition to the primer oligonucleotide (P1 .1) comprises a synthesized region which is substantially complementary to the respective nucleic acid chain comprising a target sequence (M1), wherein

the primer extension product (P1 1 -Ext) comprises a synthesized complementary region to the characteristic and specific segment of the one nucleic acid (M 1 .1) and

the primer extension product (P1 2-Ext) comprises a synthesized complementary region to the characteristic and specific segment of the second nucleic acid (M 1 .2) and

the synthesized primer extension products (P1 .1-Ext and P1 2-Ext) and their corresponding template nucleic acid chain (M 1 .1 and M 1 .2)

Reaction conditions each form a double strand;

f) binding of at least one controller oligonucleotide (C1 .1 and C 1 .2) to the primer extension products (P1 1-Ext and P1 2-Ext) formed in step (e), wherein

the controller oligonucleotide (C1 .1) with its first, second and third region can bind to the complementary segments of the primer extension product (P1 1 -Ext) with displacement of the nucleic acid chain (M 1 .1) and

the controller oligonucleotide (C1 .2) with its first, second and third region to the complementary segments of the primer extension product (P1 2-Ext) with displacement of the nucleic acid chain (M 1 .2) can bind.

Method according to No. 18, wherein nucleic acid chains comprising variants of a target sequence (template strand) (M 1 .1 and M 1 .2) comprise at least two uniform segments, which is identical in M1 .1 and M1 .2. 20. The method of no. 19, wherein the unitary segment comprises a length of 10 to 180 nucleotides.

21. The method according to Nos. 18 to 20, wherein the characteristic and specific segment comprises a length of one nucleotide up to 50 nucleotides.

22. A method for the specific extension of a primer oligonucleotide, comprising the steps:

a) providing at least two nucleic acid chains comprising variants of a target sequence (template strand) (M 1 .1 and M 1 .2), wherein provided nucleic acid chains

comprise at least one unitary segment which is specific for M 1 .1 and M 1 .2 and is identical for M 1 .1 and M 1 .2, and

at least one characteristic segment specific for each nucleic acid chain

b) providing at least two first primer oligonucleotides (P1 .1 and P 1 .2) each fully or partially attached to the corresponding characteristic and specific segment of each of the provided

Nucleic acid chains can bind complementary, wherein each primer oligonucleotide

a first region, each of which can sequence-specifically bind to a complementary segment (primer binding site) comprising a portion of the target sequence within a characteristic and specific segment of nucleic acid chains provided (M 1 .1 and M 1 .2),

a second region (overhang) connected to the 5 'end of the first region or connected via a linker, which second region can be bound by a controller oligonucleotide (C 1 .1 or C 1 .2);

a first region which can bind to the second region of the primer oligonucleotides (P1 .1 and / or P1 .2) (overhang), and a second region which can be bound to the first region of the respective primer oligonucleotide (P1 .1 or P1 .2) is complementary, where

C 1 .1 a complementary second area to

corresponding first area of P1 .1 comprises and C 1 .2 a complementary second area to

corresponding first area of P1 .2 includes

and

a third region which is complementary to at least part of the synthesized region of at least one expected first primer extension product (P 1 1 -xt or P 1 2-Ext);

wherein the controller oligonucleotides (C 1 .1 and C 1 .2) do not serve as template for a primer extension of a primer oligonucleotide used (P 1 .1 or P 1 .2),

d) hybridizing at least one primer oligonucleotide (P1 .1 and / or P1 .2) to the respective complementary segment comprising a portion of the target sequence (primer binding site) of at least one of the provided

Nucleic acid chains (M 1 .1 and M 1 .2),

e) extension of at least one primer oligonucleotide (P1 .1 and / or P1 .2) by a template-dependent polymerase using provided nucleic acid chains as templates for primer extension to give at least one specific primer extension product (primer extension products, P1 1 -xt and P1 2-Ext), each comprising in addition to the primer oligonucleotide (P1 .1 or P1 .2) a synthesized region which is substantially complementary to the respective nucleic acid chain comprising a target sequence (M1), wherein

the primer extension product (P1 .1 -Ext) comprises a complementary region to the characteristic and specific segment of the one nucleic acid (M 1 .1) and

the primer extension product (P1 2-Ext) comprises a complementary region to the characteristic and specific segment of the second nucleic acid (M 1 .2) and

Reaction conditions each form a double strand;

the controller oligonucleotide (C1 .1) with its first, second and third region to the complementary segments of the primer Extension product (P1 1 -ext) displacing the

Nucleic acid chain (M 1 .1) can bind and

Method according to No. 22, wherein the binding of a respective first primer to the characteristic and specific segment of the provided nucleic acid chains takes place in such a way that the respective characteristic and specific segment of the nucleic acid chain from the 3 ^' -terminal nucleotide of the respective first primer

is bound complementary.

Method according to No. 22, wherein the binding of a respective first primer to the characteristic and specific segment of the provided nucleic acid chains takes place such that the respectively characteristic and specific segment of the nucleic acid chain is bound in a complementary manner by the 3 ^' segment of the respective first primer.

A method of specifically extending a primer oligonucleotide using a competitor primer (Figures 21-23), comprising the steps of:

nucleic acid chains

comprise at least one unitary segment which is specific for M 1 .1 and M 1 .2 and is identical in M 1 .1 and M 1 .2, and comprise at least one characteristic segment specific for each nucleic acid chain

b) providing a first primer oligonucleotide (P1 .1) which is capable of fully or partially complementary binding to the corresponding characteristic and specific segment of one of the provided nucleic acid chains, wherein the first primer oligonucleotide

a first region capable of binding sequence-specifically to a complementary segment (primer binding site) comprising a portion of the target sequence within a characteristic and specific segment of nucleic acid chains provided (M 1 .1), a second region (overhang) attached to the 5 'end of the first region is connected or connected via a linker, wherein the second region of a controller oligonucleotide (C 1 .1) can be bound;

c) provision of a competitor primer oligonucleotide (P 5.2), which

completely or partially to the corresponding characteristic and specific segment of a second nucleic acid chain provided

(M 1 .2), wherein the competitor primer oligonucleotide comprises a first region which is sequence-specific, to a complementary segment (primer binding site) comprising a portion of the target sequence within a characteristic and specific segment of the nucleic acid chain provided ( M 1 .2), where

this region is not identical to the first region of the first primer oligonucleotide

d) providing a controller oligonucleotide (C1 .1), wherein the controller oligonucleotide comprises the following ranges:

a first region capable of binding to the second region of the first primer oligonucleotide (P1 .1) (overhang), and

a second region complementary to the first region of the first primer oligonucleotide (P1 .1), and

a third region that is complementary to at least a portion of the synthesized region of an expected first primer extension product (P 1 .1 -Ext);

wherein the controller oligonucleotide (C 1 .1) does not serve as a template for a primer extension of a used first primer oligonucleotide (P 1 .1) or a competitor primer oligonucleotide,

e) simultaneously hybridizing the first primer oligonucleotide (P1 .1) and the competitor primer oligonucleotide to the respective complementary segment comprising a portion of the target sequence (primer binding site) of at least one of the provided nucleic acid chains (M 1 .1 and M 1 .2)

f) simultaneous extension of the first primer oligonucleotide (P1 .1) and of the

A competitor oligonucleotide by a template-dependent polymerase using provided nucleic acid chains as templates for primer extension to give at least one specific primer extension product (primer extension products, P1 1 -Ext and P5.2-Ext), each adjacent to the primer Oligonucleotide (P1 .1 or P5.2) synthesized Area which is substantially complementary to the respective nucleic acid chain comprising a target sequence (M1), wherein

the primer extension product (P5.2-Ext) comprises a complementary region to the characteristic and specific segment of the second nucleic acid (M 1 .2) and

the synthesized primer extension products (P1 .1-Ext and P5.2-Ext) and their corresponding template nucleic acid chain (M 1 .1 and M 1 .2) form a double strand under reaction conditions;

g) Selective binding of the controller oligonucleotide (C1 .1) to the in step (e)

formed primer extension products (P1 .1-Ext), wherein

the controller oligonucleotide (C1 .1) with its first, second and third region to the complementary segments of the primer extension product (P1 1 -Ext) with displacement of

Nucleic acid chain (M 1 .1) can bind, wherein

the controller oligonucleotide (C1 .1) is unable to bind to the P5.2-Ext under used reaction conditions and to separate P5.2-Ext from its template strand.

26. The method of no. 25, wherein the 3 ^' -terminal nucleotide of the competitor primer

within the second blocking unit of the controller oligonucleotide can bind.

27. Method according to no. 25, wherein the 3 ^' -terminal nucleotide of the competitor primer

within the fourth blocking unit of the controller oligonucleotide, with the fourth blocking unit located in the third region of the controller oligonucleotide.

In certain embodiments, a first primer oligonucleotide and a corresponding controller oligonucleotide are combined to form a primer extension system. Such a primer extension system comprises:

A specific controller oligonucleotide for a sequence variant of the target sequence,

A first primer oligonucleotide which can bind to the sequence fragment which is the same for the target sequence (template strand) which is provided in a substantially complementary manner, and

wherein the first primer oligonucleotide does not comprise sequence segments which are specific for a sequence variant of the target sequence. Rather, the first one Primer oligonucleotide fully complementary or intrinsically complementary to the target sequence bind, without distinguishing the sequence variants.

Such a primer extension system is thus constructed such that the polymorphic locus of the target sequence is located in the sequence segment which lies in the 3 ^' primer extension direction of the first primer. The segment of the controller oligonucleotide corresponding to the polymorphic locus thus lies in its third region.

A specific controller oligonucleotide for a sequence variant of the target sequence

A first sequence variant-specific primer oligonucleotide which can bind at least partially (for example with its 3 ^' terminal nucleotide) to the specific sequence segment of a polymorphic locus of a target sequence provided fully complementary.

In certain embodiments, such a primer extension system is thus constructed such that the sequence of the first primer oligonucleotide overlays at least one nucleotide position with a characteristic sequence of the polymorphic locus.

The segment of the controller oligonucleotide corresponding to the polymorphic locus is, in certain embodiments, completely in the second region of the controller oligonucleotide.

In certain embodiments, the segment of the controller oligonucleotide corresponding to the polymorphic locus lies partially in the second and partially in the third region of the controller oligonucleotide.

In certain embodiments, a first primer oligonucleotide and a corresponding controller oligonucleotide and a competitor primer oligonucleotide are combined to form a primer extension system. Such a primer extension system comprises:

A specific competitor primer oligonucleotide.

In this case, the first primer oligonucleotide does not comprise any sequence segments which are specific for a sequence variant of the target sequence. Rather, the first primer oligonucleotide completely complementary or intrinsically complementary to the target sequence, without distinguishing the sequence variants.

Such a primer extension system is thus constructed such that the polymorphic locus of the target sequence is located in the sequence segment which lies in the 3 ^' primer extension direction of the first primer. The segment of the controller oligonucleotide corresponding to the polymorphic locus thus lies in the third region of the controller oligonucleotide.

In certain embodiments, the competitor oligonucleotide used may bind fully or partially to the segment of the target sequence which may bind complementary to the first region of the first primer oligonucleotide.

In certain embodiments, this competitor primer oligonucleotide is fully complementary to a sequence variant of a target sequence which is not identical to the sequence variant of the template strand recognized by the first primer.

In certain embodiments of the method, a competitor primer oligonucleotide does not comprise a sequence segment which is capable of substantially complementary binding to the first region of the controller oligonucleotide.

In certain embodiments, a first primer oligonucleotide and a corresponding controller oligonucleotide and a competitor oligonucleotide are combined to form a primer extension system. Such a primer extension system comprises:

A first sequence variant-specific primer oligonucleotide which can bind at least partially (for example with its 3 ^' terminal nucleotide) to the specific sequence segment of a polymorphic locus of a target sequence provided fully complementary

A specific competitor primer oligonucleotide

In certain embodiments, such a primer extension system is thus constructed such that the sequence of the first primer oligonucleotide overlays at least one nucleotide position of a characteristic sequence of the polymorphic locus.

In certain embodiments, the competitor oligonucleotide used may bind fully or partially to the segment of the target sequence which may be complementary to the first region of the first primer oligonucleotide. In certain embodiments, this competitor primer oligonucleotide is fully complementary to a sequence variant of a target sequence which is not identical to the sequence variant of the template strand recognized by the first primer.

The application describes the preparation of primer extension products which can be used, for example, in an exponential amplification as starting nucleic acid.

The first primer oligonucleotides and controller oligonucleotides used herein may be identical to or different from those of exponential amplification.

Detailed description of the invention

The technical problems mentioned in the introduction are achieved, in particular, by the provision of methods and components (feedback system) which can check the quality of synthesized primer extension products in different phases of a template-dependent primer extension. Depending on the embodiment, this check can take place either during the synthesis or only after completion of the synthesis. The check can take place in the same reaction batch, so that the actual primer extension reaction does not have to be interrupted (online control) or only after completion of the primer extension reaction (final control).

By checking the quality, it is possible to influence the primer extension reaction itself or the separation of the product from the template. This influence is taken by the provided components. Thus, these components form a feedback system for the primer extension reaction or for the release of the product of the primer extension reaction from the template.

The components of the feedback system can exert an influence on the primer extension reaction in such a way that it is possible to decide between a continuation of the enzymatic synthesis or an interruption of the synthesis or restart of the synthesis. Furthermore, the components of the feedback system can exert influence that the detachment of the product of the synthesis from the template is continued depending on the compliance with the controller oligonucleotide or is stopped or delayed or completely interrupted in the event of any deviations occurring in the sequence ,

The synthesis system in a primer extension reaction typically comprises at least one template and at least one primer capable of binding more or less specifically to the template and initiating a primer extension reaction. Furthermore, the synthesis system comprises at least one polymerase, as well as substrates (dNTPs) and Buffer conditions under which a primer extension reaction can take place. Other oligonucleotides may be added depending on the embodiment of the method, eg block oligonucleotides, for sequence-specific stop of the polymerase or probe oligonucleotides which can deliver a fluorescence signal.

The feedback system comprises a primer which acts as an initiator of a primer extension reaction and another oligonucleotide, a so-called controller oligonucleotide. The primer of the feedback system is identical in a preferred embodiment with the primer of the synthesis system. The controller oligonucleotide is capable of interacting with both the particular primer and the primer extension product sequence-specific from that primer. It is capable of forming a complementary duplex under reaction conditions upon sequence alignment with the primer extension product. The controller oligonucleotide itself does not serve as a template for synthesis for the said primer / polymerase system. Other oligonucleotides may be added depending on the embodiment of the method, e.g. Block oligonucleotides for sequence-specific stop of the polymerase or probe oligonucleotides which can deliver a fluorescence signal.

The method, in certain embodiments, comprises a primer extension reaction (also called primer extension) by means of a primer in the presence of a suitable controller oligonucleotide in the same reaction mixture. The controller oligonucleotide is capable of interacting with the primer extension product to form a complementary strand. The progress of the formation of the double strand between the controller and the primer extension product (P1 -Ext) depends essentially on the correspondence of the sequences between the controller and the corresponding primer extension product. As a result, a sequence check or sequence check can already take place during a primer extension or immediately after a primer extension at least over partial segments of the synthesized primer extension fragment by means of controller oligonucleotides.

Further, in certain embodiments, the method includes a template-dependent primer extension method in combination with subsequent control of the synthesized primer extension product by at least one controller oligonucleotide upon completion of the primer extension reaction. Primer extension and controller interaction with the synthesized primer extension product are two temporally separate reactions. Although the primer extension reaction proceeds in the same reaction mixture in the presence of a corresponding controller oligonucleotide, the reactions are temporally separated by the choice of reaction conditions in individual reaction steps.

The presence of the feedback system in the same reaction as the primer extension reaction makes it possible to design a homogeneous assay. By incorporating the components of the feedback system into the same reaction approach as the primer extension reaction per se, ie simultaneous presence of both the components of the synthesis system and the feedback system, checking or influencing the primer extension reaction and the separation of the primer extension products of if necessary, the matrix can be made in very short time intervals. This allows the feedback system to respond very quickly to any deviations that may occur.

The simultaneous presence of the feedback system in the primer extension approach can lead to a repeated review, so that the result of the review can be summarized as the sum of multiple verification events. The frequency of the verification can be determined both by the appropriate choice of reaction conditions (eg temperature, concentration of the feedback system components) and by the structures of feedback components (eg length and complementarity or extent of the use of modified nucleotides in the design of individual structures). to be influenced.

In certain cases, the feedback system should allow for correct-running reactions (in many cases more than 99% of primer extension strands of a primer extension reaction due to a high natural specificity of an enzymatic template-dependent reaction) and falsely synthesized primer extension products (less than 1% of all primer extension products ). Thus, a feedback system can be helpful, for example, in trace analysis.

High sequence-dependent interaction of the primer extension product (P1-Ext) with the controller can be used to individually influence equilibria between individual intermediate complexes generated during the reaction. Since these complexes have different accessibility to certain sequence segments (single-stranded segments), many reactions can be affected during a running primer extension reaction. Possible intermediate complexes include e.g.

Primer extension product / template, primer extension product / controller oligonucleotide and primer extension product / template / controller oligonucleotide and / or

Primer extension product / probe. Thus, one can exert greater influence on the specificity in the overall process of primer extension as well as in dependent reactions.

Several technical effects can be achieved as a consequence of the sequence-dependent interaction between the controller oligonucleotide and the synthesized strand of the primer extension product (P1-Ext):

Complete or partial sequence-dependent separation, dissociation or detachment of P1-Ext from the template strand;

o Sequence-specific detection of certain variants of the sequence of the P1 .Ext.

sequence-specific maintenance of a double strand or, conversely, sequence-specific conversion of strand segments into a single-stranded form, and a related accessibility of certain sequence segments for interaction with other system components, eg, probes, primers, etc.

In certain embodiments of the method according to the invention, the primer extension can take place as a single synthesis in one step or as a repeated reaction (linear amplification).

The primer extension reaction may be performed alone or in combination with an amplification method.

Thus, especially in the coexistence of several very similar sequences, which may potentially occur for a primer extension reaction starting from a primer, it is advantageous to accommodate a feedback system within the reaction approach. As a result, differences can usually be separated much more sharply or sharply. This can be advantageous for example in allelic discrimination methods or in the targeted amplification of a few copies with mutations which are present to a much lesser extent than the wild type.

Sequence checking by the method according to the invention takes place beyond the primer length (about 5 to 50 nucleotides of the synthesized section) and thus differs from conventional primer extension reactions, in which essentially the primer sequence is responsible for the sequence-specific binding.

The improved specificity of the deletion of the synthesized strand can be advantageously used in several aspects in detection methods.

For example, it may be used as an alternative detection method and / or component for genetic alterations such as single nucleotide polymorphisms.

The sequence-specifically synthesized strand of the primer extension product (P1-Ext) is the desired product of the primer extension reaction. It can be used in various methods of analyzing genetic information, for example in: o generating one or more copies from a longer nucleic acid chain, e.g. a genomic DNA or its segments, or an RNA or its equivalents such as cDNA or segments thereof. These copies can be used as starting nucleic acid chains in amplification methods, such as PCR or other amplification methods; or.

o detecting a particular change in a sequence in a nucleic acid fragment, e.g. an amplification fragment

The components and methods should, especially in the simultaneous presence of several, very similar variants of a template sequence, eg wild-type and one or more mutated sequences, support an improvement in the specificity of individual process steps. The advantages of the method are particularly evident in the simultaneous presence of several, very similar variants of a template sequence, eg wild-type and one or more mutated sequences.

Especially with minor genetic differences, such as single nucleotide changes (SNV) and short InDels (2-10 nucleotides), the specificity of primer extension-dependent procedures / steps can be improved.

In some embodiments of the method, components for a homogeneous assay are to be provided which allow a simultaneous presence of components in a reaction (one-pot reaction or homogeneous assay).

The primer extension reaction described here and the thereby generated primer extension products can serve as starting nucleic acids in an amplification process, for example.

Such an amplification method has already been described in the PCT application (PCT / EP2017 / 07101 1) and the European application (EP-A 16185624.0). For details of the execution of the amplification, the skilled person is referred to this application.

Preferably, such amplification occurs as an exponential amplification in which newly synthesized products of both primers (primer extension products) occur as templates for further synthetic steps. This primer sequences are at least partially copied, so that complementary primer binding sites arise, which are present immediately after their synthesis as sequence segments of a double strand. In the amplification process, synthesis steps of both strands and double-stranded opening steps of the newly synthesized sequence segments are made in mutual alternation. Adequate duplex separation after synthesis is an important prerequisite for further synthesis. Overall, such a variety of synthetic and double-stranded separation steps can lead to exponential amplification.

In the amplification process, the double-stranded opening of the main products of the amplification (amplification of nucleic acid chains comprising target sequence) takes place inter alia by means of an oligonucleotide, termed controller oligonucleotide. The controller oligonucleotide comprises sequence segments corresponding to the target sequence.

Specifically, strand separation is achieved by use of the controller oligonucleotide with predefined sequences which preferentially separate a newly synthesized double strand consisting of both specific primer extension products by means of a sequence-dependent nucleic acid-mediated strand displacement. The resulting single-stranded segments of primer extension products comprise the target sequence, as well as corresponding primer binding sites, which can serve as binding sites for further primer oligonucleotides, such that exponential amplification of amplicons to be amplified

Nucleic acid chains is achieved. The primer extension reactions and Strand displacement reactions preferably take place simultaneously in the batch. The amplification is preferably carried out under reaction conditions which do not permit spontaneous separation of both specific synthesized primer extension products.

A specific exponential amplification of a nucleic acid sequence comprising a target sequence comprises a repetition of synthesis steps and double strand opening steps (activation steps for primer binding sites) as a mandatory prerequisite for the amplification of the nucleic acid chain.

The mechanisms of strand separation by means of a controller described in this application are similar to those mechanisms described for the "Controller Oligonucleotide" in the PCT Application (PCT / EP2017 / 07101 1). The following briefly summarizes this mechanism.

The opening of synthesized duplexes is implemented as a reaction step which is to be sequence-specifically influenced by the controller oligonucleotide. This opening can be complete, even to dissociation of both complementary primer extension products, or even partial.

According to the invention, the controller oligonucleotide comprises sequence segments which can interact with the target sequence and further sequence segments which bring about this interaction or facilitate or favor it. In the context of the interaction with the controller oligonucleotide, double-stranded sections of the synthesized primer extension products are converted into single-stranded form via sequence-specific strand displacement. This process is sequence dependent: only when the sequence of the synthesized duplex has some degree of complementarity with the corresponding sequence of the controller oligonucleotide will there be sufficient double-stranded opening such that the sequence portions essential to the continuation of the synthesis, e.g. Primer binding sites are converted into single-stranded form, which corresponds to an "active state". The controller oligonucleotide thus "specifically" activates the newly synthesized primer extension products comprising the target sequence for further synthetic steps.

In contrast, sequence segments which do not comprise a target sequence are not converted to the single-stranded state and remain as a double strand, which corresponds to an "inactive" state. The potential primer binding sites in such a duplex are less favored or completely hindered in interaction with new primers, so that further synthetic steps on such "non-activated" strands generally do not occur. This lack of or decreased activation (ie conversion to a single-stranded state) of synthesized nucleic acid strands after a synthesis step results in the fact that in the subsequent synthesis step only a reduced amount of primers can successfully participate in a primer extension reaction. The reaction conditions (eg temperature) are designed in such a way that a spontaneous separation of complementary primer extension products in the absence of a controller oligonucleotide is unlikely or significantly slowed down.

The desired enhancement of the specificity of a primer extension reaction thus results from the sequence dependency of the separation of complementary primer extension products comprising a predefined target sequence: the controller oligonucleotide facilitates this double-stranded separation as a result of matching its sequence segments with predetermined sequence segments Primer extension products.

Predominantly sequence-specific separation of the double strand with the assistance of a controller oligonucleotide can be combined in combination with sequence-specific or less sequence-specific primers.

For example, use of predominantly specific controller oligonucleotides capable of distinguishing between variants allows for the assembly of allele-specific and mutation-specific assays, respectively.

The invention is particularly useful in primer extension reactions of sequence variants of a known locus of a target sequence. Such a locus can comprise several occurring sequence variants of a target sequence and is thus a polymorphic locus (FIGS. 12-15). Such a polymorphic locus includes, for example, single nucleotide polymorphisms.

In order to achieve the sequence specificity of a sequence variant of a locus of the target sequence, components which play an essential role in the specificity of primer extension should be placed in a specific arrangement. Particularly advantageous arrangements are those which comprise a known sequence variant of a locus, wherein a predominantly sequence-specific controller oligonucleotide and corresponding primers can be designed.

The position of an expected sequence variant in the known locus is thus taken into account in the design of components such that at least the controller oligonucleotide, better controller oligonucleotide in combination with at least one primer, has a specific sequence composition in a primer extension system is suitable for primer extension of a desired variant of the target sequence.

The object of the invention is further achieved in that a primer extension system comprises at least one sequence-specific primer (eg allele-discriminating primer) in combination with one specific controller oligonucleotide (eg allele-specific controller oligonucleotide). Thus, for each specific composition of a target sequence and its specific variants (eg, alleles), a specific combination of at least one specific primer and at least one specific controller oligonucleotide may be provided. This results in a specific amplification of one of the possible sequence variants of a target sequence. Furthermore, the object of the invention is achieved in that a primer extension system comprises at least two, in particular four sequence-specific primers (eg allel-discriminating primers) in combination with in each case one specific controller oligonucleotide (eg allele-specific controller oligonucleotide). includes. Thus, for each specific composition of a target sequence and its specific varients (eg alleles), a specific combination of at least one specific primer and at least one specific controller oligonucleotide can be provided, with a specific primer for all four nucleotide variants at a particular position. Controller oligonucleotide is provided. In the presence of at least one sequence variant of the target sequence in the reaction mixture, a specific primer extension results in one of the possible sequence variants of a target sequence.

Furthermore, the object of the invention is achieved in that a primer extension system at least one sequence-specific primer (eg allele-discriminating primer) in combination with a specific controller oligonucleotide (eg allele-specific controller oligonucleotide) and at least one further primer (a competitor primer) which has a complementary sequence composition to other expected sequence variants. Thus, for each specific composition of a target sequence and its specific variants (e.g., alleles), a specific combination of at least one specific primer and at least one specific controller oligonucleotide may be provided. This results in a specific primer extension of one of the possible sequence variants of a target sequence.

The object of the invention is further solved by analyzing both strands of a double-stranded nucleic acid chain, wherein in one reaction the components of a primer extension system are provided for a strand of a target nucleic acid, which is used as starting nucleic acid, and in a separate Approach is provided to components for the complementary strand of the target nucleic acid chain which is used as the starting nucleic acid. Thus, at least two controller oligonucleotides are used, each of which can bind to one strand of the target nucleic acid chain (as the first primer extension product). Both controller oligonucleotides are used in separate reaction mixtures.

Furthermore, the object of the invention is achieved in that a primer extension system comprises at least one primer which can support a primer extension of several potential sequence variants (eg a target sequence specific primer, but not an allelic discriminating primer, but a target sequence specific one allele -unspecific primer) in combination with each specific controller oligonucleotide (eg, allele-specific controller oligonucleotide). Thus, for each specific composition of a target sequence and its specific variants (eg, alleles), a specific combination of at least one allele-unspecific primer and at least one Allele-specific controller oligonucleotide can be provided. This results in a specific primer extension of one of the possible sequence variants of a target sequence.

The oligonucleotides required for a primer extension (at least one target sequence-specific first primer and at least one target sequence-specific controller oligonucleotide) are summarized as a target sequence-specific primer extension system.

Since several target sequences can also be present in the batch, a parallel primer extension of more than one target sequence is to be made possible by using multiple target sequence-specific primer extension systems in a reaction approach, wherein preferably target sequence-specific components are combined in each case.

The use of a pre-defined controller oligonucleotide thus allows a sequence-dependent review of the contents of the primer extension products after single synthesis steps or during primer extension and to bring about a selection of sequences for subsequent synthesis steps. Here, "active" single-stranded states of newly synthesized specific primer extension products may result as a result of successful interaction with a controller oligonucleotide, and "inactive" double-stranded states of newly synthesized non-specific primer extension products as a result of deficient and / or insufficient and / or decreased and / or slowed interaction with a controller oligonucleotide.

Definitions and Particular Embodiments:

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art. Standard techniques are used for molecular biology or biochemistry (see, eg, Sambrook et al., Molecular Cloning: A Laboratory Manual, 2d ed. (1989) Cold Spring Harbor Laboratory Press, Cold Spring Harbor, NY, and Ausubel et al., Short Protocols in Molecular Biology (1999) 4th Ed, John Wiley & Sons, Inc.).

In the context of the present invention, the terms used have the following meanings:

Insofar as the sequences shown in the description and in the sequence listing deviate from one another, the sequence shown in the description applies in case of doubt.

The term "oligonucleotide" as used herein with reference to primer, controller oligonucleotide, probes and the nucleic acid chain to be amplified is defined as a molecule comprising two or more, more preferably more than three deoxyribonucleotides and / or ribonucleotides and / or nucleotide Modifications and / or non-nucleotide modifications. In particular, its length encompasses ranges between 3 to 300 nucleotide units (where natural bases and analogues can be used together or alone), in particular between 5 to 200 nucleotide units. One skilled in the art will be able to determine the exact size depending on the ultimate function or use of the oligonucleotides.

As used herein, the term "primer" refers to an oligonucleotide, whether naturally occurring e.g. B. occurs in a purified restriction cleavage or was produced synthetically. A primer is capable of acting as the initiation point of the synthesis when used under conditions which induce the synthesis of a primer extension product complementary to a nucleic acid strand, i. H. in the presence of nucleotides and an inducing agent, e.g. DNA polymerase at a suitable temperature and pH. The primer is preferably single-stranded for maximum efficiency in primer extension. The primer must be long enough to initiate synthesis of the extension product in the presence of the inducing agent. The exact length of the primer will depend on many factors, including reaction temperature and primer source and application of the method. For example, the length of the oligonucleotide primer in diagnostic applications, depending on the complexity of the target sequence between 5 to 100 nucleotides, in particular 6 to 40 and especially 7 to 30 nucleotides. Short primer molecules generally require lower reaction temperatures to perform their primer function to form sufficiently stable complexes with the template, or higher concentrations of other reaction components, such as DNA polymerases, such that sufficient elongation of formed primer is achieved. Template complexes can be made.

The primers used herein are selected to be "substantially" complementary to the different strands of each specific sequence to be amplified. That is, the primers must be sufficiently complementary to hybridize with their respective strands and initiate a primer extension reaction. Thus, for example, the primer sequence does not need to reflect the exact sequence of the target sequence. For example, a non-complementary nucleotide fragment may be attached to the 5 'end of the primer, with the remainder of the primer sequence being complementary to the strand. In another embodiment, single non-complementary bases or longer non-complementary sequences may be inserted into a primer, provided that the primer sequence has a sufficiently large complementarity with the strand sequence to be amplified to hybridize therewith and thus form a primer template. Complex able to produce the synthesis of the extension product.

As part of the enzymatic synthesis of a template-complementary strand, a primer extension product is generated, which is completely complementary to the template strand.

The term complementary with respect to sequences refers to hybridizing sequences with reverse complementary base sequence.

Allele-specific primers are primers which are capable of their sequence composition, preferably under stringent reaction conditions on each individual sequence variants a target sequence to be hybridized and extended by a polymerase using the target sequence. Single allele-specific primers can be grouped together to cover all variants of a common target sequence. Such a group of allele-specific primers comprises at least two different allele-specific primers, as a polymorphic locus at a given position in the target sequence comprises at least two sequence variants. The allele-specific primers are selected to bind under stringent reaction conditions, preferably with their respective perfect-match template, and thus use this specific perfect-match template to form the respective primer extension products under the catalytic action of the polymerase. Preferably, 3 ^' -terminal segments of allele-specific primers can be used to discriminate variants of target sequences and are thus adapted in their sequence composition to the respective variants such that such primers form a perfect match double strand under stringent conditions with the respective variant. Such perfect-match double strands can usually be recognized well by a polymerase and under suitable reaction conditions a primer extension occurs. The interaction of an allele-specific primer with another variant of a target sequence thus results in a mismatch double strand. Such mismatches usually lead to a delay in the extension by a polymerase or to a slowing of the overall reaction. In certain embodiments, allele-specific primers in the 3 ^' segment may include at least one phosphorothioate linkage that protects allele-specific primers from 3 ^' -5 ^' nuclease degradation by a polymerase.

Thus, multiple allele-specific primers include sequence segments which are substantially identical for a group of allele-specific primers, as well as sequence segments which are different among the primers of a group and characteristic of the respective sequence variant of a target sequence. Including uniform sequence segments, such primers can hybridize to the respective target sequence under reaction conditions. Including characteristic sequence segments, a respective primer can specifically bind to a sequence variant of the target sequence to form a perfect-match double strand. Preferably, the primers are designed so that, under used reaction conditions, binding to a target sequence to form a perfect match double strand is preferred and binding to a target sequence to form a mismatch duplex is less preferred.

In certain embodiments, the first primer oligonucleotide is provided as an allele-specific primer in combination with a corresponding allele-specific controller oligonucleotide. In certain embodiments, the second primer oligonucleotide is provided as an allele-specific primer in combination with a corresponding allele-specific controller oligonucleotide. Tm melting temperature

The melting temperature of a complementary or partially complementary double strand is generally understood to mean a measured value of a reaction temperature at which approximately half of the strands are in the form of a double strand and the other half is in the form of a single strand. The system (association and dissociation of strands) is in equilibrium.

Due to a large number of factors which can influence the Tm of a double strand (eg sequence length, CG content of the sequence, buffer conditions, concentration of divalent metal cations, etc.), the Tm of a nucleic acid to be amplified should be determined under the same conditions, like the intended primer extension reaction.

Because of the dependence of the measurable melting temperature on multiple reaction parameters, e.g. of respective buffer conditions and respective concentrations of the reactants, melting temperature is understood to mean a value which was measured in the same reaction buffer as the exponential amplification, at concentrations of both complementary components of a double strand of about 0.1 pmol / l to about 10 pmol / in particular in a concentration of about 0.3 pmol / to about 3 pmol / l, in particular about 1 pmol / l. The respective value of the melting temperature is a guideline, which correlates with the stability of a respective double strand.

A melting temperature for a double strand can be roughly estimated. Several commercial suppliers allow a theoretical calculation of an expected melting temperature. For example, software package OligoAnalyzer 3.1 (available online from IDT (Integrated DNA Technologies) can be used to estimate the strength of the bonds of individual oligonucleotides.

The deoxyribonucleoside triphosphates (dNTPs) dATP, dCTP, dGTP and TTP (or dUTP, or dUTP / TTP mixture) are added in adequate amounts to the synthesis mixture. In certain embodiments, in addition to dNTPs, at least one other type of dNTP analogs can be added to the synthesis mixture. For example, these dNTP analogs include, in certain embodiments, a characteristic label (eg, biotin or fluorescent dye) such that when incorporated into nucleic acid strand, this label is also integrated into the nucleic acid strand. In another embodiment, this at least one modification of the sugar-phosphate moiety of the nucleotide, for example, alpha-phosphorothioate 2 include dNTP analogues ^{'-Desoxyribonukleosid} triphosphates (or other modifications which impart a nucleic acid strand a nuclease resistance), ^2', 3 ^{'dideoxy-ribonucleoside} triphosphates, Azyklo nucleoside triphosphates (or other leading to the termination of a synthetic modifications). In certain embodiments, these dNTP analogs include at least one modification of nucleobase, eg, iso-cytosines, iso-guanosines (or other modifications of extended-genetic alphabet nucleobases), 2-amino-adenosines, 2-thiouridines, inosines, 7-deazy aadenosines, 7-deaza-guanosines, 5-Me-cytosines, 5- Propyl uridines, 5-propyl cytosines (or other modifications of nucleobases that can be incorporated into natural nucleobases by a polymerase and result in alteration of strand stability). In certain embodiments, a dNTP analog comprises both a modification of the nucleobase and a modification of the sugar-phosphate moiety. In certain embodiments, at least one other type of dNTP analogue is added to the synthesis mixture instead of at least one natural dNTP substrate.

The nucleic acid synthesis-inducing agent may be an enzyme or a system that functions to cause synthesis of the primer extension products. Suitable enzymes for this purpose include e.g. template-dependent DNA polymerases such as Bst polymerase and its modifications, Vent polymerase and others - particularly heat-stable DNA polymerases that allow the incorporation of the nucleotides in the correct manner, thereby forming the primer extension products that are complementary to each nucleic acid strand synthesized. In general, the synthesis is initiated at the 3 'end of each primer and proceeds along the template strand until the synthesis is complete or interrupted.

Preference is given to using polymerases which are capable of strand displacement. These include, for example, the large fragment of Bst polymerase or its modifications (e.g., Bst 2.0 DNA polymerase), Klenow fragment, Vent exo minus polymerase, Deepvent exo minus DNA polymerase, large fragment of Bsu DNA polymerase, large fragment of Bsm DNA polymerase.

In certain embodiments, in particular polymerases are used which have no 5 ^' -3 ^' -Exonuklease activity, or have no 5 ^' -3 ^' -FFEN activity.

In certain embodiments, at least two different polymerases are used, for example, polymerases capable of strand displacement and those having 3 ^' -5 ^' reproducing activity.

In preferred embodiments, polymerases are used with a hot-start function, which can only perform their function when a certain temperature is reached.

First primer oligonucleotide:

The primer oligonucleotide comprises a first primer region and a second region. The first primer region is capable of binding to a substantially complementary sequence within the nucleic acid or its equivalents to be amplified and initiating a primer extension reaction. The second region comprises a polynucleotide tail which is capable of binding a controller oligonucleotide and thereby effecting spatial proximity between the controller oligonucleotide and the other portions of the first primer extension product sufficient to induce strand displacement through the controller oligonucleotide. The second region of the first primer oligonucleotide further comprises at least one modification (a nucleotide modification or a non-nucleotide modification) which prevents the polymerase from copying the polynucleotide tail by inhibiting the continuation of the polymerase-dependent synthesis. This modification is located, for example, at the junction between the first and the second region of the primer oligonucleotide. The first primer region of the primer oligonucleotide is thus replicable by a polymerase so that a complementary sequence to this region can be generated during synthesis of the second primer extension product from the polymerase. The polynucleotide tail of the second region of the primer oligonucleotide is preferably not copied by the polymerase.

Certain embodiments of the first primer oligonucleotide

In certain embodiments, this is achieved by the modification in the second region, which stops the polymerase from the polynucleotide tail. In certain embodiments, this is achieved by nucleotide modifications in the second region, where the entire polynucleotide tail consists essentially of such nucleotide modifications and thus is uncopatible to the polymerase.

In certain embodiments, each primer oligonucleotide is specific for each nucleic acid to be amplified.

In certain embodiments, each primer oligonucleotide is specific for at least two of the nucleic acids to be amplified, each comprising substantially different sequences.

In certain embodiments, the primer oligonucleotide is labeled with a characteristic marker, e.g. a fluorescent dye (e.g., TAMRA, fluorescein, Cy3, Cy5) or an affinity tag (e.g., biotin, digoxigenin) or an additional sequence fragment, e.g. for binding a specific oligonucleotide probe for detection or immobilization or barcode labeling.

In certain embodiments, at least a first primer oligonucleotide is provided as an allele-specific primer in combination with at least one corresponding allele-specific controller oligonucleotide.

Primer extension product:

A primer extension product (also called a primer extension product) results from enzymatic (polymerase-dependent) extension of a primer oligonucleotide as a result of template-dependent synthesis catalyzed by a polymerase.

A primer extension product comprises the sequence of the primer oligonucleotide in its 5 ^' segment and the sequence of the extension product (also called extension product) which has been synthesized by a polymerase in a template-dependent form. That by the Polymerase synthesized extension product is complementary to the template strand on which it was synthesized.

A specific primer extension product (major product) comprises sequences of the nucleic acid chain to be amplified. It is the result of a specific synthesis or a correct execution of an intended primer extension reaction in which the nucleic acid chain to be specifically amplified serves as a template.

The length of the extension product of a specific primer extension may be between 10 and 300 nucleotides, in particular between 10 and 180 nucleotides, in particular between 20 and 120 nucleotides, in particular between 30 and 80 nucleotides.

For example, a nonspecific primer extension product (by-product) includes sequences that have arisen as a result of a nonspecific or improper primer extension reaction. These include, for example, primer extension products that have resulted as a result of a false initiation event (false priming) or as a result of other side reactions, including polymerase-dependent sequence changes such as base substitution, deletion, etc. The level of sequence aberrations of nonspecific primer extension products generally exceeds the ability of controller oligonucleotides to successfully displace such double-stranded by-products from their templates so that amplification of such by-products is slower or completely absent. The extent of acceptance or the tolerance limit for deviations depend, for example, on the reaction temperature and the manner of the sequence deviation. Examples of nonspecific primer extension products are primer dimers or sequence variants which do not correspond to the nucleic acid to be amplified, e.g. Sequences which do not comprise a target sequence.

The assessment of a sufficient specificity of the amplification is often related to the task. In many amplification methods, some degree of unspecificity of the amplification reaction can be tolerated as long as the desired result can be achieved.

Particular embodiments of the first primer extension product:

In certain embodiments, the proportion of nucleic acid chains to be amplified in the overall result of the reaction is more than 1%, in particular more than 10%, in particular more than 30%, based on the total amount of newly synthesized strands.

In certain embodiments, the sequence of the synthesized primer extension products is completely consistent with the expected sequence of a nucleic acid to be amplified. In another embodiment, deviations in the sequence obtained may be tolerated by the theoretically expected sequence. In certain embodiments, the degree of agreement of the sequence obtained is due to a Amplification with the sequence of the theoretically expected nucleic acid to be amplified, for example, between 90% and 100%, in particular, the agreement is greater than 95%, in particular, the agreement is greater than 98% (measured on the proportion of synthesized bases).

The first primer extension product is formed from a first primer oligonucleotide. A competitor primer extension product is formed starting from a competitor primer oligonucleotide (Figures 21-23).

A primer extension product, in certain embodiments, may serve as a start-up nucleic acid chain comprising a target nucleic acid-comprising sequence.

Target sequence:

In certain embodiments, a target sequence is a segment of a nucleic acid chain to be amplified which can serve as a characteristic sequence of the nucleic acid to be amplified. This target sequence can serve as a marker for the presence or absence of another nucleic acid. This other nucleic acid thus serves as the source of the target sequence and can be for example a genomic DNA or RNA or parts of the genomic DNA or RNA (eg mRNA), or equivalents of the genomic DNA or RNA of an organism (eg cDNA, modified RNA such as rRNA, tRNA, microRNA, etc.), or defined changes in the genomic DNA or RNA of an organism, for example mutations (eg deletions, insertions, substitutions, additions, sequence amplification, eg repeat propagation in the context of microsatellite instability), splice variants, rearrangement variants (eg, T-Ze II receptor variants), etc. The individual target sequences may represent a phenotypic trait, such as antibiotic resistance or prognostic information, and thus be of interest for diagnostic assays / assays. As a source / origin of a target sequence, such a nucleic acid may comprise, for example, the target sequence as a sequence element of its strand. A target sequence can thus serve as a characteristic marker for a particular sequence content of another nucleic acid.

The target sequence can be single-stranded or double-stranded. It may be substantially identical to the nucleic acid to be amplified or may be only part of the nucleic acid to be amplified.

Equivalents of the target sequence include nucleic acids with substantially identical information content. For example, complementary strands of a target sequence have identical informational content and can be said to be equivalent; RNA and DNA variants of a sequence are also examples of equivalent informational content.

As part of the material preparation prior to the amplification reaction, such a target sequence can be isolated from its original sequence environment and prepared for the amplification reaction. Particular embodiments of the target sequence:

In certain embodiments, a nucleic acid to be amplified comprises a target sequence. In certain embodiments, the target sequence corresponds to the nucleic acid to be amplified. In another specific embodiment, a start-up nucleic acid chain comprises a target sequence. In certain embodiments, the target sequence corresponds to a starting nucleic acid chain.

The nucleic acid to be amplified represents a nucleic acid chain which is to be amplified sequence-specifically or at least predominantly sequence-specifically by means of the exponential amplification using primers and controller oligonucleotide by the polymerase.

The length of the nucleic acid to be amplified may be between 20 and 300 nucleotides, in particular between 30 and 200 nucleotides, in particular between 40 and 150 nucleotides, in particular between 50 and 100 nucleotides.

The nucleic acid sequence to be amplified may comprise one or more target sequences or their equivalents. Furthermore, a nucleic acid to be amplified may comprise sequences substantially complementary to a target sequence which are propagated with similar efficiency as a target sequence in an amplification reaction and comprise the target sequence or its portions. In addition to a target sequence, the nucleic acid to be amplified may include additional sequence segments, for example, primer sequences, sequences with primer binding sites and / or sequence segments for binding of detection probes, and / or sequence segments for sequence encoding of strands by barcode sequences and / or sequence segments for binding to a solid phase. The primer sequences or their sequence portions, as well as primer binding sites or their sequence portions, may for example belong to sequence sections of a target sequence.

In certain embodiments, the nucleic acid to be amplified corresponds to the target sequence.

In another embodiment, the target sequence forms part of the sequence of the nucleic acid chain to be amplified. Such a target sequence may be flanked by 3 ^' side and / or 5 ^' side of further sequences. These further sequences may include, for example, binding sites for primers or their moieties, and / or comprising primer sequences or their moieties, and / or binding sites for detection probes, and / or adapter sequences for complementary binding to a solid phase (eg, Im Frame of microarrays, or bead-based analyzes) and / or include barcoding sequences for a digital signature of sequences.

In order for the amplification to start, a nucleic acid chain must be added to the reaction mixture at the beginning of the reaction, which occurs as an initial template for the synthesis of the nucleic acid chain to be amplified. This nucleic acid chain is called the start nucleic acid chain. This start nucleic acid chain gives the arrangement of individual Sequence elements which are important for the formation / synthesis / exponential amplification of a nucleic acid chain to be amplified.

In certain embodiments, the initial template (starting nucleic acid chain), which is initially added to an amplification reaction, or which is added to the reaction mixture, corresponds to the sequence composition of the nucleic acid sequence to be amplified.

In initial stages of the amplification reaction, and in its progression, the respective primers bind to the corresponding binding sites in the starting nucleic acid chain and initiate the synthesis of specific primer extension products. Such specific primer extension products accumulate exponentially in the course of amplification and increasingly assume the role of templates for the synthesis of complementary primer extension products in exponential amplification.

As a result of the repeated template-dependent synthesis processes in the context of an exponential amplification, the nucleic acid chain to be amplified is thus formed.

Towards the end of an amplification reaction, the major product of the reaction (the nucleic acid to be amplified) may be predominantly single-stranded or predominantly a complementary duplex. This can be determined, for example, by the relative concentration of both primers and corresponding reaction conditions.

Equivalents of the nucleic acid to be amplified include nucleic acids having substantially identical information content. For example, complementary strands of a nucleic acid to be amplified have identical information content and can be said to be equivalent.

Allelic variants of a target sequence / polymorphic locus of a target sequence (FIGS. 12-24)

A target sequence (eg a characteristic segment of a DNA or RNA) may comprise several naturally occurring sequence variants or artificially introduced sequence changes. Such variants are often called polymorphisms of a locus or allele sequences. Furthermore, these variants of a target sequence can map specific changes in the natural state of the DNA, which arise, for example, by mutations / mutagenesis and represent characteristic features of such a clonal propagation process (eg in cancer diseases or in biotechnologically exploitable strains). Single allele sequences of a target sequence may be sequence differences comprising single nucleotides (eg A-> G or T-> C substitutions or single nucleotide insertions or deletions) or a sequence difference may also comprise several nucleotides (eg 2 up to 200 nucleotides). These may, for example, be deletions / insertions / transversions / duplications etc. A sequence segment comprising such sequence variants of a target sequence is often called a polymorphic locus. A target sequence may include one or more polymorphic loci. The sequence positions of single allelic variants of a target sequence are generally known and thus allow for design of sequence-specific reaction components, eg, controller oligonucleotides or combinations comprising a controller oligonucleotide and a first primer or a controller oligonucleotide and a second primer.

The embodiments of target sequences:

In certain embodiments, a target sequence, which may include multiple sequence variants in a polymorphic locus, further comprises at least a first target sequence segment that is characteristic and unique to all target sequence variants of a target sequence (target sequence group). In certain embodiments, a target sequence comprises at least two target sequence segments (a first target sequence segment and a second target sequence segment, each target sequence segment is characteristic and uniform to all target sequence variants of a target sequence (target sequence group).) Such uniform target sequence segments are preferably located and flanked on both sides of a polymorphic locus thus, a polymorphic locus (with sequence variants) of a target sequence from both sides Preferably, the first unitary target sequence segment in its sequence composition is different from the sequence composition of the second unitary target sequence segment in at least one nucleotide position.

The length of a polymorphic locus of a target sequence may comprise regions of one nucleotide up to 200 nucleotides, in particular from one nucleotide up to 100 nucleotides, in particular from one nucleotide up to 50 nucleotides, in particular from one nucleotide up to 20 nucleotides. The lengths of a unitary sequence segment (first and second unitary sequence segment) may comprise at least for one of the two segments: from 6 to 300 nucleotides, in particular from 10 to 200 nucleotides, in particular from 15 to 100 nucleotides, in particular from 20 to 100 nucleotides ,

In certain embodiments, individual sequence variants of a target sequence group may be grouped together, such variants being defined for at least one unitary and specific sequence segment for that target sequence (target sequence group). Individual sequence variants of such a target sequence (target sequence group) thus differ by sequence segments of the polymorphic locus.

In certain embodiments, individual sequence variants of a target sequence group may be grouped together, such variants being defined for at least two unitary and specific sequence segments for that target sequence (target sequence group). Individual sequence variants of such a target sequence (target sequence group) thus differ by sequence segments of the polymorphic locus. Preferably, the polymorphic locus is between both unitary sequence segments. In certain embodiments, two different target sequences can each be specifically amplified in an amplification reaction.

Different target sequences are characterized in that they are preferably differentiable among each other by sequences specific and characteristic of each target sequence. Preferably, different target sequences are differentiable in their entire length by specific and characteristic sequences and thus do not comprise any sequence segments which are identical for both target sequences. In certain embodiments, different target sequences may comprise at least one sequence segment that is substantially similar or even identical for at least two different target sequences. The length of such a sequence segment is equal to or less than 19 nucleotides (counted as coupled nucleotide positions), more preferably equal to or less than 14 nucleotides (as mutually coupled nucleotide positions), more preferably equal to or less than 9 nucleotides (as mutually coupled nucleotide positions), in particular equal to or less than 5 nucleotides (as mutually coupled nucleotide positions).

The start-up nucleic acid chain is a preferred embodiment of a sequence segment comprising target nucleic acid which is said to result as a product of a primer extension reaction.

In order for the amplification to start, a nucleic acid chain must be added to the reaction mixture at the beginning of the reaction, which occurs as an initial template for the synthesis of the nucleic acid chain to be amplified. This nucleic acid chain is called the start nucleic acid chain. This start nucleic acid chain predetermines the arrangement of individual sequence elements which are important for the formation / synthesis / exponential amplification of a nucleic acid chain to be amplified.

Such a starting nucleic acid chain can be present in single-stranded or double-stranded form at the beginning of the reaction. When the complementary strands of the starting nucleic acid chain are separated, regardless of whether the nucleic acid was originally double- or single-stranded, the strands can serve as a template for the synthesis of specific complementary primer extension products.

The starting nucleic acid chain, in certain embodiments, comprises a target sequence or its partial segments which comprise at least one expected sequence variant of a polymorphic locus of the target sequence.

A start nucleic acid further comprises at least one predominantly single-stranded sequence segment to which at least one of the primers of the amplification system can bind predominantly complementary to its 3 ^' segment, so that the polymerase used such a primer, when hybridized to the starting nucleic acid chain, may extend template-specific incorporation of dNTPs. A starting nucleic acid sequence in certain embodiments comprises a target sequence or its partial segments comprising at least one expected sequence variant of a polymorphic locus of the target sequence and at least one uniform sequence segment of a target sequence.

A starting nucleic acid sequence in certain embodiments comprises a target sequence or its partial segments comprising at least one expected sequence variant of a polymorphic locus of the target sequence and at least two unitary sequence segments of a target sequence, wherein uniform sequence segments of a target sequence comprise the polymorphic locus with possible sequence variants Flank both sides.

Controller oligonucleotide / Controller:

The controller oligonucleotide is a single-stranded nucleic acid chain that includes a predefined, substantially complementary sequence in a portion of the primer extension product that is specifically generated as part of the amplification of the nucleic acid to be amplified. This allows the controller oligonucleotide to bind substantially complementary to the primer oligonucleotide and at least to the 5 ^' segment of the specific extension product of the primer oligonucleotide. The controller oligonucleotide in its interior sequence segment, in certain embodiments, comprises nucleotide modifications that prevent the polymerase from synthesizing a complementary strand using the controller oligonucleotide as a template when the primer oligonucleotide is complementarily bound to the controller oligonucleotide.

In certain embodiments, identical controllers are used in the primer extension reaction as in the subsequent acid reaction.

In certain embodiments, the primer extension reaction uses a controller that differs from that in the subsequent acid reaction.

The target sequence-specific controller oligonucleotide is preferably constructed such that it is capable of participating in amplification of preferably a defined specific sequence variant of a predefined target sequence.

The allele-specific controller oligonucleotide is preferably constructed such that it is capable of preferentially effecting the amplification of a specific sequence variant of a target sequence (eg, allele 1), with another sequence variant of the same target sequence (eg, allele 2) the amplification proceeds with reduced efficiency or does not take place in the given time, or results in a yield of amplification products which is insufficient for a detection. Thus, there are measurable differences in the course of an amplification reaction, which depend on whether the sequence of an allele variant specific controller oligonucleotide with the sequence of a provided at the beginning of the reaction nucleic acid chain, which serves as a start nucleic acid and the target sequence a polymorphic locus, specifically coincident or not. If there is agreement or perfect-match complementarity between the sequence composition of the polymorphic locus of a starting nucleic acid chain and a corresponding sequence segment in the controller oligonucleotide, a specific characteristic amplification takes place. In the absence of mismatch complementarity between the sequence composition of the polymorphic locus of a starting nucleic acid chain and a corresponding sequence segment in the controller oligonucleotide, the amplification proceeds differently than a specific characteristic amplification.

An allele-specific controller oligonucleotide is thus not only provided target-specific, but also allele-specific. Thus, depending on the complexity of a polymorphic locus of a target sequence, multiple controller oligonucleotides specific for respective allelic variants of a target sequence can be constructed.

Preferably, a controller oligonucleotide comprises at least one sequence segment having a sequence composition complementary to a specific allelic variant of a target sequence. Furthermore, a controller oligonucleotide preferably comprises at least one sequence segment which comprises a complementary sequence which is identical for all sequence variants of a target sequence. In certain embodiments, a controller oligonucleotide comprises at least one sequence segment capable of complementarily binding to a variant of a polymorphic locus of a target sequence.

In certain embodiments, multiple controller oligonucleotides are provided, each comprising allele-specific sequence segments.

The length of a sequence segment of a controller oligonucleotide complementary to the polymorphic locus of a starting nucleic acid nucleus can comprise regions of one nucleotide up to 100 nucleotides, in particular from one nucleotide up to 50 nucleotides, in particular from one nucleotide up to 20 nucleotides. The length of at least one sequence segment of a controller oligonucleotide which is complementary to uniform sequence segments of a target sequence (first and second unit sequence segment of a starting nucleic acid) may comprise the following ranges: from 4 to 100 nucleotides, in particular from 6 to 100 nucleotides, in particular from 8 to 50 nucleotides.

In certain embodiments, a sequence segment of a controller oligonucleotide that is complementary to at least one variant of a polymorphic locus of a target sequence is located in the third region of the controller oligonucleotide.

In certain embodiments, a sequence segment of a controller oligonucleotide that is complementary to at least one variant of a polymorphic locus of a target sequence is located in the second region of the controller oligonucleotide.

In certain embodiments, a sequence segment of a controller oligonucleotide that is complementary to at least one variant of a polymorphic locus of a target sequence becomes is partially and / or completely localized in the second and third regions of the controller oligonucleotide.

The formation of base pairs under two nucleic acid strands can be carried out essentially complementary, which means that between 70% and 100%, in particular between 90% and 100%, in particular between 95% and 100% of nucleotides of a strand can complement each other in a complementary manner. For example, a nucleotide position in a strand of 20 nucleotides may not have a complementary bond, which corresponds to 95% complementarity.

In the case of perfect match binding of two sequences, the formation of complementary base pairings is preferably 100% between both strands of a duplex. A perfect-match duplex thus does not include a mismatch between the strands.

General structural features of a controller oligonucleotide / primer system (feedback system) and a primer-template system (synthesis system).

The controller oligonucleotides preferably do not serve as templates for primer extension. The extension of corresponding primers to controller oligonucleotides is preferably prevented by a modification of controller strands. The controller oligonucleotide is capable of binding to an overhang on the primer (the first region of the controller oligonucleotide preferably specifically binds to the second region of the corresponding primer) and is capable of complementary binding with the primer (the second region of the controller Oligonucleotide binds to the first region of the primer). Furthermore, the controller can bind with its third region to the synthesized portion of the primer extension product predominantly sequence-specific.

In a particular embodiment, the primers used have a tail or overhang which can not form a stable duplex with the template (the primer overhang remains completely or partially free upon primer binding to the primer binding site of the template) and thus interacts with the first Area of the controller oligonucleotide is available. This primer overhang serves as a binding site for each specific controller oligonucleotide strand (first region of the controller oligonucleotide). The controller oligonucleotide binds to this overhang and is thus brought into spatial proximity with the duplex. This creates the conditions in which the controller oligonucleotide can undergo double-stranded invasion to form a complementary double strand (this process is also referred to as branch migration or sequence-dependent strand displacement). Strand invasion occurs to form a new double strand between a controller oligonucleotide and the corresponding strand of synthesized amplification fragments. Due to a strong sequence dependence of such a double strand formation, the opening of the synthesized double strands is highly dependent on the sequence match with the respective controller sequence. In a particular embodiment, the primers have a tail or overhang which is not copied by a polymerase. The polymerase is prevented from copying the overhang by appropriate primer modifications.

Primer extension system:

A primer extension system comprises at least one target sequence-specific controller oligonucleotide and at least one first primer oligonucleotide and at least one template-dependent polymerase capable of using a template comprising at least one characteristic target sequence or target sequence variant, Under suitable reaction conditions, to support a predominantly specific amplification of the nucleic acid chain to be amplified, whereby predominantly target sequence-specific first primer extension products are synthesized.

An allele-specific primer extension system comprises at least one allele-specific controller oligonucleotide and at least one first primer oligonucleotide (where primers may be target sequence specific and / or allelic specific), as well as at least one template-dependent polymerase which is in is able, using a template which comprises at least one target sequence variant, under suitable reaction conditions, to support a predominantly specific amplification of the target sequence variant (one allele) of the nucleic acid chain to be amplified, wherein predominantly specific first primer extension products are synthesized.

A primer extension system may comprise multiple allele-specific primer extension products, wherein each allele-specific primer extension system preferably copies at least one of the target sequence variants.

Strand displacement (Strand Displacement):

This is a process which, by the action of a suitable agent, leads to a complete or partial separation of a first double strand (consisting for example of A1 and B1 strand) and for the simultaneous / parallel formation of a new second double strand, wherein at least one of the strands ( A1 or B1) are involved in the formation of this new second strand. One can distinguish two forms of strand displacement here.

In a first form of strand displacement, the formation of a new second duplex may be accomplished using an already existing complementary strand which is generally in single-stranded form at the beginning of the reaction. In this case, the means of strand displacement (for example, a preformed single-stranded strand C1, which has a complementary sequence to the strand A1) acts on the first already formed double strand (A1 and B1) and goes with the strand A1 a complementary Binding, whereby the strand B1 is displaced from the bond with the strand A1. If the displacement of B1 is complete, the result of the C1 action is a new duplex (A1: C1) and a single-stranded strand B1. If the displacement of B1 is incomplete, the result depends on several factors. For example, a complex of partially double-stranded A1: B1 and A1: C1 may be present as an intermediate.

In a second form of strand displacement, the formation of a new second duplex may occur under concurrent enzymatic synthesis of the complementary strand, with one strand of the first preformed duplex appearing as a template for synthesis by the polymerase. In this case, the means of strand displacement (for example polymerase with a strand displacement ability) acts on the first already preformed double strand (A1 and B1) and synthesizes a new strand D1 complementary strand D1, wherein at the same time the strand B1 from the bond with the strand A1 is displaced.

By the term "nucleic acid mediated strand displacement" is meant a sum / series of intermediate steps which can be in equilibrium with one another and, as a result, the temporary or permanent opening of a first preformed duplex (consisting of complementary strands A1 and B1) and a new second one Duplex (consisting of complementary strands A1 and C1) lead, where A1 and C1 are complementary to each other.

It is known that an essential structural prerequisite for the initiation of strand displacement is the creation of a spatial proximity between a duplex end (preformed first duplex of A1 and B1) and a single stranded strand (C1) which initiates strand displacement (where A1 and C1 can form a complementary strand). Such spatial proximity can preferably be achieved by means of a single-stranded overhang (in the literature examples are known with short overhangs, which binds the single-stranded strand (C1) temporarily or permanently complementary, and thus complementary segments of the Stranges C1 and A1 in sufficiently close, so that a successful strand displacement of the strand B1 can be initiated. The efficiency of initiation of nucleic acid-mediated strand displacement is generally greater the closer the complementary segments of strand A1 and C1 are positioned to each other.

Another essential structural prerequisite for the efficient continuation of nucleic acid-mediated strand displacement in internal segments is the high complementarity between strands (eg, between A1 and C1), which must form a new double strand. For example, single nucleotide mutations (in C1) can lead to disruption of strand displacement (described, for example, for branch migration). The present invention makes use of the ability of complementary nucleic acids to sequence-dependent nucleic acid-mediated strand displacement.

Embodiments for the interaction of individual components in primer extension reactions

Synthesis of the primer extension product and interaction with the controller in a predominantly sequential order:

The technical problem of this embodiment is the synthesis of a primer extension product and subsequent separation of the primer extension product from its template. The separation of the primer extension product takes place with the assistance of a controller oligonucleotide and is thus preferably sequence-specific.

Although the synthesis of the primer extension product and the checking by means of a controller oligonucleotide preferably takes place in the same batch (homogeneous assay), the individual reactions are temporally separated. First, the synthesis of the P1-Ext (synthesis phase) takes place (FIG. 3) and then the double strand is opened by means of a controller (controlling phase) (FIG. 4). The two phases can be used for example by changing the reaction temperature of the reaction mixture in a desired sequence (in a homogeneous assay) or by sequential addition as a heterogeneous format.

Simultaneous presence of a first primer and a controller in one approach in the presence of a primer extension catalyzing agent (a polymrease) and suitable substrates requires the use of a modified controller such that the first primer, when hybridized to the controller oligonucleotide, is not is extended by a polymerase.

In the following, a preferred form is described with a homogeneous format in which at least one template strand, at least one controller oligonucleotide, at least one primer oligonucleotide, at least one polymerase and dNTPs are present as substrates in a suitable buffer system at the beginning of the reaction.

Synthesis phase:

The goal of the synthesis phase is to synthesize a specific primer extension product by means of a polymerase-mediated synthesis using a suitable template strand.

A primer extension reaction comprises a preferably specific primer binding

(first region of the primer oligonucleotide) to the template strand on a suitable primer

Binding site (sequence segment capable of being predominantly complementary to the first Area of the primer oligonucleotide), wherein the second area of the primer (primer overhang) preferably does not bind to the template strand, and thus is available for later interaction with the controller. The primer binding site can be completely single-stranded or partially single-stranded, so that at least a portion of the first region of the primer can bind sequence-specifically to the primer binding site via complementary base pairs (Watson-Crick rule).

The polymerase can now extend the bound to the primer binding site primer oligonucleotides in a template-dependent synthesis of complementary Anküpfung nucleotides into the growing strand of the primer (3 ^'end-OH), thereby creating a template strand complementary to the primer extension product (P1 ext). The synthesis of the complementary strand usually takes place under suitable reaction conditions until the polymerase finds enough substrate in the batch and sufficient sequence segments in the template strand are available in suitable form for the polymerase as template. Depending on the polymerase may be one of the conditions of the sequence segments that the template strand is single-stranded (using polymerases without strand displacement properties) or even partially or even completely double-stranded (using polymerases with strand displacement properties). The synthesis is often carried out over the sufficient time, so that from more than 5%, in particular more than 50%, in particular more than 90% of the template strands a primer extension product can be synthesized.

Immediately after the synthesis, the primer extension product (P1-ext) is present in complex with the template strand in double-stranded form (P1-Ext / template strand complex). This double-stranded complex comprising P1 -ext and template strand is preferably stable under selected reaction conditions of the primer extension phase and can not spontaneously dissociate into its constituents, or this spontaneous dissociation occurs very slowly and can thereby be neglected.

In certain embodiments, primer binding occurs under reaction conditions that allow thermodynamically stable binding of the first region of the primer oligonucleotide to the corresponding complementary position in the template. Such conditions are for example at reaction temperatures which are well below the melting temperature (Tm) of such a complex (P1 / template strand). The Tm should have been measured under the same buffer conditions. For example, the reaction temperatures may range from Tm minus 50 ° C to Tm minus 5 ° C. With sufficient complementarity of the 3 ^' segment of the primer with the template, the extension of the primer by a polymerase usually takes place quickly and easily, if the reaction conditions are also well suited for the polymerase and sufficient amounts of dNTPs are present in the batch.

In a preferred embodiment, the complex comprising primer / controller oligonucleotide is also in double-stranded form under such reaction conditions. As primer oligonucleotide and controller oligonucleotide both in the first primer region and in the second Primer region (overhang / primer tail) interact, the bond between the first primer and the controller is usually more stable than between the first primer region and the template. Under such reaction conditions, the primer should be in excess so that enough primer in single-stranded form remains in the reaction and can react with the primer binding site of the template strand so that a primer extension reaction can take place. For example, the concentration of a controller oligonucleotide is about 1 pmol / l, then the concentration of the first primer can be about 1, 1 to 5 pmol / l. Under reaction conditions that require a stable duplex formation between a controller and a first primer, the primer saturates the controller. However, there are still enough free single-stranded first primer oligonucleotides in the solution that can interact with a suitable template.

The controller oligonucleotide is thus preferably present in the complex comprising primer / controller oligonucleotide during the synthesis phase, thereby being in an inert form. In this embodiment, the controller does not interfere with the synthesis process. In this state, the first and second regions of the controller oligonucleotide are occupied by the primer oligonucleotide (corresponding to the first and second regions thereof) through the formation of a complementary strand and thus are not responsible for interactions with formed primer extension products during the synthesis phase available.

In a further preferred embodiment, the primer binding takes place under reaction conditions which do not permit thermodynamically stable binding of the first region of the primer oligonucleotide to the corresponding complementary position in the template. There is thus a balance of binding events and dissociation events. In binding events, complexes are formed which comprise the first region of the primer and the corresponding primer binding positions of the template. In dissociation events, these complexes separate into individual components, so that no primer extension reaction can start by means of polymerase. Such conditions are present, for example, at reaction temperatures which are about the melting temperature (Tm) of such a complex (P1 / template strand). The melting temperature (Tm) should be measured under the same buffer conditions and concentrations. For example, the reaction temperatures may be in the range of Tm -5 ° C to Tm + 5 ° C, in particular embodiments in the range of Tm -5 ° C to about Tm +15 ° C, in another particular embodiment in the range of Tm -5 ° C to Tm +30 ° C. Even under such conditions, extension of the primer by a polymerase can be done with sufficient complementarity of the 3 ^' segment of the primer with the template. However, the reaction can be slower or significantly slower compared to reaction conditions where stable primer binding occurs. At reaction temperatures above Tm + 30 ° C (P1 / template), the primer extension reaction is usually so inefficient that such conditions are rarely used in primer extension reactions. Also at Reaction temperatures from Tm -5 ° C to about Tm +15 ° C, it may be advantageous if the primers are in excess, so that enough primer remains in single-stranded form and can react with the template strand, so that a primer extension reaction can take place.

The structure of the first primers and the controller oligonucleotides, as well as the reaction conditions of the synthesis phase are chosen such that the double-stranded complex comprising primer / controller oligonucleotide is present predominantly in double-stranded form. By primer excess, the controller oligonucleotide may thereby be saturated and thus preferably excluded from interactions with formed primer extension products. Since primer oligonucleotide and controller oligonucleotide interact both in the first primer region and in the second primer region (overhang / primer tail), the bond between the primer and the controller is generally more stable than between the first primer Area and the matrix. As a result, the melting temperature (Tm) of the complex comprising primer / controller oligonucleotide is generally higher than that of the complexes comprising primer / template.

polymerases:

Both thermostable polymerases such as Taq polymerase / Pfu polymerases and thermolabile (such as Klenow polymerase fragment or MMLV reverse transcriptase) or mesophilic polymerases (eg Bst polymerase) can be used. The polymerases may comprise both a 3 ^'exonuclease activity (proofreading polymerases) or not. Depending on the type of template used, DNA-dependent polymerases or RNA-dependent polymerases can be used.

For polymerases, it is possible to use both enzymes which are identical to the natural enzymes (eg Pfu polymerase or Bst DNA polymerase) and also their modifications or fragments or fusions with other proteins (eg AmpliTaq, Bst Large Fragment Polymerase, Klenow Large Fragment or Phusion Polymerase). ,

Both polymerase can be used with (e.g., Bst polymerase and its modification such as Bst Large fragment) or without strand displacement properties (such as Taq polymerase or Pfu polymerase or MMLV reverse transcriptase).

Both predominantly processive polymerases or their modifications (for example Bst-Large Fragment or Phusion Polymerase) and less processive polymerases can be used (Taq Polymerase or Pfu Polymerase).

Since the synthesis phase and controlling phase are separated in time, the synthesis reaction is carried out (synthesis phase) (Figure 3) until the desired amount of primer extension product is obtained. Only then does the controlling phase take place (FIG. 4). As a result, the reaction has sufficient time to form a sufficient amount of product, the polymerases can be present usually in catalytic amounts. template strand:

The template strand comprises a primer binding site such that under selected reaction conditions binding of the first region of the first primer can occur and polymerase mediated synthesis of the strand can occur. Furthermore, a template strand comprises a target sequence. This target sequence usually comprises the sequence segment of the template strand, which performs the template function for the synthesis of the complementary strand. Preferably, the template strand and the primer oligonucleotide are adapted in their design to each other such that the second region of the primer oligonucleotide does not bind to the template strand complementarily, or at least do not form stable complementary binding, and thus potentially capable of joining with the first region of the controller oligonucleotide. In general, both DNA and RNA can occur as template strands.

The primer binding site of the template is preferably in a single-stranded form and allows for site-specific binding of the first region of the primer oligonucleotide to the template. In certain embodiments, the target sequence of the template strand comprises at least one segment of the primer binding site so that the 3 ^' segment of the first primer can bind complementary to the target sequence.

The segment of the template strand which serves as a template for the synthesis of the complementary strand by the polymerase may, in certain embodiments, be wholly or predominantly (more than 50%) single-stranded under reaction conditions. In another embodiment, this segment is predominant (greater than 50%) or fully double-stranded. The polymerases used in the synthesis must be selected accordingly: in the case of single-stranded matrices, polymerases without strand displacement can be used, e.g. Taq polymerase or Pfu polymerase. For predominantly double-stranded segments of the template, preference is given to using polymerases having strand-displacing properties, e.g. Bst polymerase Large Fragment or Vent polymerase or Klenow fragment. Combinations of several polymerases may also be used, e.g. Taq polymerase and Vent polymerase or Taq polymerase and Bst polymerase, or Pfu polymerase and Bst polymerase. For polymerases used, their selection depends on the specifications of the manufacturer. Both naturally occurring polymerases and their partial components (e.g., Klenow fragment or Bst polymerase Large Fragment) or modifications, e.g. Bst-2.0 polymerase or AmpliTaq polymerase).

In certain embodiments, the primer binding site may be for the primer in the 3 ^' segment of the template. In such an embodiment, it is advantageous if the primer oligonucleotide comprises a modification (called the first blocking moiety) which prevents the polymerase from copying the second primer region. In another embodiment, the template in its 3 ^' segment can go well beyond the primer binding site of the primer. The length of such an overhang can range from a few nucleotides to several kilobases. The structure of such a template strand causes the primer overhang, starting from the 3 ^' end of the template, not to be copied by the polymerase. Therefore, in such an embodiment, the primer need not necessarily comprise a block group (called the first blocking unit) in the second region of the primer. The second region can thus directly transition into the first region and be linked to the 5 ^' end of the first region via the 5 ^' - 3 ^' -phosphate link.

The synthesis of the primer extension product via polymerase as a template-dependent synthesis. In some embodiments, it is advantageous to limit the progress of the synthesis of the primer extension product and thus limit a length of the desired primer extension product.

The length of the primer extension product is preferably limited by the availability of a sequence segment of the template which can be used by the polymerase for synthesis. This can be achieved, for example, by limiting the template strand in the 5 ^' sequence segment, which is available as a template for the complementary synthesis. This limitation prevents the polymerase used from continuing to continue the synthesis beyond this obstacle. This limitation can be achieved, for example, by strand termination (strand termination) or by use of one or more modifications in the strand (eg spacer or linker or abasic bound phosphate residues) which prevent the polymerase from being synthesized or by nucleotide modifications (eg nucleobase modification as Iso-C and Iso-G, or the sugar-phosphate moieties such as 2 ^'-0-Me, ^2' MOE, morpholino, PNA etc.).

Using long template strands, eg genomic DNA or mRNA or long PCR fragments, the synthesis of the polymerase can be stopped or stopped by using additional oligonucleotides on predetermined sequence segments. In such an embodiment, the progress of the synthesis of the primer extension product is limited by using at least one so-called block oligonucleotide (Figures 3,4, 6-8). Under the reaction conditions of the synthesis phase, such a block oligonucleotide may preferably remain predominantly sequence-specifically hybridized to the template strand via complementary binding. Such a block oligonucleotide, when complementarily attached to the template strand, prevents the polymerase from reading the template strand in the sequence portion bound by that oligonucleotide and, correspondingly, beyond. Depending on the type of polymerase used and its equipment, different embodiments of block oligonucleotides can be used. The selection of the oligonucleotide structure, the polymerase and the reaction conditions are based on the fact that the progressive synthesis is prevented or blocked by polymerase. The length of the block oligonucleotide and the nature of the Sequence composition is directed to the fact that the block oligonucleotide must remain stably bound to its complementary position of a template strand under reaction conditions of the synthesis phase and preferably can not spontaneously dissociate from the template. Such oligonucleotide is usually brought in 3 ^' direction from the first primer oligonucleotide in effective concentrations in contact with the template strand prior to the start of a synthesis phase of a primer extension reaction and incubated for sufficient time at appropriate reaction conditions so that it can be bound to its can bind complementary position in the strand.

Examples of such oligonucleotides leading to the termination of a polymerase-dependent synthesis (FIGS. 3, 4, 6 - 8) are known to a person skilled in the art.

For example, oligonucleotides with exonuclease-resistant modifications (e.g.

Phosphorothioate (PTO) or 2 ^'-0-Me modifications which primarily in the ^5' segment of the oligonucleotide are positioned lead) to the fact that, for example, the Taq polymerase can not degrade the block oligonucleotide (with their 5 ^'-3 ^' -Exonuklease- activity) and thus the synthesis via the binding site of the oligonucleotide can not continue. For example, oligonucleotides complementary to the template, approximately 15-70 nucleotides in length, with approximately 2-50 PTO modifications localized predominantly in the 5 ^' segment of such a block oligonucleotide, can prevent Taq polymerase from cloning this oligonucleotide via 5 ^' - ^'. 3-exonuclease-dependent degradation to cleave or detach from the template. Such a nucleotide is usually capable of preventing a Taq polymerase from reading the template strand segment bound by the block oligonucleotide.

• Another example is the prevention of polymerases with strand

Displacement properties. Oligonucleotides having multiple double-strand stabilizing modifications, e.g. LNA or PNA typically results in the polymerase being unable to continue synthesis via the oligonucleotide binding site. For example, template-complementary oligonucleotides of about 15-50 nucleotides in length with about 7-30 LNA modifications, for example, can prevent Bst polymerase (large fragment) from detaching this oligonucleotide via polymerase-dependent strand displacement from the template. Further examples of such block oligonucleotides are known. For example, PNA modifications or LNA modifications have been used in clamp-PCR methods to block polymerase synthesis.

The length of the P1-text generated during the template-dependent synthesis and the length of the matching controller oligonucleotide can be chosen differently.

In certain embodiments, the length of the controller oligonucleotide and the length of the expected primer extension product are matched to one another such that the Controller oligonucleotide covers the complete synthesized by the polymerase area. In this embodiment, a controller oligonucleotide can completely detach the P1 -ext from the template. In the 3 ^' segment of the P1 -ex, no free nucleotides remain for interaction with the template during the controlling phase (see below).

In certain embodiments, the length of the controller oligonucleotide and the length of the expected primer extension product are matched to one another such that the length of the synthesized region of the primer extension product extends beyond the length of the controller oligonucleotide. The 3 ^' segment of the primer extension product thus comprises a sequence segment which is not checked by the controller oligonucleotide. Thus, when P1-Ext interacts with the controller oligonucleotide, a double-stranded segment of P1-Ext and template remains unchecked by the controller oligonucleotide. This double-stranded segment can spontaneously dissociate under the reaction conditions of the controlling phase, for example due to a temperature-induced strand opening (eg at temperatures of about 50-80 ° C). The length of this 3 ^' segment of the primer extension product (without interaction with the controller oligonucleotide) may comprise, for example, sequence lengths which lie in the following ranges: from 1 to 10 nucleotides, from 10 to 20 nucleotides, from 30 to 40 nucleotides, from 40 to 50 nucleotides, from 50 to 70 nucleotides, from 70 to 100 nucleotides.

The synthesized primer extension product is now to be detached from the template by means of controller oligonucleotide and thus made available for further steps.

Controlling phase (FIGS. 4, 7 - 11):

The aim of the controlling phase is to check the synthesized primer extension product for its agreement with the given sequence. The sequence dependency of the double strand formation from primer extension product and controller oligonucleotide serves to check the synthesis quality during the primer extension reaction.

As a result of the controlling phase, the primer extension product is completely or partially detached from the template sequence-dependently. At the same time, a formation of a double strand comprising primer extension product / controller oligonucleotide takes place at the same time.

Thus, successful formation of the primer extension product / controller strand (P1-Ext / Controller) complex is a prerequisite for opening the double strand (template / primer extension fragment) after primer extension. Sequence control is in this embodiment only after the synthesis of the primer extension product in a separate reaction step (controlling phase). The controller oligonucleotide is to form a double strand with the now synthesized in the synthesis phase P1 -Ext. Preferably, controller oligonucleotide is already in the reaction mixture at the beginning of the synthesis reaction. Due to an excess of the primer oligonucleotide, the controller oligonucleotide is present as a complex comprising primer / controller.

Formation of the controller oligonucleotide / primer extension product complex requires release of the controller oligonucleotide from the primer / controller complex. For this purpose, for example, the temperature of the reaction mixture can be increased so that the primer / controller complexes become thermodynamically unstable. The reaction temperature should, however, be chosen so that the fully double-stranded complexes of primer extension product and template strand do not spontaneously disintegrate.

By raising the reaction temperature, the controller oligonucleotides are released from complexes (primers / controllers) and are in equilibrium with the regeneration of these complexes (e.g., at temperatures around the Tm of the primer / controller complexes ± 3 to 8 ° C).

The controller oligonucleotides, which are now freely available, can interact with complexes of primer extension products and template strands in the second primer region (primer overhang). The interaction starts from the primer overhang. This establishes spatial proximity between the controller strand and the end of the double-stranded region between primer extension product / template strand. As a result, the double-stranded formation can be transferred between the controller and the first primer region (sequence-dependent strand displacement). Given the sequence identity with the synthesized portion of the primer extension product, the double strand formation between the controller oligonucleotide and the primer extension product continues to expand.

The progression of this interaction between the synthesized primer extension product and the controller oligonucleotide results in increasing release of the template strand from the complex with the primer extension product. Preferably, with sufficient compliancy in complementarity, dissociation of the template complex and primer extension product occurs. A new complex is thereby formed which comprises the primer extension product and the controller oligonucleotide.

In certain embodiments, a 3 ^' segment of the primer extension product remains in binding with the template strand even though the controller oligonucleotide has completely bound to the primer extension product. The dissociation of this complex (comprising the 3 ^' segment of the primer extension product and the corresponding complementary regions of the template) depends on the reaction conditions chosen during the controlling phase (see below). The successful interaction of components in the interaction of the controller oligonucleotide with the synthesized primer extension product and the spontaneous dissociation of the complex from the 3 ^' segment of the P1 -ext and the template can be used to detach the primer extension product (in the complex of P1- Ext and COntrolelr strand) from the matrix. Discriminating effect of the controller oligonucleotide:

However, if deviations occur in the complementarity between the P1-Ext and the controller oligonucleotide, the process of sequence-dependent strand displacement can be severely hindered. The higher the sequence differences between the synthesized primer extension product and the corresponding controller oligonucleotide, the more the formation of a complex of controller oligonucleotide and P1 text is affected. The degree of influence can be from slight slowing to complete stop in the progress of complex formation.

Due to reversibility in the double-stranded formation, the template oligonucleotide can be completely or partially detached from the template strand by binding with the primer extension product (displacement by template). Such displacement may be accomplished completely in certain embodiments. This can be done, for example, if under the reaction conditions used in the controlling phase the stability of the complex from the second region of the primer and the first region of the controller oligonucleotide is not sufficiently high and this complex can spontaneously dissociate into its subcomponents. Thus, the template strand acts against the controller oligonucleotide. Since the reaction conditions are such that the template and P1-Ext complex should not spontaneously dissociate, only such primer extension products can be detached from this complex by the controller oligonucleotide that has sufficiently complementary binding to the controller oligonucleotide. Such a discriminatory effect can be exploited under several aspects.

Examples of potential sources of variation in primer extension products.

Variations in the sequence of a primer extension product may be due to several causes, for example, the presence of multiple template strands with the same or similar primer binding sites and sequence variants at one or more positions in the segment of the template strand, e.g. in the presence of a polymorphic locus in the target sequence segment. Another cause of deviations may be, for example, synthesis errors / incorporation errors introduced by polymerases.

In the event of sequence deviations in the primer extension products from the template by the sequence composition of the controller oligonucleotide, such primer extension products preferably remain in double-stranded complexes with the template during the controlling phase. Thus, such double-stranded complexes comprising a template strand and a primer extension product (which could not be detached from the controller) can not be an active form for further analysis steps. Thus, differentiation can be made between primer extension products: primer extension products detached from the template represent an active form of primer extension products. Primer extension products in complex with their template are preferably an inactive form. For example, the use of a primer extension product in further reactions may require that certain portions of the P1-Ext be in single-stranded form. This may be necessary, for example, for binding a primer or a probe. This embodiment can therefore be used, for example, to convert the sequences in the 3 ^' segment of the P1-E 1 in a single-stranded state.

The primer extension product is only detached from the template if the synthesis is carried out correctly or only if it matches the complementarity with the controller oligonucleotide. In the case of deviations in the sequence, the primer extension product remains in complex with the template and the sequences in the 3 ^' segment of the P1-Ext can not be converted into the single-stranded state (under used conditions).

This discriminatory effect of the controller oligonucleotide after a primer extension reaction (synthesis phase) can be used for several technical tasks. The availability of controller oligonucleotide in the approach (homogeneous assay format) allows both a low-contamination integration in other methods of molecular analysis as well as a combination with other methods, such as amplification or detection methods. Some embodiments are therefore to be presented in more detail. For example, a fully complementary primer extension product attached to a controller can be partially or fully protected from nuclease exposure if the nature of the controller string has been selected appropriately. For example, when using nuclease resistant modifications to certain sequence segments of the third region of the Contollers or continuously over the whole third area of the controller, such as PTO or 2 ^'-0-alkyl modifications, such a controller can

protect complementary primer extension product from nuclease cleavage.

On the other hand, the remaining primer extension products bound to the template strand can be selectively enzymatically cleaved by the action of a nuclease (e.g., restriction endonuclease or exonuclease). Thereby, specific primer extension products of predetermined sequence with higher specificity can be isolated.

A controller may further comprise an affinity tag, eg, a biotin residue (for example, covalently coupled to the 3 ^' end or 5 ^' end). Thus, a primer extension product attached to the controller can be isolated by using a solid phase coated, for example, with streptavidin.

Several different template strands with essentially uniform

Primer binding site and a uniform primer

The embodiment is based on the sequence-specific detachment / separation of the primer extension product from its template strand in the simultaneous presence of several different primer extension products in the same reaction mixture. template strands:

In this embodiment, multiple template strands (at least two) with a substantially similar primer binding site are used, but differ in the sequence of the template segment sequence. The differences between template strands are preferably in the 3 ^' direction from the 3 ^' end of the primer. The differences may include, for example, single nucleotide variations (eg, SNVs: substitutions, deletions, insertions), or insertions, deletions, duplications, inversions of multi-nucleotide sequence segments (eg, 2 to 200 nucleotides).

Thus, a template strand comprises a target sequence comprising at least one polymorphic locus and further comprising at least one sequence segment which is uniform for all sequence variants of a target sequence. The primer binding site may be, for example, in the unitary sequence segment. The polymorphic locus is thus in the 3 ^' direction from the 3 ^' primer end.

primer:

Preferably, a single primer oligonucleotide is used which is capable of predominantly complementary binding to uniform primer binding sites of all template strands present in the anneal and initiating initiation of a synthetic reaction by a polymerase.

controller:

At least one controller oligonucleotide constructed in its third region is used so that it is capable of binding to only a certain variant of the sequence of a possible primer extension product complementarily in the synthesized region of the primer extension product. If multiple controller oligonucleotides are used, each controller oligonucleotide is constructed sequence-specifically to a particular variant of the sequence.

Synthesis phase:

During the synthesis phase, primer binding (through the first region of the primer oligonucleotide) can occur substantially without discrimination of single template strands. The polymerase is able to initiate synthesis of such bound primers and synthesizes complementary strands on the basis of the respective template strand. This results in primer extension products which are substantially complementary to the respective template strand and thus each comprise complementary segments to individual sequence variants of the template strands. During synthesis, the polymerase can not distinguish between these sequence differences of the template strands. The controller oligonucleotide is in double-stranded form in the primer / controller complex during the synthesis phase and does not interfere with the synthesis process.

Controlling phase (FIGS. 4, 7 - 11):

Upon completion of the synthesis phase, release of the controller oligonucleotide from the double-stranded complex primer / controller, e.g. by raising the temperature (at a temperature at which the primer / controller complexes are at least partially dissociated, but complexes comprising primer extension products / template strands are substantially stable). The controller oligonucleotide, which is now at least partially in single-stranded form, can interact through its first region with the second region of the primer, thus initiating strand displacement. The progress of the formation of the double strand between the first primer extension product and the controller oligonucleotide depends on the correspondence of the sequences of the third region of the controller oligonucleotide and the synthesized portion of the respective primer extension products. The second area of the controller is fully complementary to the first area of the first primer.

The synthesis products (primer extension products) differ depending on the template strand used. These differences can range from differences in only one nucleobase to completely different sequence composition of the primer extension product. Due to these differences in primer extension products, the outcome of the controlling phase is different. Predominantly, primer extension products with a sufficient degree of complementarity with the third region of the controller are replaced by their template strand. Thus, a differentiation between synthesized primer extension products takes place in the controlling phase: The controller oligonucleotides preferably form double-stranded complexes with complementary primer extension products. In case of a sequence deviation, this double-stranded formation takes place only insufficiently. Due to selected reaction conditions (a temperature at which primer / controller complexes are at least partially dissociated, but stable complexes comprising primer extension products / template strands), primer extension products with sequence differences to the controller strands remain predominantly attached to their template strands.

The now completely or partially detached primer extension product can be used in further analyzes. For example, it can be isolated from the reaction mixture (in bound form to the controller oligonucleotide). Furthermore, it can be used as a binding partner for other oligonucleotides, eg probes. Furthermore, it may even occur as a template strand, for example, after binding of a new primer in the 3 ^' segment of the primer extension product. Several different template strands with allele-discriminating primers

The embodiment is based on the sequence-specific detachment / separation of the primer extension product from its template strand in the simultaneous presence of several different primer extension products in the same reaction mixture.

template strands:

Also in this embodiment, multiple template strands (at least two) are used with a primer binding site, with the primer binding site being different for individual templates. The differences between template strands are preferably in a position which preferentially interacts with the 3 ^' segment of the primer (e.g., positions 0, -1, -2, -3, -4, -5). The differences may include, for example, single nucleotide variations (eg, SNVs: substitutions, deletions, insertions), or insertions, deletions, duplications, or inversions of sequence segments of several nucleotides (eg, 2 to 10 nucleotides).

First primer oligonucleotide:

In the primer extension reaction, several first primer oligonucleotides (more than two) are used. The respective first primer oligonucleotides are constructed in their 3 ^' segment of the first primer region such that each primer oligonucleotide used comprises a specific sequence complementary to a particular sequence variant of the candidate template strands (eg, allele-specific primers). , Such first primers are capable of predominantly complementary binding to their specific primer binding sites of the respective template strands and to initiate initiation of a synthetic reaction by a polymerase.

The first primer oligonucleotides may comprise uniform or different second regions (primer overhang, oligonucleotide tail). In this case, the composition of the respectively specific controller oligonucleotides in the respective first region is adapted so that a specific pairing of an allele-specific first primer and a corresponding controller is possible and each controller in such a pair comprises a specific base sequence in the first region of the controller and each first primer oligonucleotide in such a pair has a correspondingly complementary sequence in the second region. Thus, the primer oligonucleotides can interact with controller oligonucleotides predominantly specifically during the controlling phase.

Competitor primer oligonucleotide (Figures 21-24):

In the primer extension reaction, at least one other primer which is not a first primer oligonucleotide can be used. Such a primer will be competitor primer Called oligonucleotide. It is capable of complementarily binding at least one sequence variant of a polymorphic locus of a target sequence and thereby forming a perfect match duplex, this sequence variant preferably being a sequence which is at least at one point with the first primer oligonucleotide Mismatch can form.

The respective competitor primer oligonucleotides are preferably constructed in their 3 ^' segment such that each competitor primer oligonucleotide used comprises a specific sequence complementary to a particular sequence variant of the candidate template strands (eg, allele-specific primers). Such competitor primers are able to predominantly complementarily bind to their specific primer binding sites of the respective template strands and to initiate initiation of a synthetic reaction by a polymerase.

In essence, competitor primers are also allele-specific primers which can not interact with the first region of the specific controller oligonucleotide and thus can not initiate strand separation.

Competitor primers are said to substantially compete for binding to the primer binding site of the template strand with the first primer oligonucleotide and to be extended upon complementary binding to its complementary variant template strand from a polymerase, thereby forming a competitor primer extension product arises.

The choice of the sequence of a competitor primer oligonucleotide depends primarily on the requirement to specifically exclude a specific sequence variant of a polymorphic locus from interaction with the first primer oligonucleotide and thus the non-specific interaction between a specific first primer oligonucleotide and a to prevent or minimize in the sequence deviating primer binding site of another sequence variant.

A competitor primer oligonucleotide preferably does not comprise a sequence segment moiety which can interact with the controller oligonucleotide specific for the first primer oligonucleotide.

controller:

At least one controller oligonucleotide constructed in its second region such that it is capable of having only one particular variant of the sequence of a sequence variant-specific first primer oligonucleotide, and thus only one particular variant of the invention, is used Sequence of a possible first primer extension product to bind complementarily in the first region of the primer extension product. If multiple controllers are used, each controller oligonucleotide is constructed sequence-specifically for a particular variant of the sequence. Multiple controller oligonucleotides may be used, which further differ in that they have in their first region a specific sequence which is capable of binding predominantly to the specific first primer oligonucleotide. Thus, there is a possibility for multiplexing coding with different primer / controlling oligonucleotide pairs. Both partners each have specific sequence sections for this pair in the first primer region and in the second primer region, as well as correspondingly in the first and in the second region of the controller oligonucleotide.

Synthesis phase:

During the synthesis phase, primer binding (through the first region of the first primer oligonucleotide) can occur substantially / preferably, discriminating the individual sequence variants of template strands. For this purpose, suitable reaction conditions are preferably used (so-called stringent reaction conditions). The polymerase is able to start synthesis from such correctly complementarily bound primers and synthesizes complementary strands on the basis of the respective template strand. This results in primer extension products which are substantially complementary to the respective template strand. During synthesis, the polymerase can not distinguish between these differences in template strands. The controller oligonucleotide is in double-stranded form in the primer / controller complex during the synthesis phase and does not interfere with the synthesis process.

In the embodiment with competitor oligonucleotides, a competitor-primer bond and extension are additionally carried out in the synthesis phase:

During the synthesis phase, the competitor-primer binding may take place substantially / preferably with discrimination of the individual sequence variants of template strands. For this purpose, suitable reaction conditions are preferably used (so-called stringent reaction conditions). The polymerase is able to start a synthesis of such correctly complementarily bound competitor primers and synthesizes each complementary strands based on the respective template strand. This results in competitor primer extension products which are substantially complementary to the respective template strand. During synthesis, the polymerase can not distinguish between these differences in template strands.

Controlling phase (FIGS. 4, 7 - 11):

Upon completion of the synthesis phase, the release of the controller oligonucleotide from the double-stranded complex primer / controller occurs, eg by increasing the temperature (at a temperature at which the primer / controller complexes are at least partially dissociated, but stable complexes comprising primers). Extension products / template strands are present). The controller oligonucleotide, which is now at least partially in single-stranded form, can through its first region to interact with the second region of the primer and thus start the strand displacement. The progress of the formation of the double strand between the primer extension product and the controller depends on the correspondence of the sequences of the second region of the controller and the synthesized portion of the respective primer extension products.

The synthesis products (primer extension products) differ depending on the primers and template strands used. Due to these differences in the primer extension products, the result of the controlling phase is different. Predominantly, primer extension products with a sufficient degree of complementarity with the second region of the controller oligonucleotide are detached from their template strand. Thus, there is a discrimination between the synthesized primer extension products in the controlling phase: The controller oligonucleotides preferably form double-stranded complexes with complementary primer extension products. In case of a sequence deviation, this double strand formation takes place insufficiently. Due to the reaction conditions chosen (at a temperature at which primer / controller complexes are at least partially dissociated and stable complexes comprising primer extension products / template strands), the primer extension products with sequence differences to controller strands remain predominantly attached to their template strands.

The specifically formed competitor primer extension products can not be released from their template strands under the control of a controller since the competitor primers lack corresponding second regions (primer overhang) which could interact in a complementary manner with the first region of the controller.

The completely or partially detached sequence-specific primer extension product can be used in further analyzes. For example, it can be isolated from the reaction mixture (in bound form on the controller oligonucleotide). Furthermore, it can be used as a binding partner for other oligonucleotides, eg probes. Furthermore, it can even occur as a template strand, for example, after binding of a new primer in the 3 ^' segment of the primer extension product.

For example, the specific primer extension products synthesized in a primer extension reaction can be used as a starting nucleic acid in subsequent amplification procedures.

Synthesis of the primer extension product and interaction with the controller take place in parallel (on-line controlling)

A defective synthesis of primer extension products by polymerases represents a significant problem for the genetic analyzes. For example, individual nucleotides are exchanged by the polymerase during the synthesis (eg instead of a correct one) C is installed a T or instead of an A, a G is installed, etc.). These polymerase errors can falsify the result of the analysis as they alter the content of the sequences. The present embodiment is intended to reduce synthesis errors in fully synthesized primer extension products in a primer extension reaction.

The technical problem of this embodiment is solved by the synthesis of a primer extension product and the elimination of the incorrectly synthesized strands occurring in parallel to synthesis. The elimination of the incorrectly synthesized strands is accomplished by separating the primer extension product from its template before the primer extension product has reached its full length. This separation of the primer extension products takes place with the assistance of a controller oligonucleotide.

The synthesis of the primer extension product and the checking by means of a controller oligonucleotide are carried out in the same way (homogeneous assay), the individual reactions being essentially parallel to one another. This results in an influence of the controller oligonucleotides on the synthesis during the synthesis process. The synthesis of the primer extension product (P1-Ext) during the synthesis phase and the opening of the double strand by means of a controller oligonucleotide (controlling phase) are adapted to one another in such a way that predominantly a processively occurring correct primer extension in a complete synthesis in resulting in a template strand complementary primer extension product. In a non-processive, especially faulty primer extension or in a synthesis with an introduced by the polymerase error in the synthesized strand, however, it comes mainly to an early detachment of the partially extended primer from the template strand by the controller oligonucleotide, the synthesis of respective primer extension product is thereby prematurely interrupted. The product of the prematurely terminated synthesis is preferably bound to a controller oligonucleotide and forms a double-stranded complex which is stable under reaction conditions. Thus, this incomplete product is removed from the further primer extension reaction. In this case, complete primer extension products should preferably be provided which have a higher complementarity with the template strand.

As a result, complete primer extension products are to be synthesized with higher accuracy. The defective primer extension products comprising at least one incorporation error introduced during synthesis by a polymerase are to be selected out.

A preferred embodiment with a homogeneous format is described in which at least one template strand, at least one controller oligonucleotide, at least one primer oligonucleotide, at least one polymerase and dNTPs are present as substrates in a suitable buffer system at the beginning of the reaction. Synthesis phase.

The goal of the synthesis phase is to synthesize a specific primer extension product by polymerase-mediated synthesis using a template strand.

A primer extension reaction comprises a preferably specific primer binding (first region of the primer oligonucleotide) to the template strand at a suitable primer binding site (sequence segment capable of complementary binding to the first region of the primer oligonucleotide) the second region of the primer (primer overhang) preferably does not bind to the template strand and is therefore available for later interaction with the controller. The primer binding site can be completely single-stranded or partially single-stranded so that at least a portion of the first region of the primer can bind sequence-specifically to the primer binding site via formation of complementary base pairs (Watson-Crick rule).

The polymerase can extend such bound to the primer binding site primer oligonucleotides in a template-dependent synthesis of complementary attachment nucleotides into the growing strand of the primer (3 ^'end-OH). This results in a complementary to the template strand primer extension product (P1-Ext). The synthesis of the complementary strand usually takes place as long as the polymerase finds enough substrate in the batch and sufficient sequence segments in the template strand are available in a suitable form for the polymerase as a template. Depending on the polymerase, one of the conditions on the template segment may be that the template strand is single-stranded (using polymerases without strand displacement properties) or else partially double-stranded (using polymerases having strand displacement properties). The synthesis reaction often takes place over a sufficient time (total time of the reaction), so that at more than 1%, in particular more than 10%, in particular more than 30%, in particular more than 50% of the template strands a complete primer extension product can be synthesized.

In a preferred embodiment, primer binding occurs under reaction conditions which do not allow thermodynamically stable binding of the first region of the primer oligonucleotide to the corresponding complementary position in the template. Thus, there is a balance of binding events and dissociation events between the first region of the primer oligonucleotide and the corresponding primer binding site in the template strand. In binding events, complexes are formed which comprise the first region of the primer and the corresponding primer binding positions on the template strand. In dissociation events, these complexes separate into individual components so that no primer extension reaction can start by means of polymerase. Such conditions are present, for example, at reaction temperatures which are about the melting temperature (Tm) of such a complex (P1 / template strand). The melting temperature (Tm) should be measured under the same buffer conditions and concentrations. For example, the Reaction can be carried out under reaction temperatures in the range of Tm -5 ° C to Tm +30 ° C, in particular embodiments in the range of Tm -5 ° C to about Tm +20 ° C, in another particular embodiment in the range of Tm -5 ° C to Tm +10 ° C. Even under such conditions, extension of the primer by a polymerase can occur with sufficient complementarity of the 3 ^' segment of the primer with the template.

The structure of the primers and the controller oligonucleotides, as well as the reaction conditions of the synthesis phase are chosen such that the complex comprising primer / controller oligonucleotide is predominantly in equilibrium with its individual components (complex formation and complex dissociation occur parallel to each other) , Such conditions are for example at reaction temperatures, which are about the melting temperature (Tm) of such a complex (primer / controller oligonucleotide). The melting temperature (Tm) should be measured under the same buffer conditions and concentrations. For example, the reaction may be carried out at reaction temperatures in the range of Tm -5 ° C to Tm + 30 ° C, in particular embodiments between about Tm -5 ° C to about Tm + 20 ° C, in another particular embodiment between about Tm - 5 ° C to about Tm + 10 ° C, in certain embodiments between about Tm -5 ° C to about Tm + 5 ° C, in another particular embodiment between about Tm - 5 ° C to about Tm -2 ° C. The choice of such conditions can be determined experimentally in individual cases by measuring the melting temperatures (Tm) for such complexes.

Even if the primer is used in excess of the controller oligonucleotide, preferably no complete saturation of the controller oligonucleotide by the primer oligonucleotide takes place.

Under such reaction conditions, formation and dissociation of primer / primer-binding site complexes as well as formation and dissociation of primer / controller-oligonucleotide complexes occur. The structures and reaction conditions are adapted to each other in such a way that, under such conditions, extension of the primer by a polymerase can occur with sufficient complementarity of the 3 ^' segment of the primer with the template.

Combinations of structures of the individual components and the reaction conditions are advantageous, which even with a primer extension of only a few nucleotides lead to the fact that even an incompletely extended primer extension product can be more tightly bound to the controller oligonucleotide than a primer that is still extender. This is usually done by allowing the controller oligonucleotide to form a complementary bond with a primer extension product with its third region, thus having additional binding positions compared to a primer / controller complex. Such a more stable binding also allows incompletely extended primers to form complexes with controller oligonucleotides and, due to sufficient stability of these complexes, be removed from the reaction. Since the controller oligonucleotide does not support matrix function (eg, by modification), incompletely extended, to the controller Oligonucleotide bound primer not completed. For this reason, preferably the entire third region of the controller oligonucleotide comprises such modifications. The continuation of the synthesis of such incompletely extended primer / controller complexes can only take place when they are released again from the complex with the controller oligonucleotide. Due to advantageous selected reaction conditions, however, this is done only to a very limited extent. Thus, incompletely extended primer extension products can be bound in complexes with controller oligonucleotides during the synthesis reaction.

The controller oligonucleotide may interact during the ongoing primer extension reaction (in parallel with this reaction) with both primer oligonucleotides, partially extended primers, and fully extended primers. This interaction begins at the second region of the primer.

polymerases:

In this preferred embodiment, predominantly sufficient processive polymerases are used, e.g. Bst-Large fragment, Phi29 polymerase or polymerases with improved processivity (e.g., phage polymerase is a result of a coupling of a thermostable polymerase with a protein that extends the binding of the polymerase to the DNA) or their modifications. This results in a strand synthesis quickly, so that even during the synthesis resulting installation errors are overcome quickly. Preferably, controller oligonucleotides are used in concentrations of about 0.1 mM to about 20 pM. This allows a sufficiently frequent interaction with primer extension products so that an impact on the quality of primer extension products is expected.

In another embodiment, lower processivity polymerases (e.g., Taq polymerase, Vent polymerase, Pfu polymerase) are used. As a result, the synthesis generally proceeds more slowly and requires repeated binding events of the polymerase. For this reason, controller concentrations of about 5 nM to about 1 pM are preferably used here.

Polymerases are predominantly able to attach several nucleotides (eg more than 15 nucleotides, better more than 30 nucleotides, preferably more than 50 nucleotides) to the growing end of the primer or primer in the case of only one binding event to a primer / template strand complex. Extension product to tie. In contrast, low-affinity polymerases, such as Taq polymerase and Klenow polymerase, or entirely distributive polymerases, which bind only a few nucleotides in a binding event (usually less than 8 to 15 nucleotides). A predominantly processive synthesis is thus associated with the synthesis within a binding event of the polymerase to the primer-template complex.

Furthermore, the high processivity of the polymerase is favored by sufficient complementarity of the 3 ^' end of the growing primer extension product. In general, the synthesis is carried out at high speed and processively particularly advantageous when the 3 ^' end of the strand to be elongated fulfills a structural requirement for complementarity given by the template (as a rule, this refers to a complementary, perfect-match situation in the case of nucleobases between the 3 ^' end or 3 ^' segment of the strand to be elongated and the corresponding template ). Deviations from this, ie mismatches between the 3 ^' end or 3 ^' segment of the strand to be extended (eg positions -1 to - 5) and the template strand usually lead to a more or less pronounced slowing down or even pausing of the synthesis the polymerase. This slowdown in the rate of polymerase catalysis is known to one skilled in the art. The extent of such slowing or pausing in catalysis depends on both the polymerase and the reaction conditions (eg, concentration of dNTPs) as well as the nature of the mismatch. The continuation of the synthesis beyond such a mismatch usually requires a longer reaction time.

Since all polymerases perform the template-dependent catalysis with only limited precision, a more or less pronounced false synthesis of a primer extension product occurs with each primer extension. During a template-dependent synthesis, misincorporation events take place (e.g., a dCTP is incorporated instead of a dTTP over an adenosine in the template strand). This leads to more or less pronounced breaks in the synthesis.

By using a sufficiently long reaction time, such a mismatch position (comprising, as a rule, one to two nucleotides) can be overcome by the polymerase and the template-dependent synthesis can as a rule be continued. The extent of overcoming depends on both the type of mismatch and polymerase.

Polymerases may or may not both comprise a 3 ^' exonuclease activity (proofreading polymerases, eg, phage polymerase) (Bst-Large Fragment). Depending on the type of template used, DNA-dependent polymerases or RNA-dependent polymerases can be used.

template strand:

The template strand comprises a primer binding site such that under selected reaction conditions binding of the first region of the primer occurs and polymerase mediated synthesis of the strand can occur. Furthermore, a template strand comprises a target sequence. This target sequence usually represents the sequence segment of the template strand, which performs the template function for the synthesis of the complementary strand. Preferably, the template strand and the primer oligonucleotide are adapted in their design such that the second region of the primer oligonucleotide does not bind to the template strand, or at least does not form stable binding, and thus is potentially able to interfere with the first region of the controller. Oligonucleotide to interact. In general, both DNA and RNA can occur as template strands. The primer binding site of the template is preferably in a single-stranded form and allows for site-specific binding of the first region of the primer oligonucleotide to the template.

The segment of the template strand which serves as a template for the synthesis of the complementary strand by the polymerase may, in certain embodiments, be wholly or predominantly (more than 50%) single-stranded under reaction conditions. In another embodiment, this segment is predominantly (more than 50%) double-stranded. The polymerases used in the synthesis must be selected accordingly. For single-stranded templates, polymerases can be used without marked strand displacement, e.g. Phusion polymerase. For predominantly double-stranded segments of the template, preference is given to using polymerases having strand-displacing properties, e.g. Bst polymerase Large Fragment.

primer:

In certain embodiments, the primer binding site may be for the primer in the 3 ^' segment of the template. In such an embodiment, it is advantageous if the primer oligonucleotide comprises a modification which prevents the polymerase from copying the second primer region.

In another embodiment, the template in its 3 ^' segment can go well beyond the primer binding site of the primer. The length of such an overhang can range from a few nucleotides to several kilobases. The structure of such a template strand results in the primer overhang not being copied by the polymerase starting from the 3 ^' end of the template. Therefore, in such an embodiment, the primer need not necessarily comprise a block group in the second region of the primer.

The synthesis of the primer extension product via polymerase as a template-dependent synthesis. It is advantageous if the progress of the synthesis of the primer extension product is limited and thus a desired primer extension product is limited in its length.

The length of the complete primer extension product is preferably limited by availability of a sequence segment of the template which can be used by the polymerase for synthesis. This can be achieved, for example, by limiting the matrix strand in the 5 ^' segment. This limitation prevents the polymerase used from continuing the synthesis. Such a limitation can be achieved, for example, by strand termination (strand termination achieved eg by physical action or by an enzyme, eg an endonuclease or a restriction endonuclease) or by using one or more modifications in the strand (eg spacer or linker) prevent the polymerase from being synthesized, or by nucleotide Modifications (eg nucleobase modification as Iso-C and Iso-G, or the sugar-phosphate moieties such as 2 ^'-0-Me, ^2' MOE, morpholino, PNA etc.).

Using long template strands, e.g. genomic DNA or mRNA or long PCR fragments, it is advantageous if the synthesis of the polymerase is stopped or stopped by using additional oligonucleotides on predetermined segments. In such an embodiment, the progress of the synthesis of the primer extension product is limited by using a so-called block oligonucleotide. Such a block oligonucleotide may preferably hybridize under sequence conditions of the synthesis phase predominantly sequence-specifically to the template strand via complementary binding. Such a block oligonucleotide, when attached to the template strand, prevents the polymerase from reading the template strand beyond that oligonucleotide. Depending on the type of polymerase used and its equipment, different oligonucleotides are suitable for this purpose. The selection of the oligonucleotide structure, the polymerase and the reaction conditions are based on the fact that the progressive synthesis is hindered or blocked by the polymerase.

Examples of such oligonucleotides leading to the stop are known to a person skilled in the art.

An example is the prevention of polymerases with strand displacement properties. Oligonucleotides with several double strand stabilizing modifications, e.g. LNA or PNA typically results in the polymerase being unable to continue synthesis via the oligonucleotide binding site. For example, template-complementary oligonucleotides of about 20-50 nucleotides in length with about 7-30 LNA modifications, for example, a Bst polymerase (large fragment), can prevent this oligonucleotide from detaching via polymerase-dependent strand displacement from the template.

The length of the complete P1-ext generated during template-dependent synthesis and the length of the matching controller oligonucleotide can be chosen differently.

In certain embodiments, the length of the controller oligonucleotide and the length of the expected fully synthesized primer extension product are matched so that the controller oligonucleotide completely covers the region synthesized by the polymerase. In this embodiment, a controller oligonucleotide can completely detach the P1 -ext from the template. In the 3 ^' segment of the P1 -ex, no free nucleotides remain for interaction with the template during the controlling phase (see below)

In a further preferred embodiment, the length of the controller oligonucleotide and the length of the expected primer extension product are matched to one another such that the length of the synthesized region of the primer extension product extends beyond the length of the controller oligonucleotide. The 3 ^' segment of the primer extension product thus comprises a sequence segment which does not belong to the controller Oligonucleotide is checked. When the P1-Ext interacts with the controller, a double-stranded segment of P1-Ext and matrix remains, which is not checked by the controller.

In certain embodiments, this double-stranded segment can spontaneously dissociate under the reaction conditions of the controlling phase, eg due to a temperature-induced strand opening (eg at temperatures of about 50-70 ° C). The length of this 3 ^' segment of the primer extension product (without interaction with controller oligonucleotide) may comprise, for example, sequence lengths which lie in the following ranges: from 1 to 10 nucleotides, from 10 to 20 nucleotides, from 30 to 40 nucleotides, from 40 to 50 nucleotides, from 50 to 70 nucleotides, from 70 to 100 nucleotides.

In certain embodiments, this double-stranded segment can not spontaneously dissociate under the reaction conditions of the controlling phase, eg due to a temperature-induced strand opening (eg at temperatures of about 50-70 ° C). The length of this 3 ^' segment of the primer extension product (without interaction with controller oligonucleotide) may comprise, for example, sequence lengths which lie in the following ranges: more than 20 nucleotides, more than 30 nucleotides, more than 40 nucleotides, more than 50 nucleotides, more than 100 nucleotides, more than 200 nucleotides, more than 500 nucleotides. The maximum length can reach up to about 10,000 nucleotides.

Controlling phase (Fig. 4, 7 - 11).

The aim of the controlling phase is to check the synthesized primer extension product for its agreement with the given sequence during the ongoing synthesis (real-time control). The correct, fully complementary primer extension products are to be synthesized in full length. The resulting during the synthesis of misincorporation events by the polymerase from the further extension reaction should be excluded. In particular, mismatches between primer extension products resulting from a polymerase during synthesis are to be prevented from lengthening on the template strand. This is done by forming a complex of such a mismatch-containing primer extension product and a controller oligonucleotide during the primer extension reaction. The terminal mismatch-containing primer extension products bound to the controller oligonucleotide should preferably remain in these complexes under reaction conditions. Thus, primer extension products in which the progress of the synthesis reaction is slowed down (e.g., due to polymerase mismatch incorporation, ie, polymerase errors) are prematurely released from their template strand even before their full length synthesis can be completed. This prevents complete synthesis of a defective primer extension product.

By repeated interactions between the controller oligonucleotide and the primer oligonucleotides and between the controller oligonucleotide and the primer Extension products (the interaction begins with the binding of the controller to the primer overhang) as they are generated, there is competition between the synthesis process and a strand displacement event by the controller oligonucleotide. These reactions can be adjusted by changing the concentrations of the individual components. Thus, for example, the concentration of controller oligonucleotides can be varied between 0.001 pmol / l and 50 pmol / l, in particular between 0.01 pmol / l and 10 pmol / l. Thus, for example, with constant held primer extension reaction, the extent of the controller-dependent strand displacement can be influenced.

The freely available controller oligonucleotides can interact with the second primer region (primer overhang). Among other things, interactions with complexes comprising primer extension products and template strands occur. The interaction starts from the primer overhang. This provides spatial proximity between the controller strand and the end of the double-stranded region between primer extension product / template strand. As a result, the double-stranded formation can be transferred between the controller oligonucleotide and the first primer region (sequence-dependent strand displacement). Given the sequence identity with the synthesized portion of the primer extension product, the double strand formation between the controller oligonucleotide and the primer extension product continues to expand.

The progression of this interaction between the synthesized primer extension product and the controller oligonucleotide results in increasing release of the template strand from the complex with the primer extension product. An incomplete primer extension product will dissociate the template and incomplete primer extension product complex. A new complex of primer extension product and the controller oligonucleotide is thereby formed. The continuation of the template-dependent synthesis of such a primer extension product is thus hindered.

The use of processive polymerases typically results in the primer extension reaction by the polymerase with full match of the synthesized growing strand to its template being faster than forming a double-stranded complex of primer extension product and controller oligonucleotide.

Furthermore, the time delay of the enzymatic synthesis is exploited, which usually takes place in a strand extension process, when this strand comprises a mismatch as a result of a polymerase error. The perfect-match strands are generally synthesized faster than those that have a mismatch in the primer extension product. After a misincorporation into the growing strand, there is a temporary slowdown or even a pause in the synthesis, so that the process of double-stranding between the controller oligonucleotide and the primer extension product can detach this "paused strand" from the template before a further synthesis can take place. The binding of such an incomplete primer extension product to the controller oligonucleotide is preferably sufficiently stable under reaction conditions used so that this incomplete product can be removed from the further template-dependent syntheses by the polymerase. Since the controller oligonucleotide does not serve as a template, such an incomplete primer extension product will remain in complex with the controller oligonucleotide.

In a preferred embodiment, the length of the controller oligonucleotide and the length of expected full primer extension product are matched so that the length of the synthesized region of the primer extension product extends beyond the length of the controller oligonucleotide. The 3 ^' segment of the primer extension product thus comprises a sequence segment which is not checked by the controller oligonucleotide. The interaction of the P1-text with the controller thus leaves a double-stranded segment of P1-text and matrix. In this embodiment, this double-stranded segment can spontaneously dissociate under the reaction conditions of the controlling phase, for example due to a temperature-induced strand opening (eg at temperatures of about 50-70 ° C). The length of this 3 ^' segment of the primer extension product (without interaction with the controller oligonucleotide) may comprise, for example, sequence lengths ranging from 1 to 10 nucleotides, from 10 to 20 nucleotides, from 30 to 40 nucleotides, from 40 to 50 nucleotides. The interaction of the controller oligonucleotide interaction with the synthesized primer extension product and the spontaneous dissociation of the 3 ^' segment complex of the P1 -ext and template may result in the detachment of the primer extension product (in the complex of P1 -ext and controller-strand ) from the matrix.

The 3 ^' segment may play a functional role in subsequent analyzes / reactions. In a preferred embodiment, the complexes formed controller oligonucleotide and incomplete primer extension product are preferably sufficiently stable under the chosen reaction conditions, so that this incomplete primer extension product can be excluded from a continuation of its synthesis at the template strand or by the complex form with the controller strongly prevented the continuation of the template-dependent synthesis reaction. Thus, the synthesis of defective primer extension products can be prevented to full synthesis length. Because of insufficient length, such incomplete P1 text preferably does not include a required 3 ^' sequence segment to participate in other or subsequent reactions. This missing 3 ^' segment can be used, for example, for interaction with a probe or a probe another primer is missing. As a result, defective primer extension products can not develop the full functionality required in subsequent reactions, eg in a detection process or an amplification.

Discriminating effect of the controller oligonucleotide:

Even with concurrent synthesis reaction and controlling phase, the interaction between the controller oligonucleotide and the primer extension product depends on the complementarity between the primer extension product and the controller oligonucleotide. In case of deviations, the process of sequence-dependent strand displacement can be severely hindered. The higher the sequence differences between the synthesized primer extension product and the corresponding controller oligonucleotide, the more the formation of a complex of controller oligonucleotide and P1 -ex is affected. The degree of influence can range from slight deceleration to complete stop in the progress of complex formation. For this reason, it is advantageous if the controller oligonucleotide is adapted to the desired primer extension product and is able to enter into its third region with a substantially complementary binding to the synthesized sequence segment of the primer extension product.

Upon completion of the primer extension reaction, the correctly synthesized primer extension product may be released from the template, for example as shown in the above embodiments.

For example, the use of a primer extension product in further reactions may require that certain portions of the primer extension product be in single-stranded form. This may be necessary, for example, for the binding of a primer or a probe. This embodiment can therefore be used, for example, to convert the sequences in the 3 ^' segment of the primer extension product into the single-stranded state.

This discriminating effect from the controller after a primer extension reaction can be used for several technical tasks. The availability of controller oligonucleotides in the assay (homogeneous assay format) allows for both low-contamination integration into other methods of molecular analysis and combination with other methods, e.g. with amplification method or detection method.

Preferred Embodiments of Structures of Individual Components:

The primer extension reaction described herein comprises at least a first primer and at least one controller oligonucleotide. The product of the primer extension reaction, the primer extension product, can be used, for example, in a subsequent amplification reaction, which also proceeds with the assistance of a controller oligonucleotide.

For this reason, it is advantageous that components of the primer extension reaction (first primer and controler oligonucleotide) can also be used in an amplification reaction.

In the following, therefore, embodiments will be described which may be suitable for both reactions, both for a primer extension reaction and for a specific amplification. If required, however, different components can also be used in individual reactions.

reaction conditions

Reaction conditions include, but are not limited to, buffer conditions, temperature conditions, duration of reaction, and concentrations of respective reaction components.

The reaction comprising the synthesis of the extension products can be carried out for as long as necessary to produce the desired amount of the specific nucleic acid sequence. The process according to the invention is preferably carried out continuously. In a preferred embodiment, the amplification reaction proceeds at the same reaction temperature, wherein the temperature is in particular between 50 ° C and 75 ° C. In another embodiment, the reaction temperature can also be variably controlled, so that individual steps of the primer extension reaction proceed at different temperatures.

In particular, no helicases or recombinases are used in the reaction mixture to separate the newly synthesized duplexes of the nucleic acid to be amplified.

In a preferred embodiment, the reaction mixture does not include biochemical energy-donating compounds such as ATP.

The amount of nucleic acid to be amplified at the beginning of the reaction can be between a few copies and several billion copies in one run. For diagnostic applications, the amount of template comprising a target sequence may be unknown.

The reaction may also contain other nucleic acids which are not to be amplified. These nucleic acids may be derived from natural DNA or RNA or their equivalents. In certain embodiments, control sequences are in the same approach, which should also be amplified in parallel to the nucleic acid to be amplified.

A molar excess of about 10 ³ : 1 to about 10 ¹⁵ : 1 (primer: template ratio) of the primers employed and the controller oligonucleotide may be added to the reaction mixture, which comprises template strands. The amount of target nucleic acids may not be known if the method of the invention is used in diagnostic applications, so that the relative amount of the primer and the controller oligonucleotide relative to the complementary strand can not be determined with certainty. The amount of primer added will generally be present in molar excess relative to the amount of complementary strand (template) when the sequence to be amplified is contained in a mixture of complicated long-chain nucleic acid strands. A large molar excess is preferred to improve the efficiency of the process.

The concentrations of primer-1 and controller oligonucleotide used are, for example, in the range between 0.01 pmol / l and 100 pmol / l, in particular between 0.1 pmol / l and 100 pmol / l, in particular between 0.1 pmol / l and 50 pmol / l, in particular between 0.1 pmol / l and 20 pmol / l. The high concentration of components can increase the rate of amplification. The respective concentrations of individual components can be varied independently of one another in order to achieve the desired reaction result.

The concentration of polymerase ranges between 0.001 pmol / l and 50 pmol / l, in particular between 0.01 pmol / l and 20 pmol / l, in particular between 0.1 pmol / l and 10 pmol / l.

The concentration of individual dNTP substrates is in the range between 10 pmol / l and 10 mmol / l, in particular between 50 pmol / l and 2 mmol / l, in particular between 100 pmol / l and 1 mmol / l. The concentration of dNTP can affect the concentration of divalent metal cations. If necessary, this will be adjusted accordingly.

As divalent metal cations, for example, Mg ²⁺ are used. As a corresponding anion, for example, CI, acetate, sulfate, glutamate, etc. can be used.

The concentration of divalent metal cations is adapted, for example, to the optimum range for each polymerase and comprises ranges between 0.1 mmol / l and 50 mmol / l, in particular between 0.5 mmol / l and 20 mmol / l, in particular between 1 mmol / l and 15 mmol / l.

The enzymatic synthesis is generally carried out in a buffered aqueous solution. As buffer solutions, dissolved conventional buffer substances, such as Tris-HCl, Tris-acetate, potassium glutamate, HEPES buffer, sodium glutamate in conventional concentrations can be used. The pH of these solutions is usually between 7 and 9.5, in particular about 8 to 8.5. The buffer conditions can be adapted, for example, according to the recommendation of the manufacturer of the polymerase used.

Other substances, such as so-called Tm depressors (eg DMSO, betaines, TPAC) etc. can be added to the buffer. Such substances reduce the melting temperature ("Tm depressors") of double strands and can thus have a positive influence on the opening of double strands. Polymerase stabilizing components such as Tween 20 or Triton 100 can also be added in conventional amounts to the buffer. EDTA or EGTA may be too Complexation of heavy metals can be added in conventional amounts. Polymerase stabilizing substances such as trehalose or PEG 6000 may also be added to the reaction mixture.

Preferably, the reaction mixture contains no inhibitors of the strand displacement reaction and no inhibitors of polymerase-dependent primer extension.

In certain embodiments, the reaction mixture contains DNA-binding dyes, especially intercalating dyes, such as e.g. EvaGreen or SybrGreen. Such dyes may possibly enable the detection of the formation of new nucleic acid chains.

The reaction mixture can furthermore contain proteins or other substances which, for example, originate from an original material and which preferably do not influence the amplification.

The reaction temperatures of the individual steps of the amplification reaction can be in the range of about 15 ° C to about 85 ° C, in particular in the range of about 15 ° C to about 75 ° C, in particular in the range of about 25 ° C to about 70 ° C.

In general, the reaction temperature can be optimally adjusted for each individual reaction step, so that such a temperature is brought about for each reaction step. The amplification reaction thus comprises a repetitive change of temperatures, which are repeated cyclically. In certain embodiments of the method, reaction conditions for a plurality of reaction steps are standardized so that the number of temperature steps is less than the number of reaction steps. In such a particular embodiment of the invention, at least one of the steps of amplification occurs at a reaction temperature which differs from the reaction temperature of other steps of the amplification. The reaction is thus not isothermal, but the reaction temperature is changed cyclically.

For example, during the amplification at least two temperature ranges are used, which are brought about alternately (cyclic change of temperatures between individual temperature ranges). In certain embodiments, the lower temperature range includes, for example, temperatures between 25 ° C and 60 ° C, in particular between 35 ° C and 60 ° C, in particular between 50 ° C and 60 ° C and the upper temperature range includes, for example, temperatures between 60 ° C and 75 ° C, especially between 60 ° C and 70 ° C.

In certain embodiments, the lower temperature range includes, for example, temperatures between 15 ° C and 50 ° C, in particular between 25 ° C and 50 ° C, in particular between 30 ° C and 50 ° C and the upper temperature range includes, for example, temperatures between 50 ° C and 75 ° C, especially between 50 ° C and 65 ° C. In certain embodiments, the lower temperature range includes, for example, temperatures between 15 ° C and 40 ° C, in particular between 25 ° C and 40 ° C, in particular between 30 ° C and 40 ° C and the upper temperature range includes, for example, temperatures between 40 ° C and 75 ° C, especially between 40 ° C and 65 ° C.

The temperature can be kept constant in the respective range or can be changed as a temperature gradient (decreasing or rising).

Further explanations on temperature settings are detailed in the following sections of embodiments.

Any induced temperature can be maintained for a period of time, resulting in an incubation step. The reaction mixture may thus be incubated for a period of time during amplification at a selected temperature. This time may be of different duration for the particular incubation step and may depend on the progress of the particular reaction at a given temperature (e.g., primer extension or strand displacement, etc.). The time of an incubation step may comprise the following ranges: between 0.1 sec and 10,000 sec, in particular between 0.1 sec and 1000 sec, in particular between 1 sec and 300 sec, in particular between 1 sec and 100 sec.

By such a temperature change, individual reaction steps can preferably be carried out at a selected temperature. As a result, yields of a particular reaction step can be improved. Within a synthesis cycle, a change in temperature or a temperature change between individual temperature ranges may be required several times. A synthesis cycle may thus comprise at least one temperature change. Such a temperature change can be performed routinely, for example, in a PCR device / thermocycler as a time program.

In certain embodiments, an amplification method is preferred in which at least one of the steps comprising the strand displacement and at least one of the steps comprising the primer extension reactions take place simultaneously and in parallel and under the same reaction conditions. For example, in such an embodiment, a primer extension reaction of at least one primer oligonucleotide (e.g., of the first primer oligonucleotide) may preferably be performed at temperature conditions in the lower temperature range. On the other hand, the strand displacement with the aid of controller oligonucleotide and the one further primer extension reaction (for example, of the second primer oligonucleotide) are preferably carried out in the reaction step in the upper temperature range.

In certain embodiments, an amplification method is preferred in which at least one of the steps comprising strand displacement by the controller oligonucleotide and at least one of the steps comprising the primer extension reaction are performed at different temperatures. In such an embodiment, for example, primer extension reactions of at least one primer oligonucleotide (For example, from the first primer oligonucleotide and / or second primer oligonucleotide) preferably carried out at temperature conditions in the lower temperature range. By contrast, the strand displacement with the assistance of controller oligonucleotide preferably takes place in the reaction step in the upper temperature range.

In a further preferred embodiment, all steps of an amplification reaction proceed under identical reaction conditions.

In such an embodiment, the amplification process may be carried out under isothermal conditions, i. that no temperature changes are required to carry out the process. In such a particular embodiment of the invention, the entire amplification reaction is carried out under constant temperature, i. the reaction is isothermal. The time of such a reaction comprises, for example, the following ranges: between 100 sec and 30,000 sec, in particular between 100 sec and 10,000 sec, in particular between 100 sec and 1000 sec.

Individual process steps can each be carried out in succession by adding individual components. In an advantageous embodiment, all reaction components necessary for the execution of an amplification are present at the beginning of an amplification in a reaction mixture.

The start of an amplification reaction can be carried out by adding a component, e.g. by adding a nucleic acid chain comprising a target sequence (e.g., a starting nucleic acid chain), or a polymerase or divalent metal ions, or also by providing reaction conditions necessary for amplification, e.g. Setting a required reaction temperature for one or more process steps.

The amplification can be carried out until the desired amount of nucleic acid to be amplified is reached. In another embodiment, the amplification reaction is carried out for a time which would have been sufficient in the presence of a nucleic acid to be amplified in order to obtain a sufficient amount. In another embodiment, the amplification reaction is carried out over a sufficient number of synthesis cycles (doubling times) which would have been sufficient in the presence of a nucleic acid to be amplified in order to obtain a sufficient amount.

The reaction can be stopped by various interventions. For example, by changing the temperature (e.g., cooling or heating, for example, interfering with the function of the polymerase) or by adding a substance which stops a polymerase reaction, e.g. EDTA or formamide.

Following amplification, the amplified nucleic acid chain can be used for further analysis. In this case, synthesized nucleic acid chains can be analyzed by various detection methods. For example, fluorescence-labeled oligonucleotide probes can be used or sequencing methods (Sanger sequencing or next-generation sequencing), solid-phase analysis such as microarray or bead-array analysis, etc. The synthesized nucleic acid chain can be used as a substrate / template in further primer extension reactions.

In certain embodiments, the progress of the synthesis reaction is monitored during the reaction. This can be done, for example, by using intercalating dyes, e.g. Sybrgreen or Evagreen, or using labeled primers (e.g., Lux primer or Scorpion primer) or using fluorescently labeled oligonucleotide probes.

The detection of the change in fluorescence during amplification is implemented in a detection step of the method. The temperature and the duration of this step can be adapted to the particular requirements of an oligonucleotide probe. The temperatures of the detection step include, for example, ranges between 20 ° C and 75 ° C, in particular between 40 and 70 ° C, in particular between 55 and 70 ° C.

During the detection step, the reaction is illuminated with light of a wavelength capable of exciting a used fluorophore of the detection system (a donor or a fluorescent reporter). The signal detection is usually parallel to excitation, whereby the specific fluorescence signal is detected and its intensity is quantified.

The amplification method can be used to verify the presence of a target nucleic acid chain in a biological material or diagnostic material as part of a diagnostic procedure.

In certain embodiments, reaction conditions of at least one reaction step in which at least one allele-specific primer is to hybridize to an allele-specific sequence variant and a primer extension reaction by a polymerase is to be chosen such that a predominantly specific hybridization of such a primer to its Primer binding site can take place. Such conditions can also be called stringent conditions. For example, the temperature in such a step is about Tm of the respective primer / primer binding site or the temperature is above such a Tm. For example, the temperature may be about Tm +5 to about Tm + 15 ° C.

Preferred Embodiments of the First Primer Oligonucleotide (Primer-1)

The first primer oligonucleotide (primer-1) is a nucleic acid chain which includes at least the following regions:

A first primer region in the 3 ^' segment of the first primer oligonucleotide capable of substantially sequence-specific binding to a strand of nucleic acid chain to be amplified

A second region, coupled directly or via a linker, to the 5 ^' end of the first primer region of the first primer oligonucleotide which has a polynucleotide Which is suitable for binding a controller oligonucleotide and promoting strand displacement (step c) by the controller oligonucleotide, wherein the polynucleotide tail remains substantially single-stranded under reaction conditions, ie, does not form a stable hairpin structure or ds structures, and preferably not copied by the polymerase.

The total length of the first primer oligonucleotide is between 10 and 80, more preferably between 15 and 50, more preferably between 20 and 30 nucleotides or their equivalents (e.g., nucleotide modifications). The structure of the first primer oligonucleotide is adapted to undergo reversible binding to the controller oligonucleotide under selected reaction conditions. Furthermore, the structure of the first primer oligonucleotide is adapted to its primer function. Furthermore, the structure is adapted so that a strand displacement can be performed by means of controller oligonucleotide. Overall, structures of the first and second regions are matched to each other so that exponential amplification can be performed.

In certain embodiments of the invention, the first and second regions of the primer are coupled in a conventional 5 ^' -3 ^' configuration. In certain embodiments of the invention, the coupling of both sections is via a 5 ^' -5 ^' bond such that the second region has a reverse direction from the first region.

The coupling of areas between each other / each other is preferably covalent. In certain embodiments, the coupling between the first and second regions is a conventional DNA for ^{5'-3 ^{'-Phosphodiester}} coupling. In certain embodiments, it is a 5 ^{^'-5'} -Phosphodiester coupling. In certain embodiments, it is a 5 ^{^'-3'} - phosphodiester linkage, wherein between adjacent terminal nucleotides or nucleotide modifications of the two regions at least one linker (eg, a C3, C6, C12 or HEG linker or abasic modification) is positioned.

Individual regions may include different nucleotide modifications. In this case, individual elements of nucleotides can be modified: nucleobase and backbone (sugar content and / or phosphate content). Furthermore, modifications may be used which lack or are modified at least one component of the standard nucleotide building blocks, e.g. PNA.

In certain embodiments, a second portion of the first primer oligonucleotide includes additional sequences that do not bind to the controller oligonucleotide. These sequences can be used for other purposes, such as binding to the solid phase. These sequences are preferably located at the 5 ^' end of the polynucleotide tail.

In certain embodiments, a first primer oligonucleotide may comprise a characteristic label. Examples of such markings are dyes (eg FAM, TAMRA, Cy3, Alexa 488 etc.) or biotin or other groups which can be specifically bound, eg digoxigenin.

The first primer region of the first primer oligonucleotide

The sequence length is between about 3-30 nucleotides, in particular between 5 and 20 nucleotides, the sequence being predominantly complementary to the 3 ^' segment of a strand of the nucleic acid chain to be amplified. In particular, this primer region must be able to specifically bind to the complementary 3 ^' segment of a second primer extension product. This first area should be copied in the reverse synthesis and also serves as a template for the 2nd strand. The nucleotide building blocks are preferably linked to each other via conventional 5 ^'to ^3' Phosphodieser bond or Phosphothioester bond.

The first primer region preferably includes nucleotide monomers which do not or only insignificantly influence the function of the polymerase, for example:

• natural nucleotides (dA, dT, dC, dG etc.) or their modifications without altered base pairing

• Modified nucleotides, 2-amino-dA, 2-thio-dT or other nucleotide modifications with deviant base pairing.

In a preferred embodiment, the 3 ^'OH end of this range preferably free of modifications and has a functional ^3' -OH group, that can be recognized by the polymerase. The first primer region serves as the initiator of the synthesis of the first primer extension product in the amplification. In a further preferred embodiment, the first region comprises at least one phosphorothioate compound, so that no degradation of the 3 ^' end of the primer by the 3 ^' exonuclease activity of polymerases can take place.

The sequence of the first region of the first primer oligonucleotide and the sequence of the second region of the controller oligonucleotide are preferably complementary to one another.

In certain embodiments, the first primer region or its 3 ^' segment can bind to the sequence segments of a target sequence.

In certain embodiments, an allele-specific first primer is used in combination with an allele-specific controller oligonucleotide.

The first primer region of the first primer can bind to the corresponding complementary position of a starting nucleic acid or of a nucleic acid chain to be amplified. In particular, a first primer region comprises at least one sequence segment which can bind specifically under specific reaction conditions to an allele-specific sequence variant of the target nucleic acid, wherein the polymerase is able to extend a perfect-match complex formed thereby, so that a first Primer extension product results. The position of an allele-specific sequence in the primer, in certain embodiments, includes the 3 ^' -terminal nucleotide. In another embodiment, the position of an allele-specific sequence in the primer comprises at least one of the positions -1 to -6 nucleotides in the 3 ^' terminal segment of the first region of the first primer. In another embodiment, the position of an allele-specific sequence in the primer comprises at least one of the positions from -6 to at least -15 in the 3 ^' terminal segment of the first region of the first primer.

Such a primer further comprises sequence segments which can bind in a uniform manner to all allelic variants of a target sequence in a uniform manner. Thus, the first region of a first allele-specific primer comprises sequence segments which are both target sequence-specific and those which are allele-specific.

Preferably, a combination of an allele-specific primer and an allele-specific controller oligonucleotide is used, wherein the first region of the first primer oligonucleotide is completely complementary to the second region of the controller oligonucleotide.

Single allele-specific primers can be grouped together to cover all variants of a target sequence. Such a group of allele-specific primers comprises at least two different allele-specific primers, as a polymorphic locus at a given position in the target sequence comprises at least two sequence variants. The allele-specific primers are designed to perfectly match under stringent reaction conditions, preferably with their specific template, and thus use this specific perfect-match template to form the respective primer extension products under the catalytic action of the polymerase. Preferably, 3 ^' -terminal nucleotides and / or 3 ^' -terminal segments of allele-specific primers can be used to discriminate variants of target sequences and are thus adapted in their sequence composition to the respective variants such that such primers adopt a perfect-match duplex form stringent conditions with the respective variant. Such perfect-match double strands can usually be recognized well by a polymerase and under suitable reaction conditions a primer extension occurs. The interaction of an allele-specific primer with another variant of a target sequence thus results in a mismatch double strand. Such mismatches usually lead to a delay in the extension by a polymerase or to a slowing of the overall reaction. In certain embodiments, allele-specific primers in the 3 ^' segment may include at least one phosphorothioate linkage that protects the allele-specific primers from 3 ^' -5 ^' nuclease degradation by a polymerase.

Thus, multiple allele-specific primers include sequence segments which are substantially identical for a group of allele-specific primers, as well as sequence segments which are different among the primers of a group and characteristic of the respective sequence variant of a target sequence. Including uniform sequence segments, such primers can hybridize to the respective target sequence under Reaktionsbedinungen. Including characteristic sequence segments, a respective primer can specifically bind to a sequence variant of the target sequence to form a perfect-match double strand. Preferably, the primers are designed so that, under the reaction conditions used, binding to a target sequence to form a perfect match double strand is preferred and binding to a target sequence to form a mismatch duplex is less preferred.

In certain embodiments, a target sequence-specific first primer (but not an allele-specific first primer) is used in combination with an allele-specific controller oligonucleotide.

The first primer region of the first primer can bind to the corresponding complementary position of a starting nucleic acid or of a nucleic acid chain to be amplified. Preferably, a first primer region comprises at least one sequence segment, which preferably can bind sequence specifically under reaction conditions used to sequence segments of a target nucleic acid chain (for example comprising a start nucleic acid and / or the nucleic acid chain to be amplified), this binding being essentially independent of potentially existing sequence differences in the polymorphic locus, wherein the polymerase is capable of extending a perfect-match complex formed thereby resulting in a first primer extension product.

The binding of such a primer essentially takes place in the sequence segment of the target nucleic acid, which is uniform for at least two allelic variants of these target nucleic acid chains. The primer binding preferably takes place in the sequence segment of the target nucleic acid, which is uniform for all allelic variants of this target nucleic acid.

The binding takes place to such an extent that the polymorphic locus of the target sequence lies in the 3 ^' direction from the first region of the first primer, so that in a primer extension reaction this polymorphic locus is copied by the polymerase. A resulting first primer extension product thus comprises a complementary sequence to the polymorphic locus. This sequence is in the 3 ^' direction from the first primer.

Such a primer thus comprises sequence segments which can preferably bind uniformly to all allelic variants of a target sequence in a uniform manner. For differentiation of allelic variants to take place, such a primer must be combined with at least one allele-specific controller oligonucleotide. The allele discrimination is thus effected by the action of the controller oligonucleotide. The positioning of the polymorphic locus in the 3 ^' direction from the primer causes its localization in the third region of the controller oligonucleotide. The second region of the first primer oligonucleotide

The second region of the first primer oligonucleotide is preferably a nucleic acid sequence comprising at least one polynucleotide tail which preferably remains uncopied during the synthesis reaction of the polymerase and which is capable of binding to the first region of the controller oligonucleotide. The segment of the second region, which predominantly undergoes this binding with the controller oligonucleotide, may be referred to as the polynucleotide tail.

Furthermore, the second region of the first primer oligonucleotide must not only specifically bind the controller oligonucleotide under reaction conditions, but also participate in the process of strand displacement by means of controller oligonucleotide. The structure of the second region must therefore be suitable for bringing about spatial proximity between the controller oligonucleotide and the corresponding duplex end (in particular, the 3 ^' end of the second primer extension product).

The design of the structure of the second region of the first primer oligonucleotide is shown in more detail in several embodiments. The arrangement of the oligonucleotide segments and the modifications used are taken into account, which lead to a stop in the polymerase-catalyzed synthesis.

The length of the second region is between 3 and 60, in particular between 5 and 40, in particular between 6 and 15 nucleotides or their equivalents.

The sequence of the second area may be chosen arbitrarily. Preferably, it is not complementary with the nucleic acid to be amplified and / or with the second primer oligonucleotide and / or with the first region of the first primer oligonucleotide. Furthermore, it preferably contains no self-complementary segments, such as hairpins or stemmloops.

The sequence of the second region is preferably matched to the sequence of the first region of the controller oligonucleotide, so that both sequences can bind under reaction conditions. In a preferred embodiment, this bond is reversible under reaction conditions: there is thus a balance between components bound together and unbound components.

The sequence of the second region of the first primer oligonucleotide is preferably chosen such that the number of complementary bases which can bind to the first region of the controller oligonucleotide is between 1 and 40, in particular between 3 and 20, in particular between 6 and 15 lies.

The function of the second area is, inter alia, the binding of the controller oligonucleotide. In certain embodiments, this binding is preferably specific such that a second region of a first primer oligonucleotide is a specific controller Can bind oligonucleotide. In another embodiment, a second region may bind more than one controller oligonucleotide under reaction conditions.

There is generally no need for a perfect match in sequence between the second region of the first primer oligonucleotide and the first region of the controller oligonucleotide. The degree of complementarity between the second region of the first primer oligonucleotide and the first region of the controller oligonucleotide may be between 20% and 100%, in particular between 50% and 100%, in particular between 80% and 100%. The respective complementary regions may be positioned immediately adjacent to each other or may comprise non-complementary sequence segments therebetween.

In certain embodiments, specific sequence segments are preferably used in the second region of the first primer. These sequence-specific and therefore characteristic sequence segments are preferably not complementary to the target nucleic acid chain and are adapted to the sequence segments of the first region of an allele-specific controller oligonucleotide so that predominantly specific complementary duplexes between the first region of the controller oligonucleotide and the second region of the first Primer oligonucleotide can be formed. Thus, for example, in the presence of multiple controller oligonucleotides (e.g., which are allele-specific), pair formation may be from a particular first primer and a particular controller oligonucleotide. The second region of the first primer oligonucleotide can thus be used for a characteristic coding, especially in multiplex analyzes.

By using predominantly sequence-specific sequence segments in the second primer region and a simultaneous use of correspondingly complementary sequence segments in the first region of the controller oligonucleotide, thus an improved assignment of potentially resulting primer extension products and characteristic controller oligonucleotides can take place.

The second region of the first primer oligonucleotide may, in certain embodiments, include at least one Tm modifying modification. By introducing such modifications, the stability of the binding between the second region of the first primer oligonucleotide and the first region of the controller oligonucleotide can be modified. For example, Tm enhancing modifications (nucleotide modifications or non-nucleotide modifications) may be used, such as LNA nucleotides, 2-amino adenosines, or MGB modifications. On the other hand, Tm-lowering modifications may also be used, such as inosine nucleotides. In the structure of the second region also linkers (eg C3, C6, HEG linkers) can be integrated. For strand displacement, the controller oligonucleotide must be placed in close proximity to the double-stranded end of the nucleic acid to be amplified. This double-stranded end consists of segments of the first primer region of the first primer extension product and a correspondingly complementary 3 ^' segment of the second primer extension product.

The polynucleotide tail predominantly complements the controller oligonucleotide under reaction conditions, thereby causing a transient approach of the second region of the controller oligonucleotide and the first region of an extended primer extension product such that a complementary bond between these elements is initiated as part of a strand displacement process can.

In certain embodiments, binding of the controller oligonucleotide to the polynucleotide tail of the first primer oligonucleotide immediately results in such contact. This means that the polynucleotide tail and the first primer region of the first primer oligonucleotide must be directly coupled to each other. Thanks to such an arrangement, after a binding of a controller oligonucleotide in its first region, contact between complementary bases of the second region of the controller oligonucleotide and corresponding bases of the first primer region can occur directly, so that strand displacement can be initiated.

In certain embodiments, structures of the second region of the first primer oligonucleotide are located between structures of the polynucleotide tail and the first primer region. After binding of a controller oligonucleotide to the polynucleotide tail, it is thus not positioned directly at the first primer region, but at a certain distance from it. The structures between the uncopiable polynucleotide tail and the copiable first primer region of the primer oligonucleotide can generate such a spacing. This distance has a value which is between 0.1 and 20 nm, in particular between 0.1 and 5 nm, in particular between 0.1 and 1 nm.

Such structures represent, for example, linkers (e.g., C3 or C6 or HEG linkers) or segments that are not complementary to the controller oligonucleotide (e.g., in the form of non-complementary, non-copyable nucleotide modifications). The length of these structures can generally be measured in chain atoms. This length is between 1 and 200 atoms, in particular between 1 and 50 chain atoms, in particular between 1 and 10 chain atoms.

In order for the polynucleotide tail to remain uncopable from the polymerase under amplification conditions, the second region of the first primer oligonucleotide generally comprises sequence arrangements that cause the polymerase to stop in the synthesis of the second primer extension product after the polymerase releases the polymerase first primer area has been successfully copied. These structures are intended to allow copying of the polynucleotide Prevent tail of the second area. The polynucleotide tail thus preferably remains uncoupled from the polymerase.

In certain embodiments, such structures are between the first primer region and the polynucleotide tail.

In certain embodiments, the sequence of the polynucleotide tail may include nucleotide modifications that result in the termination of the polymerase. Thus, a sequence segment of the second region of the first primer oligonucleotide may comprise both functions: it is both a polynucleotide tail and a polymerase-terminating sequence of nucleotide modifications.

Modifications in the second region of the first primer oligonucleotide which result in a synthetic stop and thus leave the polynucleotide tail uncopyable are summarized in this application by the term "first blocking moiety or first stop region".

In the following, further embodiments of structures are given, which can lead to a stop in the synthesis of the second strand.

Several building blocks in oligonucleotide synthesis are known which prevent the polymerase from reading the template and lead to the termination of the polymerase synthesis. For example, non-copyable nucleotide modifications or non-nucleotide modifications are known. There are also synthetic types / arrangements of nucleotide monomers within an oligonucleotide which result in the termination of the polymerase (eg, 5 ^'to 5 ^' or 3 ^'to 3 ^' ). Primer oligonucleotides with a non-copyable polynucleotide tail are also known in the art (eg Scorpion primer structures or primers for binding to the solid phase). Both primer variants describe primer oligonucleotide structures which are capable of initiating the synthesis of a strand so that a primer extension reaction can take place. The result is a first strand, which also integrates the primer structure with tail in the primer extension product. In the synthesis of a complementary strand to the first primer extension product, eg as part of a PCR reaction, the second strand is extended to the "blocking moiety / stop structure" of the primer structure. Both described primer structures are designed in such a way that the 5 ^' portion of the primer oligonucleotide remains single-stranded and is not copied by the polymerase.

In certain embodiments, the second region of the primer oligonucleotide comprises a polynucleotide tail that has a conventional 5 ^' to 3 ^' array in its entire length and includes non-copyable nucleotide modifications. Such non-copyable nucleotide modifications include, for example, 2 ^{'-0-alkyl-RNA} modifications, PNA, morpholino. These modifications may be distributed differently in the second primer region. The proportion of non-copyable nucleotide modifications may be between 20% and 100% in the polynucleotide tail, in particular more than 50% of the nucleotide building blocks. In particular, these nucleotide modifications are in the 3 ^' segment of the second region and thus adjacent to the first region of the first primer oligonucleotide.

In certain embodiments, the sequence of non-copyable nucleotide modifications is at least partially complementary to the sequence in the template strand such that primer binding to the template occurs involving at least a portion of these nucleotide modifications. In certain embodiments, the sequence of non-copyable nucleotide modifications is non-complementary to the sequence in the template strand.

The non-copyable nucleotide modifications are preferably covalently coupled to one another and thus represent a sequence segment in the second region. The length of this segment comprises between 1 and 40, in particular between 1 and 20 nucleotide modifications, in particular between 3 and 10 nucleotide modifications.

In certain embodiments, the second region of the first primer oligonucleotide comprises a polynucleotide tail that has a conventional arrangement of 5 -3 'in its entire length and includes non-copyable nucleotide modifications (eg, 2 ^{' to} 0 alkyl modifications). and at least one non-nucleotide linker (eg, C3, C6, HEG linker). A non-nucleotide linker has the function of covalently linking adjacent nucleotides or nucleotide modifications while at the same time site-specifically disrupting the synthesis function of the polymerase.

Such a non-nucleotide linker should not remove the structures of the polynucleotide tail and the first primer region too far apart. Rather, the polynucleotide tail should be in close proximity to the first primer region. A non-nucleotide linker is taken to mean modifications which are no longer than 200 chain atoms in length, in particular not more than 50 chain atoms, in particular not more than 10 chain atoms. The minimum length of such a linker can be one atom. An example of such non-nucleotide linkers are straight or branched alkyl linkers having an alkyl chain which includes at least one carbon atom, more preferably at least 2 to 30, especially 4 to 18. Such linkers are in oligonucleotide chemistry well known (eg, C3, C6, or C12 linker) and can be introduced during solid phase synthesis of oligonucleotides between the sequence of the polynucleotide tail and the sequence of the first region of the first primer oligonucleotide. Another example of such non-nucleotide linkers are linear or branched polyethylene glycol derivatives. A well-known example in oligonucleotide chemistry is hexaethylene glycol (HEG). Another example of such non-nucleotide linkers are abasic modifications (eg THF modification, as analog of d ribose). If one or more of such modifications are integrated into a second region, they can effectively interfere with a polymerase in its copying function during its synthesis of the second primer extension product such that segments located in the 3 'direction (Fig Modification remain uncopied. The number of such modifications in the second range can be between 1 and 100, in particular between 1 and 10, in particular between 1 and 3.

The position of such a non-nucleotide linker may be at the 3 ^' end of the second region, thus representing the transition from the first region to the second region of the primer oligonucleotide.

The location of the non-nucleotide linker in the middle segment of the second region may also be used. This divides a polynucleotide tail into at least two segments. In this embodiment, the 3 ^' segment of the polynucleotide tail includes at least one, in particular several, for example between 2 and 20, in particular between 2 and 10 non-copyable nucleotide modifications. These non-copyable nucleotide modifications are preferably at the junction between the first and second regions of the primer oligonucleotide.

In certain embodiments, the second region of the primer oligonucleotide comprises a polynucleotide tail having in its entire length an array of 5 ^'to 3 ^' - and at least one nucleotide monomer in a "reverse" array of 3 ^'to 5 ^'- including which is positioned at the transition between the first and the second region of the first primer oligonucleotide.

In certain embodiments, the second region of the primer oligonucleotide comprises a polynucleotide tail, such polynucleotide tail consisting entirely of nucleotides which are directly adjacent to the first region of the first primer oligonucleotide in reverse order such that the coupling of the first and second primer oligonucleotides of the second area through 5 ^' - 5 ^' position. An advantage of such an arrangement is that after copying the first region, the polymerase encounters a "reverse" arrangement of nucleotides, which typically results in termination of the synthesis at that site.

In a "reverse" array of nucleotides in the total length of the polynucleotide tail, preferably the 3 ^' terminal nucleotide of the polynucleotide tail is blocked at its 3 ^' OH end to prevent side reactions. Alternatively, a terminal nucleotide can be used which has no 3 ^' -OH group, for example a dideoxy nucleotide.

In such an embodiment, of course, the corresponding nucleotide arrangement is to be adapted in the controller oligonucleotide. In such a case, the first and the second portion of the controller oligonucleotide in 3 ^'to ^3' arrangement have to be linked. In certain embodiments, the second region of the primer oligonucleotide comprises a polynucleotide tail having a conventional 5 ^' to 3 ^' configuration in its entire length and including at least one nucleotide modification which is not a complementary nucleobase for the polymerase, when the synthesis is performed with all natural dNTP (dATP, dCTP, dGTP, dTTP or dUTP).

For example, iso-dG or iso-dC nucleotide modifications can be integrated as single, but in particular more (at least 2 to 20) nucleotide modifications in the second region of the first primer oligonucleotide. Other examples of nucleobase modifications are various modifications of the extended genetic alphabet. Such nucleotide modifications preferably do not support complementary base pairing with natural nucleotides, such that a polymerase (at least theoretically) does not contain a nucleotide from the series (dATP, dCTP, dGTP, dTTP or dUTP). However, in reality, rudimentary incorporation may occur, especially at higher concentrations of dNTP substrates and prolonged incubation times (e.g., 60 minutes or longer). Therefore, in particular, several such nucleotide modifications should be positioned at adjacent sites. The stop of polymerase synthesis is effected by the lack of suitable complementary substrates for these modifications. Oligonucleotides with iso-dC and iso-dG, respectively, can be synthesized by standard techniques and are available from several commercial suppliers (e.g., Trilink-Technologies, Eurogentec, Biomers GmbH). Optionally, the sequence of the first region of the controller oligonucleotide can also be adapted to the sequence of such a second primer region. In this case, complementary nucleobases of the extended genetic alphabet can be integrated into the first region of the controller oligonucleotide accordingly during the chemical synthesis. For example, iso-dG may be integrated in the second region of the first primer nucleotide, its complementary nucleotide (iso-dC-5-Me) may be placed at the appropriate location in the first region of the controller oligonucleotide.

In conclusion, the termination of the synthesis of the polymerase in the second region can be achieved in various ways. However, this blockade preferably takes place only when the polymerase has copied the first region of the first primer oligonucleotide. This ensures that a second primer extension product has an appropriate primer binding site in its 3 ^' segment. This primer binding site is exposed as part of the strand displacement and is thus available for a new binding of another first primer oligonucleotide.

In the synthesis of the complementary strand to the first primer extension product, the primer extension reaction remains in front of the polynucleotide tail. Because this polynucleotide tail remains single-stranded for interaction with the controller oligonucleotide and thus is available for binding, it supports the initiation of the strand displacement reaction by the controller oligonucleotide by using the oligonucleotide corresponding complementary segments of the controller oligonucleotide brings in the immediate vicinity of the appropriate duplex end. The distance between the complementary part of the controller oligonucleotide (second region) and the complementary part of the extended primer oligonucleotide (first region) is thereby reduced to a minimum. Such spatial proximity facilitates the initiation of strand displacement.

In the context of a schematic representation of a nucleic acid-mediated strand displacement reaction, a complementary sequence of controller oligonucleotide is now in the immediate vicinity of the appropriate duplex end. This leads to competition for binding to the first region of the first primer oligonucleotide between the strand of the controller oligonucleotide and the primer complementary template strand. By repetetive closure and formation of the base pairing between the primer region and the complementary segment of the controller oligonucleotide (second region of the controller nucleotide) or the complementary segment of the template strand, the initiation of the nucleic acid-mediated strand displacement process occurs.

Generally, the closer the corresponding complementary sequence portion of the controller oligonucleotide to the complementary segment of the primer region is, the higher the yield of initiation of strand displacement. By increasing this distance, however, the yield of the initiation of the strand displacement decreases.

In the context of the present invention, it is not absolutely necessary for the initiation of the strand displacement to work with maximum yield. Therefore, distances between the 5 ^' segment of the first primer region of the first primer oligonucleotide, which binds to a complementary strand of the template and forms a complementary duplex, and a correspondingly complementary sequence segment in the controller oligonucleotide when bound to the Polynucleotide tail of the second region of the first primer oligonucleotide in the following ranges: between 0.1 and 20 nm, in particular between 0.1 and 5 nm, in particular between 0.1 and 1 nm. In the preferred case, this distance is less than 1 nm. In other units, this distance corresponds to a distance of less than 200 atoms, in particular less than 50 atoms, in particular less than 10 atoms. In the preferred case, this distance is an atom. The distance information is for guidance only and illustrates that shorter distances between these structures are preferred. The measurement of this distance is in many cases only possible by analyzing the exact structures of oligonucleotides and measuring sequence distances or linker lengths.

The first primer may also include additional sequence segments that are not required for interaction with the controller oligonucleotide or template strand. Such sequence segments may, for example, bind further oligonucleotides which are used as detection probes or immobilization partners when bound to the solid phase. Primer function of the first primer oligonucleotide

The first primer oligonucleotide can be used in several partial steps. First and foremost, it performs a primer function in the amplification. The primer extension reaction is carried out using the second primer extension product as a template. In certain embodiments, the first primer oligonucleotide may use the starting nucleic acid chain as a template at the beginning of the amplification reaction. In certain embodiments, the first primer oligonucleotide may be used in the preparation / provision of a starting nucleic acid chain.

As part of the amplification, the first primer serves as the initiator of the synthesis of the first primer extension product using the second primer extension product as template. The 3 ^' segment of the first primer comprises a sequence which can bind predominantly complementary to the second primer extension product. Enzymatic extension of the first primer oligonucleotide using the second primer extension product as template results in the formation of the first primer extension product. Such a first primer extension product comprises the target sequence or its sequence parts. In the course of the synthesis of the second primer extension product, the sequence of the copiable portion of the first primer oligonucleotide is recognized as a template by the polymerase, whereby a corresponding complementary sequence is synthesized to result in a corresponding primer binding site for the first primer oligonucleotide. The synthesis of the first primer extension product occurs up to and including the 5 ^' segment of the second primer oligonucleotide. Immediately after the synthesis of the first primer extension product, this product is bound to the second primer extension product to form a double-stranded complex. The second primer extension product is sequence-specifically displaced from this complex by the controller oligonucleotide. The controller oligonucleotide binds to the first primer extension product. Again, after successful strand displacement by the controller oligonucleotide, the second primer extension product can itself serve as a template for the synthesis of the first primer extension product. The now vacated 3 ^' segment of the first primer extension product can bind another second primer oligonucleotide so that a new synthesis of the second primer extension product can be initiated.

Furthermore, the first primer oligonucleotide can serve as the initiator of the synthesis of the first primer extension product starting from the starting nucleic acid chain at the beginning of the amplification. In certain embodiments, the sequence of the first primer is completely complementary to the corresponding sequence segment of a starting nucleic acid chain. In certain embodiments, the sequence of the first primer oligonucleotide is only partially complementary to the corresponding sequence segment of a starting nucleic acid chain. However, this divergent complementarity is not intended to prevent the first primer oligonucleotide to start a predominantly sequence-specific primer extension reaction. The respective differences in the complementarity of the first primer oligonucleotide to the respective position in the starting nucleic acid chain are preferably in the 5 ^' segment of the first region of the first primer oligonucleotide, so that in the 3 ^' segment a predominantly complementary base pairing and an initiation of the Synthesis is possible. For the initiation of the synthesis, for example, especially the first 4-10 positions in the 3 ^' segment should be fully complementary to the template (starting nucleic acid chain). The remaining nucleotide positions may differ from a perfect complementarity. The extent of perfect complementarity in the remaining 5 ^' segment of the first region of the first primer oligonucleotide may thus range between 50% to 100%, in particular between 80% and 100%, of the base composition. Depending on the length of the first region of the first primer oligonucleotide, the sequence deviations comprise 1 to a maximum of 15 positions, in particular 1 to a maximum of 5 positions. The first primer oligonucleotide may thus initiate synthesis from a startup nucleic acid chain. In a subsequent synthesis of the second primer extension product, copyable sequence portions of the first primer oligonucleotide are copied from the polymerase such that, in subsequent synthesis cycles, a fully complementary primer binding site within the second primer extension product for binding of the first primer oligonucleotide is formed and available in subsequent synthesis cycles.

In certain embodiments, the first primer oligonucleotide may be used in the preparation of a starting nucleic acid chain. In this case, such a first primer oligonucleotide can bind to a nucleic acid (for example a single-stranded genomic DNA or RNA or its equivalents comprising a target sequence) predominantly / preferably sequence-specifically and initiate a template-dependent primer extension reaction in the presence of a polymerase. The binding position is chosen such that the primer extension product comprises a desired target sequence. The extension of the first primer oligonucleotide results in a nucleic acid strand which has a sequence complementary to the template. Such a strand can be detached from the template (eg by heat or alkali) and thus converted into a single-stranded form. Such a single-stranded nucleic acid chain can serve as a starting nucleic acid chain at the beginning of the amplification. Such a start nucleic acid chain comprises in its 5 ^' segment the sequence portions of the first primer oligonucleotide, furthermore it comprises a target sequence or its equivalents and a primer binding site for the second primer oligonucleotide. Further steps are explained in the section "Starting nucleic acid chain".

The synthesis of the first primer extension product is a primer extension reaction and forms a partial step in the amplification. The reaction conditions during this step are adjusted accordingly. The reaction temperature and the reaction time are chosen so that the reaction can take place successfully. The particular preferred temperature in this step depends on the polymerase used and the binding strength of the respective first primer oligonucleotide to its primer binding site and includes, for example, ranges from 15 ° C to 75 ° C, in particular from 20 to 65 ° C, in particular from 25 ° C to 65 ° C. The concentration of the first primer oligonucleotide comprises ranges from 0.01 pmol / l to 50 pmol / l, in particular from 0.1 pmol / l to 20 pmol / l, in particular from 0.1 pmol / l to 10 pmol / l.

In certain embodiments, all steps of the amplification proceed under stringent conditions that prevent or slow down the formation of nonspecific products / byproducts. Such conditions include, for example, higher temperatures, for example above 50 ° C.

If more than one specific nucleic acid chain has to be amplified in one batch, in certain embodiments, sequence-specific primer oligonucleotides are preferably used in each case for the amplification of corresponding respective target sequences.

Preferably, sequences of the first primer oligonucleotide, the second primer oligonucleotide, and the controller oligonucleotide are matched to one another such that side reactions, e.g. Primer-dimer formation, minimized. For this purpose, for example, the sequence of the first and second primer oligonucleotides are adapted to each other such that both primer oligonucleotides are incapable of undergoing an amplification reaction in the absence of an appropriate template and / or target sequence and / or starting sequence. Start or support nucleic acid chain. This can be achieved, for example, in that the second primer oligonucleotide does not comprise a primer binding site for the first primer oligonucleotide and the first primer oligonucleotide does not comprise a primer binding site for the second primer oligonucleotide. Furthermore, it should be avoided that the primer sequences comprise extended self-complementary structures (self-complement).

In certain embodiments, the synthesis of the first and second primer extension products proceeds at the same temperature. In certain embodiments, the synthesis of the first and second primer extension products proceeds at different temperatures. In certain embodiments, synthesis of the first primer extension product and strand displacement by the controller oligonucleotide proceeds at the same temperature. In certain embodiments, synthesis of the first primer extension product and strand displacement by the controller oligonucleotide proceeds at different temperatures.

Use of a first primer oligonucleotide in combination with a first competitor primer oligonucleotide: Preferred Embodiments of the First Competitor Primer Oligonucleotide (Primer-1)

A first competitor primer oligonucleotide competes with the first primer oligonucleotide for binding to a sequence segment of a nucleic acid sequence sequence segment comprising at least two variants of a target nucleic acid chain.

The first primer oligonucleotide binds to the desired or expected sequence variant and is preferably extended under stringent Reaktionsbedinungen by a polymerase. The first competitor oligonucleotide binds to the second potential or expected sequence variant and is preferably extended under stringent reaction conditions by a polymerase. There are thus two primer extension products: one of the first primer oligonucleotide, which is to be further amplified in the amplification and the other of the first competitor primer oligonucleotide, which is not to be propagated in an amplification.

By competition of two primers for a primer binding sequence in the target nucleic acid chain, the specificity of the analysis can be improved.

The two primers (the first primer and the first competitor primer) thus represent allele-specific primers with regard to potential or expected sequence variants. The essential difference is that the competitor primer is not able to involving a allele-specific controller oligonucleotide to initiate strand separation.

In certain embodiments, a first competitor primer oligonucleotide (competitor primer-1) comprises a nucleic acid chain which includes at least the following properties:

A first competitor primer region in the 3 ^' segment of the first competitor primer oligonucleotide capable of substantially sequence-specific binding to a strand of a nucleic acid chain to be amplified, and thus capable of competing with the first primer oligonucleotide for its primer binding site ,

A 3 ^' end of the competitor primer which, following binding to the primer binding site in the target sequence, can be sequence-specifically extended by the polymerase to form a competitor-primer extension product

A 3 ^' end of the competitor, which is prevented from "prolonging" by a "polymerase" from the "second blocking moiety" and / or from the "fourth blocking moiety" of the controller oligonucleotide when the first competitor primer oligonucleotide is attached to the oligonucleotide Controller oligonucleotide is bound complementarily

The total length of the first competitor primer oligonucleotide is between 10 and 80, in particular between 15 and 50, in particular between 20 and 30 nucleotides or their equivalents (eg nucleotide modifications). The length of the 3 ^' segment, which may undergo complementary binding to an expected sequence variant of a target sequence, comprises substantially the same regions as the first region of the first primer. This ensures that both primers can competitively bind to the target sequence and this binding occurs approximately in the same temperature range. The competitive binding and especially the competing primer extension using allele-specific sequence segments of the target nucleic acid usually leads to a further increase in specificity.

The structure of the first competitor primer oligonucleotide is adapted to undergo reversible binding to the controller oligonucleotide under selected reaction conditions. In certain embodiments, the first competitor primer comprises sequence segments which are said to be complementary to the first region of the controller oligonucleotide. Thus, this first competitor oligonucleotide can not occur as an initiator of strand displacement by a controller oligonucleotide.

In an advantageous embodiment of the invention, the first competitor primer oligonucleotide is a DNA oligonucleotide with a conventional 5 ^'to ^3' arrangement of nucleotides.

In certain embodiments, a competitor primer oligonucleotide includes additional sequences that do not bind to the controller oligonucleotide. These sequences can be used for other purposes, such as binding to the solid phase. These sequences are preferably located at the 5 ^' end of the 3 ^' segment.

The first primer region of the first competitor primer oligonucleotide

The sequence length is between about 15-30 nucleotides, in particular between 5 and 20 nucleotides, wherein the sequence is predominantly complementary to the 3 ^' segment of a strand of the amplification to be repressed allele variant of a target nucleic acid. The first primer region may include nucleotide monomers which do not or only insignificantly affect the function of the polymerase, for example:

In certain embodiments, an allele-specific first primer is used in combination with an allele-specific controller oligonucleotide and an allele-specific competitor primer oligonucleotide.

Preferred embodiments of the controller oligonucleotide

A controller oligonucleotide (Figures 2, 7-24, 29) comprises:

A first single-stranded region which can bind to the polynucleotide tail of the second region of the first primer oligonucleotide, A second single-stranded region which can bind to the first region of the first primer oligonucleotide essentially complementary,

A third single-stranded region which is substantially complementary to at least one segment of the extension product of the first primer extension product,

and the controller oligonucleotide does not serve as a template for primer extension of the first or second primer oligonucleotide.

In general, the sequence of the third region of the controller oligonucleotide is adapted to the sequence of the nucleic acid to be amplified, since this is a template for the order of the nucleotides in the extension product of a first primer. The sequence of the second region of the controller oligonucleotide is adapted to the sequence of the first primer region. The structure of the first region of the controller oligonucleotide is adapted to the sequence of the second region of the first primer oligonucleotide, especially the nature of the polynucleotide tail.

A controller oligonucleotide may also include other sequence segments that do not belong to the first, second or third region. For example, these sequences can be attached as flanking sequences at the 3 ^' and 5 ^' ends. Preferably, these sequence segments do not interfere with the function of the controller oligonucleotide.

The structure of the controller oligonucleotide preferably has the following properties:

The individual areas are covalently bonded to each other. The binding can be done for example via conventional 5 ^' -3 ^' bond. For example, a phospho-diester bond or a nuclease-resistant phospho-thioester bond can be used.

A controller oligonucleotide may bind by its first region to the polynucleotide tail of the first primer oligonucleotide, which binding is mediated primarily by hybridization of complementary bases. The length of this first region is 3 to 80 nucleotides, in particular 4 to 40 nucleotides, in particular 6 to 20 nucleotides. The degree of sequence match between the sequence of the first region of the controller oligonucleotide and the sequence of the second region of the first primer oligonucleotide may be between 20% and 100%, in particular between 50% and 100%, in particular between 80% and 100%. The binding of the first region of the controller oligonucleotide should preferably be made specifically to the second region of the first primer oligonucleotide under reaction conditions.

The sequence of the first region of the controller oligonucleotide is preferably chosen such that the number of complementary bases that can bind to the second region of the first primer oligonucleotide complementary between 1 and 40, in particular between 3 and 20, in particular between 6 and 15 lies. Since the controller oligonucleotide is not a template for the polymerase, it may include nucleotide modifications that do not support polymerase function, which may be both base modifications and / or sugar-phosphate backbone modifications. The controller oligonucleotide may include, for example, in its first region nucleotides and / or nucleotide modifications selected from the following list: DNA, RNA, LNA ("locked nucleic acids": analogs having 2 ^' -4 ^' bridge linkage in the sugar moiety). , UNA ( "unlocked Nucleic acids": no bond between 2 ^{^'-3'} -atoms of the sugar moiety), PNA ( "peptide nucleic acids" analogs), PTO (phosphorothioate), morpholino analogs, 2 ^{'-0-alkyl-RNA} modifications (such as 2 ^'-OMe, ^2' -0 propargyl, 2 ^'-0- (2-methoxyethyl), ^2' -0-propyl-amine), 2 - halogen-RNA, 2 ^'-amino-RNA, etc. These Nucleotides or nucleotide modifications are linked to one another, for example, by conventional 5 ^' -3 ^' or 5 ^' -2 ^' binding. For example, a phospho-diester bond or a nuclease-resistant phospho-thioester bond can be used.

The controller oligonucleotide may include nucleotides and / or nucleotide modifications in its first region, the nucleobases being selected from the following list: adenines and their analogs, guanines and its analogs, cytosines and its analogs, uracil and its analogs, thymines and its analogues, inosine or other universal bases (eg nitroindole), 2-amino-adenine and its analogues, iso-cytosines and its analogues, iso-guanines and its analogues.

The controller oligonucleotide may include in its first region non-nucleotide compounds selected from the following list: Intercalating substances which may affect the binding strength between the controller oligonucleotide and the first primer oligonucleotide, e.g. MGB, naphthalene etc. The same elements can also be used in the second region of the first primer.

The controller oligonucleotide may include in its first region non-nucleotide compounds, e.g. Linkers such as C3, C6, HEG linkers which link individual segments of the first region together.

The controller oligonucleotide may bind by means of its second region to the first primer region of the first primer oligonucleotide, the binding being mediated essentially by hybridization of complementary bases.

The length of the second region of the controller oligonucleotide is matched to the length of the first region of the first primer oligonucleotide and is preferably consistent therewith. It is between about 3-30 nucleotides, in particular between 5 and 20 nucleotides. The sequence of the second region of the controller oligonucleotide is preferably complementary to the first region of the first primer oligonucleotide. The degree of complementarity is between 80% and 100%, in particular between 95% and 100%, in particular at 100%. The second region of the controller oligonucleotide preferably includes nucleotide modifications which prevent the polymerase on the extension of the first primer oligonucleotide, but do not block the formation of complementary double strands, or not substantially prevent, for example, 2 ^{'-0-alkyl-RNA} analogues (eg, ^2' -0-Me, 2 ^'-0- ( 2-methoxyethyl), 2 ^'-0- propyl, ^2' -0-propargyl nucleotide modifications), LNA, PNA or morpholino nucleotide modifications. Single nucleotide monomers are preferably linked via 5 ^' -3 ^' bond, but an alternative 5 ^' -2 ^' bond between nucleotide monomers may also be used.

The sequence length and nature of the first and second regions of the controller oligonucleotide are preferably selected such that binding of these regions to the first primer oligonucleotide is reversible under reaction conditions, at least in one reaction step of the process. This means that the controller oligonucleotide and the first primer oligonucleotide can bind specifically to each other, but this bond should not lead to the formation of a permanently stable under reaction conditions complex of both elements.

Rather, an equilibrium between a bound complex form of controller oligonucleotide and the first primer oligonucleotide and a free form of individual components under reaction conditions should be sought or made possible at least in one reaction step. This ensures that at least a portion of the first primer oligonucleotides can be in free form under reaction conditions and can interact with the template to initiate a primer extension reaction. On the other hand, it will be ensured that corresponding sequence regions of the controller oligonucleotide are available for binding with an extended primer oligonucleotide.

By choosing the temperature during the reaction, the proportion of free, single-stranded and thus reactive components can be influenced: by lowering the temperature, first primer oligonucleotides bind to the controller oligonucleotides, so that both participants bind a complementary double-stranded complex. Thus, the concentration of single-stranded forms of individual components can be lowered. An increase in temperature can lead to the dissociation of both components into single-stranded form. In the region of the melting temperature of the complex (controller oligonucleotide / first primer oligonucleotide) are about 50% of the components in single-stranded form and about 50% as a double-stranded complex. By using appropriate temperatures, the concentration of single-stranded forms in the reaction mixture can thus be influenced.

In embodiments of the amplification process comprising a temperature change between individual reaction steps, desired reaction conditions can be brought about during corresponding reaction steps. For example, by using temperature ranges approximately at the level of the melting temperature of complexes of controller oligonucleotide / first primer oligonucleotide portions of each free forms of individual components can be influenced. The temperature used increases destabilizing complexes comprising controller oligonucleotide / first primer oligonucleotide such that, during this reaction step, individual complex components become, at least temporarily, single-stranded, thereby being able to interact with other reactants. For example, a first sequence region of the controller oligonucleotide may be released from the double-stranded complex with a non-extended first primer, and thus may interact with the second sequence region of an extended first primer oligonucleotide, thereby initiating strand displacement. On the other hand, release of a first, non-extended primer oligonucleotide from a complex comprising controller oligonucleotide / first primer oligonucleotide results in the first primer region becoming single-stranded and thus able to interact with the template such that primer extension by a polymerase can be initiated.

The temperature used does not have to correspond exactly to the melting temperature of the complex of controller oligonucleotide / first primer oligonucleotide. It is sufficient if the temperature in a reaction step is approximately in the range of the melting temperature. For example, the temperature in one of the reaction steps comprises ranges of Tm +/- 10 ° C, in particular Tm +/- 5 ° C, in particular Tm +/- 3 ° C of the complex of controller oligonucleotide / first primer oligonucleotide.

Such a temperature can be set, for example, in the context of the reaction step, which comprises a sequence-specific strand displacement by the controller oligonucleotide.

In embodiments of the amplification process which do not involve temperature cycling between individual reaction steps and the amplification proceeds under isothermal conditions, reaction conditions are maintained over the entire duration of the amplification reaction in which there is equilibrium between a complex oligonucleotide-controller design and the first primer Oligonucleotide and a free form of individual components is possible.

The ratio between a complex form of controller oligonucleotide and the first primer oligonucleotide and free forms of individual components can be influenced both by reaction conditions (eg temperature and Mg ²⁺ concentration) and by structures and concentrations of individual components.

The sequence length and nature of the first and second regions of the controller oligonucleotide are, in certain embodiments, chosen such that under given reaction conditions (eg, in the strand displacement displacement step by the controller oligonucleotide) the ratio between a proportion of free controller oligonucleotide and a portion of a controller oligonucleotide complexed with a first primer oligonucleotide comprises the following ranges: from 1: 100 to 100: 1, more preferably from 1:30 to 30: 1, more preferably from 1:10 to 10: 1. The ratio between a proportion of a free first primer oligonucleotide and a proportion of a first primer oligonucleotide complexed with a controller oligonucleotide comprises ranges of from 1: 100 to 100: 1, more preferably from 1:30 to 30: 1, more preferably from 1:10 to 10: 1.

In certain embodiments, the concentration of the first primer oligonucleotide is higher than the concentration of the controller oligonucleotide. This results in an excess of the first primer in the reaction and the controller oligonucleotide must be released for its effect of binding with the first primer by choosing the appropriate reaction temperature. In general, this is done by raising the temperature to sufficient levels of free forms of the controller oligonucleotide.

In certain embodiments, the concentration of the first primer oligonucleotide is lower than the concentration of the controller oligonucleotide. As a result, there is an excess of the controller oligonucleotide and the first primer oligonucleotide must be released for its effect of binding to the controller oligonucleotide by choosing the appropriate reaction temperature. In general, this is done by raising the temperature to sufficient levels of free forms of the first primer oligonucleotide.

In isothermal conditions, there is an equilibrium: certain portions of the first primer oligonucleotide and controller oligonucleotide are bound together, while others are present as a single-stranded form in the reaction.

The controller oligonucleotide may bind by means of its third region to at least one segment of the specifically synthesized extension product of the first primer oligonucleotide. Binding is preferably by hybridization of complementary bases between the controller oligonucleotide and the extension product synthesized by the polymerase.

In order to support the strand displacement reaction, the sequence of the third region should preferably have a high complementarity to the extension product. In certain embodiments, the sequence of the third region is 100% complementary to the extension product.

The binding of the third region is preferably carried out on the segment of the extension product, which connects directly to the first region of the first primer oligonucleotide. Thus, the segment of the extension product is preferably in the 5 ^' segment of the entire extension product of the first primer oligonucleotide.

The binding of the third region of the controller oligonucleotide preferably does not occur over the entire length of the extension product of the first primer oligonucleotide. Preferably, a segment remains unbound at the 3 ^' end of the extension product. This 3 ^' -terminal segment is necessary for the binding of the second primer oligonucleotide. The length of the third region is adapted accordingly so that the third region binds to the 5 ^' -terminal segment of the extension product on the one hand, while on the other hand does not bind the 3 ^' -step segment of the extension product.

The total length of the third region of the controller oligonucleotide is from 2 to 100, in particular from 6 to 60, in particular from 10 to 40 nucleotides or their equivalents. The controller oligonucleotide may enter into a complementary bond with the segment of the extension product over that length, thereby displacing this 5 ^' segment of the extension product from binding with its complementary template strand.

The length of the 3 ^' -terminal segment of the extension product which is not bound by the controller oligonucleotide comprises, for example, ranges between 5 and 200, in particular between 5 and 100, in particular between 5 and 60 nucleotides, in particular between 10 and 40, in particular between 15 and 30 nucleotides.

This 3 ^' segment of the extension product is not displaced from the controller oligonucleotide from binding with the template strand. Even with a fully bound third region of the controller oligonucleotide to its complementary segment of the extension product, the first primer extension product may remain bound to the template strand via its 3 ^' -terminal segment. The bond strength of this complex is preferably chosen so that it can dissociate spontaneously under reaction conditions (step e), for example. This may be recordable, be achieved by that the melting temperature of the complex is from the 3 ^'-ständigen segment of the extension product of the first primer oligonucleotide and its template strand approximately in the range of the reaction temperature or below the reaction temperature at a corresponding reaction step (reaction step e). With little stability of this complex in the 3 ^' segment of the extension product, complete binding of the third region of the controller oligonucleotide to the 5 ^' segment of the extension product results in rapid dissociation of the first primer extension product from its template strand.

The controller oligonucleotide as a whole has a suitable structure to perform its function: under appropriate reaction conditions, it is capable of sequence-specific displacement of the extended first primer oligonucleotide from binding with the template strand, thereby converting the template strand into single-stranded form, and thus for further binding with a novel first primer oligonucleotide and its target sequence-specific extension by the polymerase.

To fulfill the function of strand displacement, regions one, two and three of the controller oligonucleotide should be predominantly in single-stranded form under reaction conditions. Therefore, double-stranded self-complementary structures (eg hairpins) should be included in these As far as possible, they can be avoided since they can reduce the functionality of the controller oligonucleotide.

The controller oligonucleotide should not appear as a template in the method of the invention, therefore the first primer oligonucleotide, when attached to the controller oligonucleotide under reaction conditions, should not be extended by the polymerase.

This is preferably achieved by using nucleotide modifications which prevent the polymerase from copying the strand. Preferably, the 3 ^' end of the first primer oligonucleotide does not remain elongated when the first primer oligonucleotide binds to the controller oligonucleotide under reaction conditions.

The degree of blockage / inhibition / slowing / aggravation of the reaction may be between complete expression of this property (e.g., 100% blockage under given reaction conditions) and a partial expression of this property (e.g., 30-90% blockade under given reaction conditions). Preference is given to nucleotide modifications which are individually or in series coupled to one another (eg as a sequence fragment consisting of modified nucleotides) to more than 70%, in particular more than 90%, in particular more than 95%, and in particular 100% elongation prevent a first primer.

The nucleotide modifications may include base modifications and / or sugar-phosphate-residue modifications. The sugar-phosphate modifications are preferred because any complementary sequence of a controller oligonucleotide can be assembled by combining with conventional nucleobases. The nucleotides with modifications in the sugar-phosphate residue, which can lead to hindrance or blockage of the synthesis of the polymerase include, for example: 2 ^'-0-alkyl modifications (eg, ^2' -0-methyl, 2 ^'-0- (2-methoxyethyl), 2 ^'-0-propyl, ^2' -0-propargyl nucleotide modifications), 2 ^{^'-amino-2'} -Deoxy- nucleotide modifications, 2 ^{^{'amino-alkyl-2'}} -Deoxy- Nucleotide modifications, PNA, morpholino modifications, etc.

The blockade can be accomplished by either a single nucleotide modification or only by coupling multiple nucleotide modifications in series (e.g., as a sequence fragment consisting of modified nucleotides). For example, at least 2, in particular at least 5, in particular at least 10, of such nucleotide modifications can be coupled side by side in the controller oligonucleotide.

A controller oligonucleotide may comprise a uniform type of nucleotide modifications or may comprise at least two different types of nucleotide modification.

The location of such nucleotide modifications in the controller oligonucleotide is preferably intended to prevent the polymerase from extending the 3 ^' end of a first primer oligonucleotide bound to the controller oligonucleotide. In certain embodiments, such nucleotide modifications are located in the second region of the controller oligonucleotide. In certain embodiments, such nucleotide modifications are located in the third region of the controller oligonucleotide. In certain embodiments, such nucleotide modifications are located in the second and third regions of the controller oligonucleotide.

For example, the second region of the controller oligonucleotide consists of at least 20% of its positions from such nucleotide modifications, in particular at least 50%.

For example, the third region of the controller oligonucleotide consists of at least 20% of its positions from such nucleotide modifications, in particular at least 50%, in particular at least 90%. In certain embodiments, the entire third region comprises nucleotide modifications that prevent a polymerase from extending a primer bound to such a region using the controller oligonucleotide as a template. In certain embodiments, the entire third and second regions include such nucleotide modifications. In certain embodiments, the entire first, second, and third regions include such nucleotide modifications. Thus, the controller oligonucleotide may consist entirely of such nucleotide modifications. Such modified controller oligonucleotides can be used, for example, in multiplex analyzes in which further primers are used. This is to prevent inadvertent primer extension reactions on one or more controller oligonucleotides.

The sequence of nucleobases from these nucleotide modifications is adapted to the requirements of the sequence in each area.

For example, the remaining portion may be natural nucleotides, or nucleotide modifications that do not or only marginally inhibit polymerase function, eg, DNA nucleotides, PTO nucleotides, LNA nucleotides, RNA nucleotides. In this case, further modifications, for example base modifications such as 2-amino-adenosine, 2-aminopurines, 5-methyl-cytosines, inosines, 5-nitroindoles, 7-deaza-adenosine, 7-deaza-guanosine, 5-propyl-cytosine, 5 Propyl uridine or non-nucleotide modifications such as dyes, or MGB modifications, etc. can be used, for example, to match binding strengths of individual regions of the controller oligonucleotides. The individual nucleotide monomers can be coupled to each other via conventional 5 ^' -3 ^' bond or else via 5 ^' -2 ^' bond.

A segment of the controller oligonucleotide having nucleotide modifications that prevent extension of the 3 ^' end of a first primer oligonucleotide bound to the controller oligonucleotide by the polymerase is termed a "second blocking moiety". The length of this segment may include from 1 to 50 nuclide modifications, especially between 4 and 30. For example, this segment may be located in the controller oligonucleotide such that the 3 ^' end of the bound first primer Oligonucleotide lies in this segment. Thus, this segment can span regions two and three. By using further primers (eg, competitor primers) which may also bind complementarily to the controller oligonucleotide, additional blocking moieties may be introduced, for example, a fourth blocking moiety which may be at the same position in the controller oligonucleotide as the second blocking unit or a deviating position. For example, the fourth blocking unit may lie in the 5 ^' direction from the second blocking unit. The primer blockade by such a fourth blocking moiety follows the same principle as that of the second blocking moiety: a primer which is capable of complementarily binding to the controller oligonucleotide is not extended by polymerase. Thus, the controller oligonucleotide is prevented from serving as a template for other primers, eg a competitor primer.

A segment of the controller oligonucleotide with nucleotide modifications which prevent the extension of the 3 ^' end of a further primer oligonucleotide bound to the controller oligonucleotide (eg a competitor primer oligonucleotide) by the polymerase is termed a "fourth blocking" Unit ". The composition of such a "fourth blocking unit" can be carried out analogously to the "second blocking unit".

In certain embodiments, preferably no linker structures or spacer structures, such as C3, C6, HEG linkers, are used to prevent the 3 ^' end extension of a first primer oligonucleotide bound to the controller oligonucleotide.

The controller oligonucleotide may comprise, in addition to regions one, two and three, further sequence segments which, for example, flank the abovementioned regions in the 5 ^' segment or 3 ^' segment of the controller oligonucleotide. Such sequence elements may be used, for example, for other functions, such as interaction with probes, binding to a solid phase, etc. Such regions preferably do not interfere with the function of regions one to three. The length of these flanking sequences may be, for example, between 1 to 50 nucleotides. Furthermore, a controller oligonucleotide may comprise at least one element for immobilization on a solid phase, eg a biotin residue. Furthermore, a controller oligonucleotide may include at least one element for detection, eg, a fluorescent dye.

In the presence of a controller oligonucleotide, newly synthesized sequences are checked for sequence content through interaction with the controller oligonucleotide.

• If the sequence oligonucleotide is correctly matched to the sequence oligonucleotide, strand displacement occurs, with the template strands being replaced by newly synthesized strands. Here, primer binding sites are converted to the single-stranded state and are available for a new interaction with the primers and thus for further synthesis. Thus, the system is off put both primer extension products in an active state. The controller oligonucleotide thus has an activating effect on the system.

• If there is no match with given sequence contents of the controller oligonucleotide, the strand displacement of the template strands is influenced by newly synthesized strands. The strand displacement and / or separation is either slowed down quantitatively or completely eliminated. It is thus not at all or less often the transfer of primer binding sites in the single-stranded state. Thus, there are no or fewer primer binding sites available for a new interaction with primers. Thus, the system of both primer extension products is rarely put into an active state or an active state is not reached.

The efficiency of the double-stranded opening of the newly synthesized primer extension products after each individual synthesis step affects the potentially achievable yields in subsequent cycles: the fewer free / single-stranded primer binding sites of a nucleic acid chain to be amplified at the beginning of a synthesis step The lower the number of newly synthesized strands of the nucleic acid chain to be amplified in this step. In other words, the yield of a synthesis cycle is proportional to the amount of primer binding sites available for interaction with corresponding complementary primers. Overall, this can be realized a control circuit.

This control circuit corresponds to a real-time / on-line control of synthesized fragments: the sequence control takes place in the reaction mixture while the amplification takes place. This sequence control follows a predetermined pattern and the oligonucleotide system (by strand-opening action of controller oligonucleotide) can decide between "correct" and "non-correct" states without external interference. In the correct state, the synthesis of sequences is continued; in the incorrect state, the synthesis is either slowed down or completely prevented. The resulting differences in the yields of "correct" and "incorrect" sequences after each step affect the entire amplification comprising a variety of such steps.

In exponential amplification, this dependency is exponential, so even slight differences in efficiency in a single synthesis cycle due to sequence differences may signify a significant time delay in total amplification, or cause complete absence of detectable amplification in a given time frame.

This effect of real-time control of the newly synthesized nucleic acid chains is associated with the use of the controller oligonucleotide. Sequence variant-specific controller oligonucleotides:

A target sequence specific controller oligonucleotide is preferably constructed in such a way that it is able to participate in the amplification of at least one predefined sequence variant of a target sequence.

In a preferred form, an amplification system comprising at least one controller oligonucleotide is designed such that the expected position of an allelic variant of a target sequence corresponds to a corresponding segment or a corresponding position in the controller oligonucleotide.

An allele-specific controller oligonucleotide is preferably constructed such that it is capable of preferentially effecting the amplification of a sequence variant of a target sequence (eg, allele 1), wherein in another sequence variant of the same target sequence (eg, allele 2 ) the amplification does not proceed at all or only with reduced efficiency or does not take place in the given time, or results in a yield of amplification products which is insufficient for a detection.

An allele-specific controller oligonucleotide is thus not only target-specific, but also allele-specific. Such a controller oligonucleotide thus comprises target sequence-specific sequence segments as well as allele-specific sequence segments. Depending on the complexity of a polymorphic locus of a target sequence, it is thus possible to construct a plurality of controller oligonucleotides specific for the particular allelic variant of a target sequence.

The length of a sequence segment of a controller oligonucleotide which is completely complementary to the polymorphic locus of a starting nucleic acid chain can comprise regions of one nucleotide of up to 100 nucleotides, in particular of one nucleotide of up to 50 nucleotides, in particular of one nucleotide of up to 20 nucleotides. The length of at least one sequence segment of a controller oligonucleotide which is complementary to uniform sequence segments of a target sequence (first and second unit sequence segment of a starting nucleic acid) may comprise the following ranges: from 4 to 100 nucleotides, in particular from 6 to 100 nucleotides, in particular from 8 to 50 nucleotides. In certain embodiments, a sequence segment of a controller oligonucleotide that is complementary to at least one variant of a polymorphic locus of a target sequence is located in the third region of the controller oligonucleotide.

In certain embodiments, a sequence segment of a controller oligonucleotide that is complementary to at least one variant of a polymorphic locus of a target sequence is partially and / or completely located in the second and third regions of the controller oligonucleotide.

The position of allele-specific sequence segments of a controller oligonucleotide can thus be divided into three groups. The first group comprises allele-specific sequence segments which are detected in both the first primer oligonucleotide and the controller oligonucleotide. This position thus at least partially encompasses the second region of the controller oligonucleotide and the first region of the first primer oligonucleotide.

The second group comprises allele-specific corresponding sequence segments which are only covered by the controller oligonucleotide, both primers (the first primer and the second primer) are only target sequence specific but not allele specific. The position thus comprises, at least in part, the third region of the controller oligonucleotide which is intended to bind complementarily to the 5 ^' segment of the portion of the first primer extension product synthesized by the polymerase.

The third group comprises allele-specific sequence segments which are detected in both the second primer oligonucleotide and the controller oligonucleotide. This position thus at least partially encompasses the third region of the controller oligonucleotide predominantly in the 5 ^' segment of the controller oligonucleotide.

Discrimination between allelic variants of a target sequence encompasses different mechanisms in these groups, which, for example, must be taken into account when choosing reaction conditions.

For the first and third groups, primers play an essential role in discrimination. The complementary primer binding to a corresponding primer binding site of an allelic variant of the target sequence and initiation of a synthesis of a primer extension product by the polymerase determine the extent of the different amplifications. The controller oligonucleotide interacts only with the first primer (first group) and with the complementary sequence segment to the 3 ^' segment of the second primer (third group). The successful strand displacement by the controller oligonucleotide thus depends primarily on the corresponding complementary design of these moieties of primers and the controller oligonucleotide. The synthesized segment content of the respective primer Extension product which lies between both primers represents a uniform sequence composition for an allelic variant of a common target sequence. For this reason, it is advantageous to carry out the amplification under stringent hybridization conditions which promote allele-specific initiation of a synthesis. Use of another allele-specific competitor primer can further enhance specific initiation of the synthesis.

In the second group, the initiation of primer extension product synthesis plays a secondary role, as the primers used bind to primer binding sites that are a consistent composition for all potential allelic variants of a target sequence. The discrimination takes place only with the participation of the controller oligonucleotide, which participates by sequence-specific or predominantly specific strand displacement in the separation of the first and the second primer extension product.

In certain embodiments, a fully complementary sequence of the third region of the controller oligonucleotide is preferably used which can form a perfect match with at least one allelic variant of the target sequence. The amplification of different allelic variants thus requires in this embodiment a combination of one allele-specific controller oligonucleotide.

As a rule, a deviation from fully-complementary sequence compositions leads to deviating amplification efficiencies. At the corresponding sequence segments of a controller oligonucleotide, there is competition for binding to the first primer extension product (consisting predominantly of DNA) with the second primer extension product (also comprising DNA). Allele-specific sequence design of this sequence segment of the controller oligonucleotide corresponding to an allelic variant allows a perfect match / perfect binding to the first primer extension product for both competing strands. Thus, a controller oligonucleotide is capable of successfully displacing the second primer extension product from its binding with the first primer extension product with its corresponding sequence segment. The separation of both primer extension products allows for exponential amplification.

In the case of a deviation in the composition of the corresponding segment of the controller oligonucleotide (eg when bound to a non-complementary allelic variant of a primer extension product), the situation generally changes. The interaction between perfect-match of the second primer extension product (consisting of DNA) and the first primer extension product (consisting of DNA) can be overcome only poorly or not even by a mismatch comprehensive segment of a controller oligonucleotide. By preferenced binding of a perfect-match double strand between both primer extension products, there is thus no sufficient strand separation with the assistance of a mismatch controller oligonucleotide, which as a rule leads to an insufficient or a slowed-down amplification. In a preferred embodiment, the sequence segment corresponding to an allelic variant lies in the third region of the controller oligonucleotide, which comprises predominantly or exclusively DNA monomers.

In certain embodiments, the sequence segment corresponding to an allelic variant lies in the third region of the controller oligonucleotide, which comprises both DNA and DNA modifications.

In certain embodiments, the sequence segment corresponding to an allelic variant lies in the third region of the controller oligonucleotide, which comprises predominantly or exclusively DNA modifications. For example, in localization of a korresspondierenden an allelic variant sequence segment within a second blocking unit, which comprises a plurality of 2 ^{'-0-alkyl-modification} of nucleotides, such modifications can have an effect on binding of the controller oligonucleotide to allele-specific variates of primer - exercise extension products.

In a preferred embodiment, the segment of a controller oligonucleotide that corresponds to an allele variant lies in the third region of the controller oligonucleotide, wherein this segment of the strand of the controller oligonucleotide is predominantly composed of DNA nucleotides. Preferably, this segment lies in the 5 ^' direction of the second blocking unit. The length of this segment corresponding to the polymorphic locus comprises in particular 1 to 20 nucleotides. The composition of the nucleotides in this fully complementary corresponding segment of the controller oligonucleotide comprises at least 70% of DNA nucleotides, in particular 80%, in particular more than 95% of DNA nucleotides.

Preferably, in an allelic variant which comprises only one nucleobase (eg SNP or a point mutation), the corresponding position in the central region of the controller oligonucleotide strand which on both sides to this corresponding position of DNA complementary to the target sequence Surrounded by the strand of the controller oligonucleotide at least 4 DNA monomers, in particular at least 6 DNA nucleotides, in particular at least 10 DNA nucleotides in both directions of the expected SNP or point mutation. Such arrangements of DNA monomers around an expected SNP site or point mutation or single nucleotide allelic variant makes it possible to maintain a single-stranded conformation which is characteristic for the B-shape (so-called single strand persistence length). Thus, strand displacement occurs through the controller oligonucleotide using a corresponding segment comprising DNA monomers.

In certain embodiments, a controller oligonucleotide is used which can form a complementary bond with the first primer extension product with its 5 ^' end. In allelic variants which comprise only one nucleobase, eg SNP or Point mutations, the corresponding sequence segment is preferably arranged at a distance from the 5 ^' end of the controller oligonucleotide, which comprises lengths of 10 to 60 nucleotides, in particular 20 to 50 nucleotides, in particular 30 to 40 nucleotides.

However, the use of DNA nucleotides as monomers of controller oligonucleotides must not result in the controller oligonucleotide being used as a template for primer extension using one of the primers employed by a polymerase used.

Use of DNA nucleotides (for example A, C, T or G) within the segment corresponding to an allelic variant in the controller oligonucleotide strand brings thereby some advantages, so that the discrimination behavior of an amplification system is easier to estimate.

For example, the behavior of perfectly match variants of a controller oligonucleotide to specific allele variants in point mutations can be more easily estimated. The discrimination between allelic variants follows the rules of Watson-Crick base pairing: Controller oligonucleotides, which can form complementary base pairs (A: T, G: C) with the first primer extension products, generally lead to amplification reactions in good Exploit.

However, potential mismatches between an allele-specific controller oligonucleotide and a first primer extension product (e.g., A: C or G: G) result in insufficient or delayed amplification. In the presence of allelic variants, which may account for more than one nucleotide difference from the controller oligonucleotide in a potential first primer extension product (e.g., short InDels), sufficient amplification is typically not achieved.

The effect of a mismatch on amplification can be estimated by determining stabilities of potential duplexes comprising an allele-specific controller oligonucleotide having a defined sequence and a potential primer extension product or its moieties, eg, only the synthesized moiety of a primer extension product. The duplexes are formed in the absence of second primer extension products. Upon hybridization of an allele-specific controller oligonucleotide to a potential perfect-match primer extension product, the binding of such duplexes is more stable than the binding of duplexes comprising at least one mismatch position. This stability can be detected by melting temperature measurement. Differences between amplification reactions of allelic variants are generally greater the greater the difference in stability between a perfect-match duplex and a mismatch duplex comprising an allele-specific controller oligonucleotide and a potential first primer extension product. Such differences between reactions, for example, by those for a reaction required time to reach a certain amount of products. Such differences in the time between amplification reactions of perfect-match and mismatch allele variants can also be seen as a capacity for discrimination: the greater the time difference, the higher the discrimination between each allele variants.

Due to the use of modifications in the controller oligonucleotide, eg in the region of the second blocking unit for preventing the extension of the first primer or a competitor primer, a different discrimination or even tolerance to certain mismatches can take place. In this case, for example, 2 ^'-0-alkyl modifications may be employed within the second blocking unit. Such nucleotide modifications can alter the conformation of a duplex (from B-form of a DNA: DNA duplex to A-like form of a DNA: RNA or DNA: mod. DNA duplex). In this case, especially in the base pairing between G: C and G: U or G: T, a change in the discrimination can take place.

For example, the use of modifications in the controller oligonucleotide leads to a change in the discrimination behavior of individual base pairs. A similar behavior is known from the research of RNA: the behavior of the G: U changes depending on the strand-form: in the case of RNA, a G: U base pair usually forms a sufficiently stable base pairing, in the case of DNA a G: U Mismatch usually leads to a weakening of the binding of both strands.

For example, in this application, 2 ^' alkyl nucleotide-comprising modifications are used in the controller oligonucleotide (eg, within the second blocking moiety). Here, a 2 ^'-0-Me Cytosine (C ^*) or ^2' -0-Me Adenosine (A ^*) is used. Such modified nucleotides allow good discrimination between individual sequence variants (where perfectly match binding comprises C ^* : dG and A ^* : U or A ^* : T and mismatch includes, for example, C ^* : dA or A ^* : dC).

However, the use of leads 2 ^'-0-Me-G (G ^*) or ^2' -0-Me-U (U ^*) to different results. For example, amplification using controller oligonucleotide with a G ^* at the corresponding site in the strand results in the simultaneous amplification of allelic variants with dC and dU at corresponding sites in the first primer extension product.

Thus, not only an allele-discriminating, but also an allele-tolerant function of a controller oligonucleotide can be represented.

When using nucleotide modifications that allow inadequate discrimination of allelic variants, multiple allelic variants can thus be amplified simultaneously. In addition to a 2 ^'-0-Me guanosine or ^2' -0-Me Uridine also universal bases such as inosine, or 5-nitro-indole monomers to be candidates for the tolerance allele composition belong. Such modifications of a controller oligonucleotide strand can be arranged at expected corresponding positions to particular allelic variants. Thus, this lack of discrimination in some modifications can be considered as follows:

In certain embodiments, the variant is an allelic sequence corresponding segment in the third area of the controller oligonucleotide which ^'comprises predominantly or exclusively 2 -0-alkyl modifications.

In certain embodiments, the segment of a controller oligonucleotide corresponding to an allelic variant lies in the third region of the controller oligonucleotide, this segment of the strand of the controller oligonucleotide being composed predominantly of 2 ^'to 0 alkyl modifications. Preferably, this segment is within the second blocking unit or in the 5 ^' direction of the second blocking unit. The length of this segment corresponding to the polymorphic locus comprises in particular 1 to 20 nucleotides. The composition of the nucleotides in this fully complementary corresponding segment of the controller oligonucleotide comprises at least 50% while 2 ^'-0-alkyl modifications, more preferably 80%, in particular more than 95% ^2' -0-alkyl modifications.

In particular, even in an allelic variant which comprises only one nucleobase (for example SNP or a point mutation), the corresponding position is in the middle region of the controller oligonucleotide strand. This controller oligonucleotide strand is ^'surrounded -0-alkyl modifications, the strand of the controller oligonucleotide at least four ^2' on both sides to this position corresponding of complementary to the target sequence 2 -0-alkyl modifications, in particular at least six 2 ^' -O-Alkyl modifications, in particular at least 10 2 ^' -O-alkyl modifications in both directions of the expected SNP or point mutation comprises such an arrangement of DNA monomers to an expected SNP site or point Mutation or single nucleotide allele variant allows the maintenance of a single-stranded conformation, which can be referred to as A-like form. Thus, strand displacement occurs through the controller oligonucleotide using a corresponding segment comprising nucleotides with 2 ^'to O alkyl modifications.

In certain embodiments, a controller oligonucleotide is used which can form a complementary bond with the first primer extension product with its 5 ^' end. In allelic variants which comprise only one nucleobase, eg SNP or point mutations, the corresponding sequence segment is preferably arranged at a distance from the 5 ^' end of the controller oligonucleotide, which lengths of 10 to 60 nucleotides, in particular 20 to 50 nucleotides, in particular 30 to 40 nucleotides.

Upon localization of a sequence segment expected within an allelic variant within such a segment comprising several 2 ^'to 0-alkyl modifications, a possibly different base pairing is taken into account (relates, in particular, to alternative base pairing between DNA structures (B). Like structure) and A-like structures of RNA (or 20me variants). In one embodiment, the following rule can be used:

Controller oligonucleotides comprising 2 ^'-0-alkyl modifications of cytosine can form a sufficient base pairing with dG-nucleotide at corresponding locations in the first primer extension product and thus support the amplification of such allelic variants generally.

Controller oligonucleotides comprising 2 ^'-0-alkyl modifications of adenosine able to form a sufficient base pairing with dT or dU nucleotide at corresponding locations in the first primer extension product and thus support the amplification of such allelic variants generally.

Controller oligonucleotides comprising 2 ^'-0-alkyl modifications of guanosine can form a sufficient base pairing with dC and dU nucleotide at corresponding locations in the first primer extension product and thus support the amplification of both allelic variants generally.

Controller oligonucleotides comprising 2 ^'-0-alkyl modifications of uridine can form a sufficient base pairing with dA and dG-nucleotide at corresponding locations in the first primer extension product and thus support the amplification of both allelic variants generally.

Due to a strand of a double-complementary target nucleic acid strand, specific amplification systems are created, each either 2 ^'-0-alkyl modifications of cytosine or ^2' -0-alkyl modifications of adenosine is used in corresponding locations. Thus, the lack of discrimination of G and U nucleotide analogs can be circumvented.

Reaction conditions in the strand displacement reaction

The displacement of the second primer extension product from binding with the first primer extension product by means of a sequence-dependent strand displacement by the controller oligonucleotide forms a partial step in the amplification. The reaction conditions during this step are adjusted accordingly. The reaction temperature and the reaction time are chosen so that the reaction can take place successfully.

In a preferred embodiment, the strand displacement by the controller oligonucleotide until detachment / dissociation of the second primer extension product from binding with the first primer extension product. Such dissociation of the 3 ^' segment of the first primer extension product from complementary portions of the second primer extension product may be spontaneous in the context of temperature dependent / temperature related separation of both primer extension products. Such a dissociation has a favorable effect on the kinetics of the amplification reaction and can be influenced by the choice the reaction conditions are influenced, for example by means of temperature conditions. The temperature conditions are therefore chosen such that successful strand displacement by complementary binding of the controller oligonucleotide favors dissociation of the second primer extension product from the 3 ^' segment of the first primer extension product.

In another specific embodiment, the strand displacement by the controller oligonucleotide proceeds until the dissociation / dissociation of a 3 ^' segment of the second primer extension product (P2.1-Ext) or the template strand (M1) from the complementary binding with the first primer. Extension product (P1 .1-text). In this case, this 3 ^' segment of the second primer extension product (P2.1-Ext) or the template strand (M1) comprises at least one complementary region to the first primer and a complementary segment to the first primer extension product (P1 1-Ext) the enzymatic synthesis has arisen. This results in the formation of a complex (C1 .1 / P1 1 -Ext / P2.1.-Ext) or (C1 .1 / P1 .1 -Ext / M1), which contains both the first primer extension product (P1. 1 -xt), the second primer extension product (P2.1-Ext) / or the template strand (M1) and the controller oligonucleotide (C1 .1). In such a complex, the 3 ^' segment of the second primer extension product is at least transiently single-stranded since it can be displaced from the controller oligonucleotide from its binding with the first primer extension product. Schematically, there is a balance between binding and detachment of the P2.1 -Ext / or M1 to the P1 .1 text. The 3 ^' segment of the first primer extension product (P1 .1-Ext) is in such a complex complementary hybridized to the second primer extension product (P2.1 -Ext) or to a template strand (M1).

Due to a partially open primer binding site for the first primer oligonucleotide (3 ^' segment of the second primer extension product), a new primer extension product (P1 .2) can be attached to this single-stranded sequence segment of the complex (P2.1 Ext) under reaction conditions and thus initiate a synthesis of a new first primer extension product (P1 .2-Ext) by a polymerase. In general, the initiation of this reaction with reduced efficiency, since the 3 ^' segment of P2.1 -Ext is not permanently single-stranded, but is in the competitive behavior with the controller oligonucleotide and thus alternately single-stranded and double-stranded states by binding to the P1 1 -Ext has.

Continuing this newly started synthesis of P1 2-Ext using the second primer extension product as template (P2.1-Ext), polymerase-induced strand displacement can also dissociate the complex (C1.1 / P1 1 -Ext / P2.1. -Ext) lead. The controller oligonucleotide, the temperature-dependent double strand destabilization and the strand displacement by the polymerase act synergistically and complementarily. This results in a dissociation of the 3 ^' segment of the first primer Extension product (P1 .1 -EX) of complementary portions of the second primer extension product (P2.1-Ext).

Such dissociation has a favorable effect on the kinetics of the amplification reaction and may be influenced by the choice of reaction conditions, e.g. by means of temperature conditions. The involvement of the polymerase-mediated synthesis-dependent strand displacement in the dissociation of P1 .1-Ext and P2.1 -xt has a favorable effect on strand separation.

The temperature in this step includes, for example, ranges from 15 ° C to 75 ° C, especially from 30 ° C to 70 ° C, especially from 50 ° C to 70 ° C.

Given the length of the first region of the controller oligonucleotide and the second region of the first primer oligonucleotide (including, for example, ranges of from 3 to 25 nucleotide monomers, more preferably from 5 to 15 nucleotide monomers), a strand displacement reaction can generally be successfully initiated. With complete complementarity of the controller oligonucleotide to corresponding portions of the first primer extension product, the controller oligonucleotide can bind to the first primer extension product except for the 3 ^' segment of the first primer extension product and displace the second primer extension product. The second primer extension product thus remains in association with the 3 ^' segment of the first primer extension product. The strength of this compound can be influenced by temperature. Upon reaching a critical temperature, this compound can decay and dissociate both primer extension products. The shorter the sequence of the 3 ^' segment, the more unstable this compound and the lower the temperature which causes spontaneous dissociation.

A spontaneous dissociation can be achieved for example in the temperature range, which is approximately at the melting temperature. In certain embodiments, the temperature of the strand displacement steps through the controller oligonucleotide is at about the melting temperature (Tm +/- 3 ° C) of the complex comprising the 3 ^' segment of the first primer extension product that is not bound by the controller oligonucleotide , and the second primer oligonucleotide and the second primer extension product, respectively.

In certain embodiments, the temperature of the strand displacement steps through the controller oligonucleotide is at about the melting temperature (Tm +/- 5 ° C) of the complex comprising the 3 ^' segment of the first primer extension product that is not bound by controller oligonucleotide , and the second primer oligonucleotide and the second primer extension product, respectively.

In certain embodiments, the temperature of the strand displacement steps through the controller oligonucleotide is above the melting temperature of the complex comprising the 3 ^' segment of the first primer extension product other than controller oligonucleotide and the second primer oligonucleotide and the second primer extension product, respectively. Such a temperature includes temperature ranges from about Tm + 5 ° C to Tm + 20 ° C, especially from Tm + 5 ° C to Tm + 10 ° C. By using a higher temperature, the equilibrium in this reaction step can be shifted towards dissociation. As a result, the kinetics of the reaction can be favorably influenced. Use of too low temperatures in the strand displacement step by controller oligonucleotide can result in a significant slowing of the amplification.

In certain embodiments, a first primer extension product comprises a 3 ^' segment which is not bound by the controller oligonucleotide, and which

Sequence lengths from 9 to about 18 nucleotides. In this embodiment, spontaneous dissociation can usually be achieved already at temperature ranges between 40 ° C and 65 ° C. Higher temperatures also lead to dissociation.

Sequence lengths from 15 to about 25 nucleotides. In this embodiment, spontaneous dissociation can usually be achieved already at temperature ranges between 50 ° C and 70 ° C. Higher temperatures also lead to dissociation.

Sequence lengths from 20 to about 40 nucleotides. In this embodiment, a spontaneous dissociation usually already at temperature ranges between 50 ° C and 75 ° C can be achieved. Higher temperatures also lead to dissociation.

The composition of the 3 ^' segment of the first primer extension product and optionally an introduction of melting temperature-influencing oligonucleotide modifications (eg MGB) or reaction conditions (eg TPAC, betaine) can influence the choice of temperature. An appropriate adaptation can therefore be made.

In certain embodiments, the single steps of strand displacement by controller oligonucleotides proceed at the same temperature as the synthesis of the first and second primer extension products. In certain embodiments, the single steps of strand displacement by controller oligonucleotides occur at a temperature that is different from the temperature of the particular synthesis of the first and second primer extension products. In certain embodiments, synthesis of the first primer extension product and strand displacement by the controller oligonucleotide is included same temperature. In certain embodiments, synthesis of the second primer extension product and strand displacement by the controller oligonucleotide proceeds at the same temperature.

The concentration of the controller oligonucleotide comprises ranges from 0.01 pmol / l to 50 pmol / l, in particular from 0.1 pmol / l to 20 pmol / l, in particular from 0.1 pmol / l to 10 pmol / l.

Primer oligonucleotides comprising additional sequence segments:

The above-mentioned structures of the first primer and the second primer can be considered as so-called "base structure of the primer" or "minimal structure of the primer".

Such basic structures of oligonucleotides with primer function (eg, first primer oligonucleotide, second primer oligonucleotide, optionally third primer oligonucleotide, optionally fourth primer oligonucleotide, etc.) comprise sequence segments which are essential for the execution of the amplification reaction. Method are advantageous, for example, the first and second region of the first primer.

Such a basic structure of the primer can be extended by additional, additional sequence segments. Such additional sequence segments include structures which, while not necessary for the performance of the amplification process, may nevertheless be useful for other tasks.

Such additional sequence segments may optionally be introduced into a primer and used for further functions or reactions. This can be done by the

Polymerase synthesized primer extension products (starting, for example, from the first and / or the second primer) can be linked to such sequences segments. This achieves integration of such additional sequence segments and primer extension products into a molecular structure. Such integration may be advantageous in certain embodiments. A multitude of applications for primer sequences with additional

Sequence segments are known to a person skilled in the art.

Several functions are known to a person skilled in the art, which are supported by additional sequence segments of the primer.

The introduction of additional structures can be used, for example, as a means of imparting intermolecular or intramolecular bonding. A person skilled in the art is aware of several examples of such structures. For example, probes may be designed according to such a principle of intra-molecular binding, e.g. as part of Scorpion primers. For example, sequence segments can be used to bind further

Serve oligonucleotides. In this case, a sequence-specific intermolecular binding can be achieved using stringent conditions. Such interactions can for example, for the binding of amplification products to a solid phase by complementary binding to immobilized oligonucleotides.

Another example introduces so-called adapter sequences and / or

Use of further sequence segments for the unique coding or sequence-specific labeling of primers and primer extension products emanating therefrom (so-called primer barcoding). This is used, for example, for NGS library preparation (Stählberg et al Nucleic Acids Res. 2016 Jun 20; 44 (11): e105). In the sequence analysis of primer extension products, such a label can be used to assign sequences later.

Yet another example is the use of further sequence segments

Introduction of specific sequences with binding of certain proteins, e.g. Restriction endonucleases etc.

Yet another example is the use of further sequence segments

Introduction of spacer-sequence sequences, which are not intended to bind a specific interaction partner, but serve primarily to increase the distance between adjacent sequences.

Such additional sequences may either be positioned on the copiable portion of the primer or added to the non-clippable portion of the primer. Several factors play a role in judging whether a sequence segment is copied or not.

For example, positioning of the sequence segment in the respective oligonucleotide, nucleotide modifications used (eg C3, HEG, 2 ^' -Ome etc.) can decide whether or not a sequence segment is used as a template during a process step.

In one embodiment, an additional sequence segment is introduced into the copyable region of the primer, eg, at the 5 ^' segment of the copiable portion of the second primer, so that, for example, in reading the primer sequence during a synthesis of a target sequence, additional sequence Segments are also read from the polymerase. The length of such additional sequence segment includes ranges of 3 to 50 nucleotides. The composition of these sequence segments leaves at this

Embodiment, the synthesis by a polymerase, this sequence segment thus serves as a template for polymerase-dependent synthesis. In such a segment will be

For example, using natural nucleotides, e.g. dA, dG, dC, dT.

In a further embodiment, additional sequence segments may be positioned, for example, at the 5 ^' terminus of the primer, which is not useful in the synthesis of specific

Amplification fragments comprising a target sequence to be copied. This can be achieved, for example, by positioning one or more modifications or chemical groups which prevents polymerase from the synthesis of a complementary strand (eg HEG, C3, a segment comprising 4 to 10 nucleotides with 2 ^'to- Ome modifications Etc.). Such modification may for example be positioned at the 5 ^'terminus of the copyable portion of the second primer and obstruct the continuation of the synthesis. For example, an HEG group may be introduced at the 5 ^' end of the copiable segment of the second primer, followed by an additional sequence segment.

Furthermore, an additional sequence segment may be positioned at the 5 ^' terminus of the second region of the first primer. Such localization of additional sequence segments prevents synthesis of a complementary strand during regular synthesis of specific amplification products comprising a target sequence.

The length of such additional sequence segment includes ranges of 3 to 50 nucleotides. The base composition may comprise, for example, natural nucleobases (A, G, C, T, U, inosine) or modifications at different positions of nucleotides (eg at the bases such as 2-amino-adenine, iso-guanine, iso-cytosines, 5-propargyl-Uridine, 5- propargyl cytosines or the sugar-phosphate backbone, such as LNA, 2 ^'-OMe, 2 - halogen, etc.). In a certain embodiment, a first primer and additional sequence segments are combined to form an oligonucleotide. In a certain further embodiment, a second primer and additional sequence segments are combined to form an oligonucleotide.

Such additional sequence segments are designed in an oligonucleotide such that they do not prevent amplification of target sequences. this will

This is achieved, for example, by avoiding or reducing inhibiting interactions with the structures of the primers or controllers which are essential for the method. In certain embodiments, additional structures may be chosen from among

Form reaction conditions with other primer regions complementary double-stranded segments. In particular, however, such double-stranded segments do not prevent specific amplification of a target sequence. In certain embodiments, such additional sequence segments do not interact with the first or second primer region of the first primer. In certain embodiments, such additional sequence segments do not interact with the controller oligonucleotide. In certain embodiments, such additional sequence segments do not interact with other primers in the reaction. In certain embodiments, such additional sequence segments do not interact with P1.1 ext or P2.1 ext or other amplification fragments comprising a target sequence. In certain embodiments, such additional sequence segments do not form reaction-stable double-stranded portions with the first or second region of the first primer that completely inhibit the function of the first or second region.

In certain embodiments, such additional sequence segments do not interact with the second primer. In particular, in certain embodiments, such additional sequence segments do not interact with the 3 ^' segment of the second primer. In certain embodiments, the first primer comprises at its 5 ^' terminus of the second region an additional sequence segment of the first primer (variant sequence variant P1). This segment optionally includes a sequence of 10-50 nucleotides which does not interfere with the amplification process of target sequences (eg, does not form secondary structures with primers). Furthermore, this segment optionally comprises a sequence of about 5 to 15 nucleotides of the copiable first region of the first primer. The additional sequence variant P1 comprises natural nucleotides as monomers (A, C, G, T) and can potentially serve as a template for a polymerase.

In certain embodiments, the second primer comprises at its 5 ^' terminus an additional sequence segment of the second primer (variant sequence variant P2). This segment optionally includes a sequence of 10-50 nucleotides which does not match the

Amplification process of target sequences interferes (e.g., does not form secondary structures with primers). Furthermore, this segment optionally comprises a sequence of about 5 to 15 nucleotides of the copyable region of the second primer. The additional sequence variant P2 comprises natural nucleotides as monomers (A, C, G, T) and can potentially serve as a template for a polymerase.

It has been observed that such oligonucleotides comprise a first primer and

Additional sequence variant P1 or oligonucleotides comprising a second primer and

Additional sequence variant P2 are less susceptible to side reactions than

Oligonucleotides comprising only a first primer, or oligonucleotides comprising only a second primer. For example, in certain embodiments, the generation and / or amplification of nonspecific primer-dimer structures may be delayed. Thus, in such a side reaction, optionally, the formation of by-products comprising no target sequence can be reduced or retarded. As a result, for example, the premature consumption of primers can be reduced or delayed. For example, the use of such oligonucleotides is advantageous if primer dimers comprising first primers (PD P1) or primer dimers comprising second primers (PD P2) are produced by secondary reactions and lead to premature consumption of primers in the reaction. Use of primers having such additional structures (first primer with additional sequence variant P1 and / or second primer with additional sequence variant P2) is advantageous in certain embodiments if nonspecific reactions are observed in an amplification reaction. Such side reactions may be favored by several factors, including but not limited to:

• longer reaction times (for example in ranges between 1 hr and 100 hr)

Higher concentrations of primers are used (e.g., in the range between 1 pmol / l and 1 mmol / l)

• higher concentrations of polymerase are used (eg in areas above 10 unit / 10 pl) • Multiplex reactions (eg amplification of more than 10 different target sequences in a reaction mixture).

High concentrations of complex nucleic acid chains in the reaction mixture (e.g.

Concentrations above 1 μg hgDNA in 50 μl)

Individual factors can be alone or in combination with other factors

Favor side reactions.

In general, it is possible to counteract side reactions (eg nonspecific primer-dimer formation) by optimizing reaction components and / or reaction conditions, for example by reducing concentrations of individual components, shorter reaction times, sequence design of primer sequences , Choice of more stringent reaction conditions. The additional sequence segments cited in an advantageous embodiment (oligonucleotides comprising a first primer and additional sequence variant P1 or oligonucleotides comprising a second primer and additional sequence variant P2) represent a further possibility for delaying certain side reactions.

In embodiments, primer oligonucleotides with additional sequence segments are shown. In these embodiments, additional sequence segments are used which do not participate in the specific amplification of a target sequence and contribute to the delay of side reactions. Thus, oligonucleotides comprising a first primer and additional sequence variant P1 and oligonucleotides comprising a second primer and additional sequence variant P2 are used.

One skilled in the art will recognize that an oligonucleotide, in addition to a primer structure that is advantageous for the specific amplification of a target sequence (this structure may also be referred to as a "base structure" or "minimal structure"), also includes additional, additional sequence sequences. Segments may include (eg additional sequence variant P1 or additional sequence variant P2). Such additional sequence segments may provide a variety of different other beneficial properties.

Examples of embodiments of the present invention

figure description

Fig. 1 shows the sequence components of a preferred embodiment of the invention. Primer 1 .1 can bind with its first region (in 3 ^' segments) to the respective primer binding site on the template strand (M1 .1) predominantly complementary. The polynucleotide tail (primer overhang) of the second region does not bind to the template strand (M1 .1). The controller (1 .1.) Comprises a first, second and third area.

FIG. 2 schematically illustrates the topography of the complete primer extension product (P1-Ext.), Wherein the extension product comprises a region formed by primer 1 .1 and a segment synthesized by the polymerase. The synthesis of a P1-ext primer extension product is shown schematically in FIG. The synthesis progress is in this case stopped by a block oligonucleotide sequence-specific. The primer / controller complex is stable under the reaction conditions used during the synthesis phase. The synthesis of the P1-Ext by the polymerase goes to the block oligonucleotide (B 1.1), so that the length of the synthesized segment of the P1-Ext is limited.

The sequence-specific control of primer extension is mediated in particular by the binding of the controller oligonucleotide. The controller binding to the primer extension product during the control phase is shown schematically in Figure 4, where A) the release of the controller from the complex: primer / controller; B-C), the binding of the controller to the second region of the primer on the primer extension product, and D-E) illustrates the sequence-specific strand displacement by the controller to release the template strand.

FIG. 5 schematically shows a probe binding to the primer extension product after its release from the template strand. Release from the template strand allows the 3 ^' segment of the P1-Ext to interact with another oligonucleotide, such as a fluorescent probe (S1 .1), or other primers or an affinity probe. For example, a binding can lead to the increase of a fluorescence signal.

As a probe, for example, a complementary to the 3 ^' segment of the primer extension product formed oligonucleotide with a quencher (eg BHQ1) and a reporter (eg FAM) can be used. As a reporter, for example, a molecular beacon with self-quenching properties can be used. The signal is generated only when a complementary bond. This allows, for example, complete P1-text to be distinguished from incomplete ones.

The synthesis phase and the controlling phase may take place simultaneously, as illustrated by the reaction approach illustrated in FIG. Controller and primer as well as their complex are in equilibrium during the reaction (Figure 6 A)). The synthesis of the primer extension product is initiated by the addition of a polymerase. Upon primer binding to the primer binding site, the polymerase can start the synthesis of a complementary primer extension product (Figure 6B)). The polymerase-catalyzed synthesis of fully complementary products occurs faster than the synthesis of products that involve a mismatch due to an error arising during the synthesis. The mismatch strands are synthesized more slowly.

In Fig. 7 and 8 further schematic representations of a reaction mixture with simultaneous synthesis phase and controlling phase are shown. Controller and primer as well as their complex are in equilibrium during the reaction before (Fig. 7 A), Fig. 8 B)). The free-of-charge controllers can interact with the primer extension products during the synthesis phase. The interaction starts at the second primer area of a respective primer extension product (Figure 7B), Figure 8B)). The result of the controller's interaction with the primer extension products will be different depending on the progress of the synthesis of the primer extension product: with fully synthesized P1-Ext, this product may be released. In this case, a fully synthesized P1 -ex can interact through its 3 ^' segment with other oligonucleotides, eg probes, primers etc. (FIG. 8C)). Incompletely synthesized P1-Ext also leads to a detachment of this product from the template strand. The complex formed is sufficiently stable under reaction conditions, so that this incomplete primer extension product can be excluded from a continuation of its synthesis at the template strand or is prevented by the complex form with the controller strongly to the continuation of the template-dependent synthesis reaction. Thus, the synthesis of defective primer extension products can be prevented to full synthesis length. For example, due to insufficient length, such incomplete P1 ext does not include the required sequence segments to participate in other reactions. For example, here a 3 ^' segment is missing in the primer extension product (Figure 8D)).

Figures 9A-C schematically show the topography of a template strand (comprising a target sequence) with a polymorphic locus (N2) and two unitary target sequence segments (N1 and N3). The template strand with the first variant (M 1.1) and the template strand with the second variant (M 1 .2) schematically show the topography of a target sequence within template strands. Both template strands comprise target sequence segments N1 and N3, which are identical and uniform in both template strands. The respective sequence segment N2 is characteristic and specific in each template strand, so that both template streaks can be distinguished by it. N2 comprises at least two sequence variants of a polymorphic locus of a target sequence. M 1 .1 = template with the first variant of the target sequence. M 1.2 = template with the second variant of the target sequence. N1 = first unified target sequence segment in which S1.1 is identical to S1 .2. N2 = polymorphic locus, in which S1.1 is not identical to S1.2. N3 = second uniform target sequence segment, in which S1 .1 is identical to S1 .2. B1.1 block oligonucleotide for limiting a primer extension.

In this embodiment, a target sequence, which may comprise a plurality of sequence variants in a polymorphic locus (N2), furthermore comprises at least a first target sequence segment (N1) which is suitable for all target sequence variants of a target sequence (target sequence group comprising M 1 .1 and M 1 .2 ) is characteristic and uniform. Furthermore, a target sequence comprises at least one second target sequence segment (N3) which is characteristic and uniform for all target sequence variants of a target sequence (target sequence group comprising M 1 .1 and M 1 .2 here). Such uniform target sequence segments are preferably located on either side of a polymorphic locus and thus flank a polymorphic locus (with sequence variants) of a target sequence from both sides. Preferably, the first uniform target sequence segment (N1) differs in its sequence composition from the Sequence composition of the second unitary target sequence segment (N3) in at least one nucleotide position.

Figures 10 (A - C) show schematically the topography of a template strand with a polymorphic locus (N2) and two unitary target sequence segments (N1 and N3) as shown in Figure 9.

Figure 10D shows the result of strand separation after primer extension by two specific and unique controller oligonucleotides (C1.1 and C1 .2), each of which controller oligonucleotides provides a polymorphic locus of the target sequence (N2) corresponding sequence segment, wherein C1 .1 and C1 .2 differ in this sequence segment. This results in a specific and characteristic pairing of a specific and characteristic sequence variant (an allelic variant) of a specific target sequence and a specific for this sequence variant and specific controller oligonucleotide.

The figure summarizes schematically the effect of the presence of the fully complementary strand (template strand) on the potential mismatch duplex: Because of the fully-complementary nature of the polymerase-synthesized primer extension product, both primer extension products formed during synthesis both comprise fully-complementary sequences. Binding of such fully complementary sequences to each other is more effective than in sequences involving a mismatch. The strand separation thus runs only over a shorter distance and is less effective than with fully complementary strands.

Fig. 11 schematically shows another topography of an N2 of a target nucleic acid chain with respect to the controller oligonucleotide and the first primer.

In this embodiment, the N2-corresponding sequence segment of the controller oligonucleotide partially comprises the third region as well as partially the second region. Also, the 3 ^' segment of the first primer is designed to be sequence specific and characteristic of a specific and characteristic sequence variant of the target nucleic acid. Thus, both the controller oligonucleotide and the first primer oligonucleotide participate in allele discrimination. Thus, for each specific sequence variant of the polymorphic locus, both a specific controller oligonucleotide and a specific first primer oligonucleotide can be constructed.

Figure 12 shows schematically potential positions of a polymorphic locus within a target sequence (positions 1 to 6) and their corresponding sequence segment positions in the individual components of a primer extension system. The polymorphic loci of a target sequence shown schematically comprise 2 to 50 nucleotides, in particular 4 to 30 nucleotides, which are characteristic and specific for an allelic variant of a target sequence. Overall, the arrangement of individual amplification components can be designed so that several variants / combinations are possible:

Arrangement 1 (P1): A polymorphic locus (N2) of the target sequence overlays the first primer (in the first region) and the controller oligonucleotide (in the second region). These components of the amplification system can thus be specific and characteristic of the respective

Sequence variate of the target sequence can be constructed.

Array 2 (P2): A polymorphic locus (N2) of the target sequence overlays the first primer (in the first region) and the controller oligonucleotide (in the second region). These components of the amplification system can thus be specific and characteristic of the respective

Sequence variate of the target sequence can be constructed. Arrangement P2 differs from P1 mainly in that N2 lies predominantly in the 3 ^' terminal sequence segment of the first primer. As a result, if necessary, a better specificity of the amplification can be achieved.

Arrangement 3 (P3): A polymorphic locus (N2) of the target sequence overlays only the controller oligonucleotide (in the third region) with the corresponding sequence segment of the controller oligonucleotide in the 5 ^' segment of the synthesized portion of the first primer extension product. The controller oligonucleotide of the amplification system can thus be constructed specifically and characteristically for the respective sequence variant of the target sequence. In this arrangement, a target sequence specific first primer is used, which is not sequence variant specific. Because of the possible proximity of the second blocking moiety, the binding of the controller oligonucleotides to the first primer extension product can be affected by nucleotide modifications of the second blocking moiety.

Arrangement 4 (P4-P6): A polymorphic locus (N2) of the target sequence overlays only the controller oligonucleotide (in the third region). The controller oligonucleotide of the amplification system can thus be constructed specifically and characteristically for the respective sequence variant of the target sequence. In this arrangement, a target sequence specific first primer is used, but which are not sequence variant specific. This sequence segment of the controller oligonucleotide lies in the 5 ^' direction from the second blocking unit and may comprise several DNA nucleotide monomers, eg from 5 to 30.

Figures 13-14 show schematically the topography of a target nucleic acid chain with a polymorphic locus (N2) and two unitary target sequence segments (N1 and N3), where the polymorphic locus comprises only one nucleotide position (eg an SNV or an SNP or a point mutation Etc.). The differences between individual sequence variants thus amount to only one nucleotide (here referred to as 4.1 and 4.2). Such a locus (N2) can lead to similar arrangements of individual components as a locus with at least 2 nukeotids. When the controller oligonucleotide is bound to a complementary first primer extension product (perfect match), strand separation following a primer can thus be achieved. Extension done. In the formation of a mismatch strand separation is inhibited or slowed down or even interrupted.

Fig. 15 shows schematically potential positions of a polymorphic locus with sequence variance of only one nucleotide within a target sequence (positions 1 to 6) of a template strand and their corresponding sequence segment positions in individual components of a primer extension system.

Overall, the arrangement of individual amplification components can be designed so that several variants / combinations are possible:

Sequence variate of the target sequence can be constructed.

Sequence variate of the target sequence can be constructed. Arrangement P2 differs from P1 primarily in that N2 may be predominantly in the 3 ^' terminal sequence segment of the first primer or even comprises the 3 ^' terminal nucleotide. This may possibly result in a further increase in the specificity of the amplification.

Arrangement 3 (P3): A polymorphic locus (N2) of the target sequence overlays only the controller oligonucleotide (in the third region) with the corresponding sequence segment of the controller oligonucleotide in the 5 ^' segment of the synthesized portion of the first primer extension product. The controller oligonucleotide of the amplification system can thus be constructed specifically and characteristically for the respective sequence variant of the target sequence. In this arrangement, a target sequence specific first primer is used, but which are not sequence variant specific. Because of the possible proximity of the second blocking moiety, the binding of the controller oligonucleotides to the first primer extension product can be affected by nucleotide modifications of the second blocking moiety.

Arrangement 4 (P4-P6): A polymorphic locus (N2) of the target sequence overlays only the controller oligonucleotide (in the third region). The controller oligonucleotide of the amplification system can thus be constructed specifically and characteristically for the respective sequence variant of the target sequence. In this arrangement, a target sequence specific first primer is used, which is not sequence variant specific. This sequence segment of the controller oligonucleotide lies in the 5 ^' direction of the second blocking unit. This segment of the controller oligonucleotide may comprise multiple DNA nucleotide monomers, eg from 5 to 30, wherein the N2-corresponding sequence segment may be flanked by at least 3 to 15 DNA nucleotide building blocks on both sides.

16 schematically shows an embodiment with topography of a specific primer extension system and a polymorphic locus (N2) template strand in certain embodiments in which the N2-corresponding segment of the controller oligonucleotide lies in the second region. A specific P1 .1 may preferably bind specifically to the complementary position of a specific sequence variant of the template strand (S1.1) under reaction conditions and initiate the synthesis of the P1.1 -ext. No competitor primer is used. P1 .1 -Ext can bind complementarily to C1 .1 and be released from the template strand with its participation.

17 schematically shows an embodiment with topography of a specific primer extension system and a polymorphic locus (N2) template strand in certain embodiments in which the N2-corresponding segment of the controller oligonucleotide lies in the second region. A specific P1 .1 can preferentially bind specifically to the complementary position of a specific sequence variant of the template strand (M 1 .1) under reaction conditions and initiate the synthesis of the P1.1 -ext. During primer extension, P1.1-Ext. No competitor primer is used. The binding to another sequence variant (M 1 .2) is less efficient due to the mismatch with position (N) within the primer binding site of M 1 .2. The primer extension is thus started less efficiently under stringent reaction conditions.

Fig. 18 shows schematically an embodiment with topography of a specific primer extension system and a polymorphic locus (N2) template strand in certain embodiments in which the segment of the controller oligonucleotide corresponding to N2 lies in the second region (2). The N2 locus includes the 3 ^'- terminal nucleotide of the first primer. A specific P1.1 with a complementary 3 ^'- terminal nucleotide under the reaction conditions can preferably specifically bind to the complementary position of a specific sequence variant of the template strand (M 1 .1) bind and initiate synthesis of P1 .1-Ext. In the course of the primer extension it comes to the formation of P1.1 -Ext. No competitor primer is used. The binding to another sequence variant (SN 1 .2) is less efficient due to the mismatch with position (N) within the primer binding site of M 1.2. The primer extension is thus started less efficiently under stringent reaction conditions.

Fig. 19 shows schematically an embodiment with topography of a specific primer extension system and a polymorphic locus (N2) template strand in certain embodiments in which the segment of the controller oligonucleotide corresponding to N2 lies in the third region (Fig. 3). Target sequence specific but not sequence variant specific first primers are used. One for all sequence variants of one Target nucleic acid unitary P1 .1, can bind to the template strand and initiate the synthesis of the P1 1 -ext. During primer extension, P1 .1-Ext is formed. No competitor primer is used. The separation of primer extension products P1.1 -Ext from the template strand is preferably carried out specifically by complementary binding of P1.1 -Ext to the controller oligonucleotide. The separation of strands of another sequence variant synthesized using (M 1.2) is less efficient due to the mismatch with position (N) to the corresponding sequence segment of the controller oligonucleotide. The position of the sequence segment (3) corresponding to N2 of the target sequence is in the vicinity of the second blocking unit, so that the interaction between the controller oligonucleotide and the respective first primer extension product are affected by modifications used in the second blocking unit can.

Fig. 20 shows schematically an embodiment with topography of a specific primer extension system and a polymorphic locus (N2) template strand in certain embodiments, in which the N2-corresponding segment of the controller oligonucleotide lies in the third region (4). Target sequence specific but not sequence variant specific first primers are used. A P1.1 unitary for all sequence variants of a target nucleic acid can bind to the template strands and initiate the synthesis of the P1 1 -text. In the course of primer extension, this results in the formation of P1 1- Ext. No competitor primer is used. The separation of primer extension products P1.1 -Ext from the template strand is preferably carried out specifically by complementary binding of P1.1 -Ext to the controller oligonucleotide. The separation of strands of another sequence variant synthesized using (M 1.2) is less efficient due to the mismatch with position (N) to the corresponding sequence segment of the controller oligonucleotide. The position of the sequence segment (4) corresponding to N2 of the target sequence is at a distance from the second blocking moiety, so that the interaction between the controller oligonucleotide and the respective first primer extension product of modifications used in the second blocking moiety in FIG Essentially unaffected. The segment of the controller oligonucleotide corresponding to N2 is preferably made up of DNA monomers using between 4 to 20 DNA monomers and at least 4 to 10 DNA monomers located around position-4 on both sides.

Fig. 21 shows schematically an embodiment with topography of a specific primer extension system and a polymorphic locus (N2) template strand in certain embodiments in which the N2-corresponding segment of the controller oligonucleotide lies in the second region. A specific P1 .1 may preferably bind specifically to the complementary position of a specific sequence variant of the template strand (M 1 .1) under reaction conditions and initiate the synthesis of the P1.1 -ext. In the course of primer extension, this leads to the formation of P1 1-Ext. The binding to another sequence variant (M 1 .2) is less efficient due to the mismatch with position (N) within the primer binding site of M 1.2. The primer extension is thus started less efficiently under stringent conditions. The P5.1 forms a perfect match with M 1 .2 and can be extended by the polymerase to form a competitor primer extension product P5.1-Ext. Figure 21 shows variants of competitor primer P5.1 for P1 .1 with no overhang for binding to the controller oligonucleotide, with the 3 ^' end of P5.1 binding within the second blocking unit.

To further increase the specificity, a competitor primer oligonucleotide (P 5.1) is added to the reaction which is capable of binding predominantly complementarily to the sequence variants of the target sequence and whose copy formation with subsequent separation from the template strand is suppressed must become. Due to a complementary binding with such primer binding sites, a competitor primer may preferentially bind and be extended by the polymerase. The resulting product (here P5.1 -Ext) blocks the single-stranded primer binding sites for an interaction of the first primer.

In certain embodiments, the 3 ^' end of a competitor primer binds within the second blocking unit of the controller oligonucleotide so that extension of this primer on the controller oligonucleotide can not occur. The competitor primer does not include a sequence segment that can interact with the first region of the controller oligonucleotide. This prevents the extension product of the competitor oligonucleotide from being detached from the template.

FIG. 22 schematically shows an embodiment with topography of a specific primer extension system and a polymorphic locus (N2) template strand in certain embodiments in which the N2-corresponding segment of the controller oligonucleotide lies in the second region (FIG. 2). The N2 locus includes the 3 ^'- terminal nucleotide of the first primer. A specific P1 .1 having a complementary 3 ^' -terminal nucleotide can preferably bind specifically to the complementary position of a specific sequence variant of the template strand (M 1 .1) under reaction conditions and initiate the synthesis of the P1 1 -text. During primer extension, P1 .1-Ext. The binding to another sequence variant (M 1 .2) is less efficient due to the mismatch with position (N) within the primer binding site of SN 1.2. The primer extension is thus started less efficiently under stringent conditions.

To increase the specificity, a competitor primer (P5.2) is added to the reaction which is capable of binding predominantly complementarily to the sequence variants of the target sequence and whose primer extension and subsequent separation from the template strand must be suppressed , Due to a complementary binding with such primer binding sites, a competitor primer can preferably bind to particular sequence variants (designated here by N) and extended by the polymerase. The resulting product (P5.2-Ext) blocks the single-stranded primer binding sites for interaction with the first primer.

In certain embodiments, the 3 ^' end of a competitor primer binds within the second blocking unit of the controller oligonucleotide so that extension of this primer on the controller oligonucleotide can not occur. The competitor primer does not include a sequence segment with which it can interact with the first region of the controller oligonucleotide. This prevents the extension product of the competitor oligonucleotide from being detached from the template.

Figure 22 shows variants of competitor primer 5.2 for P1.1 with no overhang for binding to the controller oligonucleotide, with the 3 ^' end of P5.2 binding within the second blocking unit. The 3 ^' -terminal segment of P5.2 forms a perfect match with M 1.2 and can be extended by the polymerase.

FIG. 23 schematically shows an embodiment with topography of a specific primer extension system and a polymorphic locus (N2) template strand in certain embodiments in which the N2-corresponding segment of the controller oligonucleotide lies in the third region (FIG. 3). Target sequence specific but not sequence variant specific first primers are used. A P1 .1 unitary to all sequence variants of a target nucleic acid can bind to the template strands and initiate the synthesis of P1.1-Ext. During primer extension, P1 .1-Ext. The separation of synthesized primer extension products P1.1 -Ext from the template strand is preferably carried out specifically by complementary binding of P1 .1-Ext to the controller oligonucleotide. The separation of strands of another sequence variant synthesized using (M 1.2) is less efficient due to the mismatch with position (N) to the corresponding sequence segment of the controller oligonucleotide. The position of the sequence segment (3) corresponding to N2 of the target sequence is in the vicinity of the second blocking unit, so that the interaction between the controller oligonucleotide and the respective first primer extension product are affected by modifications used in the second blocking unit can.

To increase the specificity, a competitor primer (P5.3) is added to the reaction which is able to bind predominantly complementarily to the sequence variants of the target sequence (N) and whose copy generation and subsequent strand separation must be suppressed. Due to a complementary binding with such primer binding sites, a competitor primer may preferentially bind to certain sequence variants (designated here by N) and be extended by the polymerase. The resulting product blocks the single-stranded primer binding sites for interaction with the first primer.

In certain embodiments, the competitor primer oligonucleotide (P5.3) is longer than the first primer oligonucleotide such that its 3 ^' end is within the fourth blocking moiety of the Controller oligonucleotide can bind (the fourth blocking unit is assembled analogously to the second blocking unit and blocks a primer extension on the controller oligonucleotide), so that no extension of this primer can be done on the controller oligonucleotide. The competitor primer does not include a sequence segment which can interact with the first region of the controller oligonucleotide. This prevents the extension product of the competitor oligonucleotide from being detached from the template.

Figure 23 shows variants of competitor primer 5.3 for P1.1 with no overhang for binding to the controller oligonucleotide, with the 3 ^' end of P5.3 binding within the fourth blocking unit. The 3 ^' -terminal segment of P5.3 forms a perfect match with M 1.2 and can be extended by the polymerase.

Figure 24 shows schematically a selective primer extension reaction of several sequence variants using multiple selective controller oligonucleotides (C1.1 and C1.2).

Figures 25-29 show schematically the structure of the first primer oligonucleotide and the controller oligonucleotide, as well as the interaction between the first primer oligonucleotide and the template, as well as the synthesis of the first primer extension product.

Figure 30 shows schematically the interaction between structures during primer extension of the first primer oligonucleotide.

Fig. 31 shows results of Example 1

Fig. 32 shows results of Example 2

Fig. 33 shows schematically some embodiments of structures of a starting nucleic acid chain and their use as template at the beginning of the reaction. Using P1.1, without block oligonucleotide.

Fig. 34 shows schematically some embodiments of structures of a starting nucleic acid chain and their use as a template at the beginning of the reaction. Using P1.1, with block oligonucleotide.

FIG. 35 shows schematically the interaction of the structures during the nucleic acid amplification by, on the one hand, the amplification of the first primer oligonucleotide and of the second primer oligonucleotide and furthermore the action of the controller oligonucleotide and the resulting strand displacement.

FIGS. 36-38 show results from Example 4

Fig. 39 shows schematically an embodiment with topography of a specific primer extension system and a template strand with a polymorphic locus (N2) in certain embodiments, in addition to other illustrations the following nomenclature of reaction components and sequence segments is used: a) a sample comprising a nucleic acid polymer comprising the target sequence M, wherein the target sequence in 5'-3 'orientation comprises the sequence sections MS and MP and MP is located directly in 3' of MS, with the following

Components is brought into contact:

b) an oligonucleotide primer P which comprises the sequence sections PC and PM in the 5'-3 'orientation and PM is arranged directly in 3' of PC, wherein PM has the sequence [MPa] complementary to the sequence section MP [that binds] in a substantially sequence-specific manner can] and PC can not bind to M [or a sequence immediately adjacent to MP in 3 '];

c) a controller oligonucleotide C which in 5'-3 'orientation the

Sequence sections CS, CP and CC, where CP is located immediately in the 3 'direction of CS and immediately in the 5' direction of CC, and where CS is at least to the 3 ^' segment of MS (immediately in the 5' direction of MP lying) and CP and CC to the sequence section PM and PC

complementary [hybridizing] sequence and wherein CS comprises modified nucleotide building blocks such that CS can not serve as a template for the activity of the template-dependent nucleic acid polymerase;

d) a template-dependent nucleic acid polymerase, in particular a DNA polymerase, as well as substrates of the DNA polymerase (in particular ribonucleoside triphosphates or deoxyribonucleoside triphosphates) and suitable cofactors, a primer extension product P 'being obtained which, besides the

Sequence areas PC and PM comprises a synthesized area PS, which is substantially complementary to the target sequence MS,

and where

either the reaction conditions are chosen, and / or

the lengths and the melting temperature of PC and possibly MS are selected so that P 'can form a double strand with M and P' can form a double strand with C and the formation of the double strand from P 'and C opposite the formation of the double strand from P 'is preferred with M.

The method according to certain embodiments, wherein the sequence section CS at its 3 'end immediately in the 5' direction of the sequence section CP a

Sequence section CS 'of 5 to 15 nucleotide positions contains length, which consists of nucleic acid analogs, in particular of 2'0-alkyl ribonucleotides.

The method according to any one of the preceding embodiments, wherein M comprises a sequence portion MB immediately in 5 'of MS, and further wherein a block oligonucleotide B capable of hybridizing to MB is contacted with the sample, and wherein a. B comprises nucleoside analogs selected such that a B hybrid to MB does not permit the MB-dependent nucleic acid polymerase reaction on MB or

b. the template-dependent nucleic acid polymerase is selected such that a

Hybrid of B with MB [even if B from natural nucleosides or

Deoxynucleosides], the reaction of the template-dependent nucleic acid polymerase on MB is not allowed.

The terms used in this embodiment illustrate certain variants of the structures described in the application.

A nucleic acid polymer (one embodiment of the template) comprises the target sequence M, which comprises the sequence segments MS and MP and MP in the 5'-3 'orientation and is located directly in 3' of MS. In one embodiment, the target sequence comprises a polymorphic locus (N2).

An oligonucleotide primer P (corresponding to a first primer oligonucleotide) comprises, in 5'-3 'orientation, the sequence segments PC (corresponding to a second region of the first primer oligonucleotide) and PM (corresponding to a first region of the first primer oligonucleotide).

A controller oligonucleotide C comprises, in 5'-3 'orientation, the sequence sections CS (corresponding to a third region of the controller oligonucleotide), CP (corresponding to a second region of the controller oligonucleotide) and CC (corresponding to a first region of the controller oligonucleotide )

A primer extension product P '(corresponding to a first primer extension product) is obtained by template-dependent extension of the first primer oligonucleotide. In addition to the sequence regions PC and PM, the primer extension product comprises a synthesized region PS which is essentially complementary to the target sequence MS

A variant VM of the target sequence M is different from the sequence M in at least one position VMM. In particular, this position has one or more substitution (s), insertion (s) and / or deletion (s). This position VMM in this embodiment is a sequence variant of the polymorphic locus (N2) of the target sequence. In one embodiment, VMM is at the 5 'end of VMP. in other words, the 3 'end of VPM hybridizes with VMM.

A second controller oligonucleotide VC comprises in the 5'-3 'orientation the sequence sections VCS (corresponding to a third area of the controller oligonucleotide), VCP (corresponding to a second area of the controller oligonucleotide) and VCC (corresponding to a first area of the controller). oligonucleotide).

A second oligonucleotide primer VP (corresponding to a variant of a first primer oligonucleotide) comprises, in the 5'-3 'orientation, the sequence segments VPC (corresponding to a second region of the first primer oligonucleotide) and VPM (corresponds to a first region the first primer oligonucleotide) and VPM is located immediately in 3 'of VPC, where VPM has [the hybridizing] sequence complementary to the sequence portion VMP of the target sequence VM and can not bind VPC to VM [or one in 3 'immediately following VMP sequence] can bind. In one embodiment, VMM (polymorphic locus N2) of the target sequence resides at the 5 'end of VMP and the 3' end of VPM (of the first primer oligonucleotide) can be specifically hybridized with VMM.

A competitor oligonucleotide KP can hybridize to the target sequence. In one embodiment, KP can hybridize with VMP of the target sequence.

In one embodiment, a block oligonucleotide B can hybridize to a sequence portion of the target sequence MB immediately adjacent to the 5 'direction of MS, where B comprises nucleoside analogs selected such that a hybrid (complex) of B with MB is the response of a template-dependent one Nucleic acid polymerase not allowed on MB.

Figures 40-58 schematically show certain embodiments for using a primer extension product as a starting nucleic acid chain for an amplification method.

52 shows variants of competitor primer P 5.1 for P1 .1:

• P5.1 does not contain an overhang for binding to the activator oligonucleotide.

• 3 ^' - end of P5.1 binds within the second blocking unit

• P5.1 forms a perfect match with SN 1.2 and can be extended by the polymerase

• P5.1 has the same length as the first range of P1 .1

FIG. 53 shows variants of competitor primer P 5.2 for P1 .1:

• P5.2 does not contain an overhang for binding to the activator oligonucleotide.

• 3 ^' - End of P5.2 binds within the second blocking unit

• 3 ^' terminal segment of P5.2 includes at least one mismatch to SN 1 .1

• 3 ^' terminal segment of P1.1 includes at least one mismatch to SN 1 .2

• P5.2 forms a perfect match with SN 1.2 and can be extended by the polymerase

• P5.2 has a longer binding segment at SN 1 .2 than the first region of P1.1

FIG. 54 shows variants of competitor primer P 5.3 or P5.4 for P1 .1:

• P5.3 does not contain an overhang for binding to the activator oligonucleotide.

• 3 ^' - End of P5.3 or P5.4 binds within the fourth blocking unit

• P5.3 forms a perfect match with SN 1.2 and can be extended by the polymerase

• P5.3 has a longer segment to bind to SN 1.2 than the first range of P1 .1

• P5.3 blocks the segment complementary to P1 .1 in SN 1 .2

Figures 59-60 schematically show certain topographical embodiments of a specific primer extension system and a polymorphic locus (N2) template strand in certain embodiments, in addition to other illustrations, the following are Nomenclature of reaction components and sequence segments used (see nomenclature Fig. 39).

For Figure 58: P3.1-Ext part 1 = extension product of P3.1 synthesized on P2.1 -EX as template. P4.1 Ext Part 1 = Extension product of P4.1 synthesized on P1.1 -xt as template. P3.1-Ext = extension product of P3.1 synthesized using P4.1 -Ext part 1 or at the P4.1 -Ext as template. P4.1 -Ext = extension product of P4.1 synthesized using P3.1 Ext part 1 or at the P3.1 text as template.

Examples:

Material and methods:

Reagents were purchased from the following commercial suppliers:

unmodified and modified oligonucleotides (Eurofins MWG, Eurogentec, Biomers, Trilink Technologies, IBA Solutions for Life Sciences); Polymerases NEB (New England Biolabs); dNTP ^'s : Jena Bioscience; intercalating EvaGreen dye: Jena Bioscience; Buffer substances and other chemicals: Sigma-Aldrich; Plastic goods: Sarstedt

Solution 1 (amplification reaction solution 1):

Potassium glutamate, 50 mmol / l, pH 8.0; Magnesium acetate, 10 mmol / l; dNTP (dATP, dCTP, dTTP, dGTP), 200 pmol / l each; Polymerase (Bst 2.0 warm start, 120,000 U / ml NEB), 12 units / 10 pl;

Triton X-100, 0.1% (v / v); EDTA, 0.1 mmol / l; TPAC (tetrapropylammonium chloride), 50 mmol / l, pH 8.0; EvaGreen dye (dye was according to manufacturer's instructions in

Dilution 1: 50 used).

Solution 2 (amplification reaction solution 2):

1x isothermal buffer (New England Biolabs); in simple concentration, the buffer contains: 20 mM Tris-HCl; 10mM (NH ₄ ) ₂ S0 ₄ ; 50 mM KCl; 2mM MgSO ₄ ; 0.1% Tween® 20; pH 8.8@25 ° C); dNTP (dATP, dCTP, dUTP, dGTP), 200 pmol / l each;

EvaGreen dye (dye was used according to manufacturer's instructions in 1:50 dilution)

All concentrations are indications of the final concentrations in the reaction. Deviations from the standard reaction are indicated accordingly.

The melting temperature (Tm) of the components involved was determined at concentration of 1 pmol / l of respective components in solution 1 or 2. Different parameters are indicated in each case.

General information about reactions

Primer extension reactions and amplification were performed by default at two reaction temperatures of 55 ° C and / or 65 ° C. Deviations are indicated. The start of the reaction was carried out by heating the reaction solutions to reaction temperature, since Bst 2.0 polymerase warm start at lower temperatures is largely inhibited in their function by a temperature-sensitive oligonucleotide (an "aptamer" according to the manufacturer). The polymerase becomes increasingly more active from a temperature of about 45 ° C, at a temperature of 65 ° C, no differences between Polymerase Bst 2.0 and Bst 2.0 warm start were found. To prevent the extensive formation of byproducts (eg, primer dimers) during the preparation phase of a reaction, Polymerase Bst 2.0 Warmstart was used. Deviations are specified.

The reaction was stopped by heating the reaction solution to above 80 ° C, e.g. 10 min at 95 ° C. At this temperature, the polymerase Bst 2.0 is irreversibly denatured and the result of the synthesis reaction can not be subsequently changed.

Reactions were carried out in a thermostat with a fluorescence measuring device. For this purpose, a commercial real-time PCR device was used, StepOne Plus (Applied Biosystems, Thermofischer). The reaction volume was 10 pl by default. Deviations are indicated.

Both endpoint determination and kinetic observations were made. For example, in endpoint determinations, the signal was registered by nucleic acids bound to nucleic acids, e.g. TMR (tetramethyl-rhodamine, also called TAMRA) or FAM (fluorescein). The wavelengths for excitation and measurement of the fluorescence signals of FAM and TMR are stored as factory settings in the StepOne Plus Real-Time PCR device. Also, an intercalating dye (EvaGreen) was used in end point measurements, e.g. when measuring a melting curve). EvaGreen is an intercalating dye and is an analog of the commonly used dye Sybrgreen, but with slightly less inhibition of polymerases. The wavelengths for excitation and measurement of the fluorescence signals of SybrGreen and EvaGreen are identical and are stored as factory settings in the StepOne Plus Real-Time PCR device. Fluorescence can be monitored continuously by means of built-in detectors, i. "online" or "real-time" are detected. Since the polymerase synthesizes a double strand during its synthesis, this technique could be used for kinetic measurements (real-time monitoring) of the reaction. Due to some cross-talk between color channels in the StepOne Plus device, partially increased basal signal intensity was observed in measurements where e.g. TMR-labeled primers in concentrations greater than 1 pmol / L (e.g., 10 pmol / L) were used. It has been observed that the TMR signal in the SybrGreen channel leads to increased baselines. These increased baseline values were taken into account in calculations.

The kinetic observations of response curves were routinely recorded by fluorescence signals from fluorescein (FAM-TAMRA Fret pair) and intercalating dyes (EvaGreen), respectively. Time-dependence of the signal course was registered (real-time signal acquisition with StepOne plus PCR device). An increase in the signal during a reaction compared with a control reaction was interpreted according to the structure of the approach. For example, an increase in the signal using Evagreen dye was interpreted as an indication of an increase in the amount of double-stranded nucleic acid chains during the reaction, and thus as a result of ongoing DNA polymerase synthesis.

In some reactions, a melting curve determination was usually performed following the reaction. Such measurements allow conclusions about the presence of double strands, which can absorb, for example, intercalating dyes and thereby significantly enhance the signal intensity of dyes. As the temperature increases, the proportion of double strands decreases and the signal intensity also decreases. The signal is dependent on the length of nucleic acid chains and on the sequence composition. This technique is well known to a person skilled in the art.

For example, when using melting curve analysis in conjunction with reactions containing significant levels of modified nucleic acid chains (eg, controller oligonucleotides or primers), the EvaGreen dye signal was found to differ between B-form of DNA and A-form of DNA can behave modified nucleic acid chains. For example, in the B-form of the double-stranded nucleic acid chains (commonly believed for classical DNA segments), higher signal intensity has been observed than with double-stranded nucleic acid chains having the same sequence of nucleobases which may adopt an A-form-like conformation (eg, multiple 2 ^'-0-Me modifications of nucleotides). This observation has been taken into account when using intercalating dyes.

If necessary, the reaction was analyzed by capillary electrophoresis and the length of fragments formed was compared to a standard. In preparation for capillary electrophoresis, the reaction mixture was diluted in a buffer (Tris-HCl, 20 mmol / l, pH 8.0, and EDTA, 20 mmol / l, pH 8.0) to such an extent that the concentration of labeled nucleic acids was ca. 20 nmol / l. Capillary electrophoresis was performed by GATC-Biotech (Konstanz, Germany) as a contract performance. According to the supplier, capillary electrophoresis was performed on an ABI 3730 Cappilary Sequencer under standard conditions for Sanger sequencing using POP7 gel matrix, at about 50 ° C and at constant voltage (about 10 kV). The conditions used led to the denaturation of double strands, so that in capillary electrophoresis the single-stranded form of nucleic acid chains was separated. Electrophoresis is a standard technique in genetic analysis. Automated capillary electrophoresis is now routinely used in Sanger sequencing. The fluorescence signal is continuously recorded during capillary electrophoresis (usually using virtual filters) to produce an electrophorogram in which the signal intensity correlates with the duration of the electrophoresis. For shorter fragments, eg unused primers observed an earlier signal peak, with extended fragments there is a time shift of the signals proportional to the length of the extended area. Thanks to guided controls of known lengths, the length of extended fragments can be measured. This technique is known to a person skilled in the art and is also used by default in fragment length polymorphism.

Unless otherwise defined with respect to a particular sequence, both upper case and lower case letters agct and AGCT refer to the deoxyribonucleotide building blocks of the DNA, or the corresponding ribonucleotides or base analogs. In some embodiments, uracil nucleobases are used in modified sequence segments, so as the sugar 2 were - OMe modifications used (ribose 2 ^'-0-methyl modification). Other 2 ^'-0-alkyl modifications are possible. In amplification approaches with dUTP (especially first amplification reaction), amplification fragments are generated which comprise dUMP (as protection against contamination). In general, however uracil bases can be used with both 2 ^{'-deoxy-ribose} and ribose; The person skilled in the disclosure as a whole extracts from the disclosure the teaching relating to the respective sequence segments of the sequences used here for determining at which sites classical DNA backbones, RNA or base analogues can be usefully used.

Example 1 :

A primer extension reaction for the preparation of a primer extension product using sequence variants of a target sequence and subsequent use of the synthesized primer extension product in an amplification reaction.

In this example the influence of sequence differences in two matrices on the interaction with the controller after a synthesis phase was investigated. Two templates were provided which included a sequence difference at a nucleotide position. Upon extension of the first primer oligonucleotide, a complementary strand was formed in each case which had a complementary sequence to the respective template and thus likewise comprised this sequence difference in the sequence. Both templates included a uniform primer binding site so that a single primer could be used. Discrimination between individual sequence variants of the target sequence thus took place by means of a specific controller oligonucleotide.

The generated during the synthesis phase primer extension products can be replaced by controllers mainly specifically of template strands. The primer extension products comprise a 3 ^' segment that is not bound by a controller oligonucleotide. This 3 ^' segment of the first primer extension product may be complementarily bound by another oligonucleotide, eg a primer. First primer extension products generated in this manner can be amplified in a subsequent amplification reaction using a further second primer. The amplification reaction thus serves to illustrate an effect of a controlling phase (strand separation by a controller) after a synthesis phase.

The following matrices were used:

Template with sequence composition leading to a first primer extension product with a perfect match with the controller oligonucleotide:

M2SF5-M001 -200

5 ^' GCT CATA CTACAATGTCA CTTA CTGTAA GAGCAGATCC CTGGACAGGC AA GGAATACAGGTA AAAAA 3 ^' (SEQ ID NO: 001)

A = 2 ^{'deoxy-adenosine;} C = 2 ^{'deoxy-cytosine;} G = 2 ^{'deoxy-guanosine;} T = 2 ^{'deoxy-thymidine} (thymidine)

The binding sequence for the first primer oligonucleotide is underlined.

Template-sequence template resulting in a first primer extension product that mismatches with the controller oligonucleotide at a single base position (in bold):

M2SF5-WT01-200

5 ^' GCT CATA CTACAATGTCA CTTA CTGTAA GAGCAGATCC CTGGACAGGC GA GGAATACAGGTA AAAAA 3 ^' (SEQ ID NO: 002)

The binding sequence for the first primer oligonucleotide is underlined.

The following primers were used:

The first primer oligonucleotide: P1 F5-200-AE2053

5 ^' AACTCAGACAAGATGTGA IIIIIII ACCTGTAT [CUCU GAUGCUUC] 1TACCTGTATTCC 3 ^' (SEQ ID NO: 003)

The segment used as the primer in the reaction is underlined.

This oligonucleotide included the following modifications:

1 = C3 linker

The compound in parentheses eckingen segment of the primer [CUCU GAUGCUUC] comprised Me modifications 2 ^'-0- and served as the second primer region capable of binding the first portion of the controller oligonucleotide: A = (2 ^{'-0-methyl-adenosine),} G = ^(2' -0-methyl-guanosine); C = (2 ^{'-0-methyl-cytosine);} U = (2 ^{'-0-methyl-uridine)}

This primer oligonucleotide comprises the first region (positions 1 - 12 from the 3 ^' end), the second region (C3 linker, as well as positions 13 - 24 from the 3 ^' end), and a segment with an additional sequence variant P1 (positions 25 - 57 from the 3 ^' end). The first region and the second region are necessary for performing a specific amplification and may be summarized as "base structure of the first primer" or "minimal structure of the first primer". The additional sequence variant P1 represents an example of additional sequence segments which can be integrated on the first primer oligonucleotide. Positions 1-12 serve as template in synthesis of the second primer extension product. C3 modification and the second region prevent synthesis from continuing at positions 25-57 during synthesis of the second primer extension product.

The following controller oligonucleotide was used: AD-F5-1001 -503

5 ^' [UAAUCUGUAA GAGCAGAUCC CUGGACAGGC AA GGAAUAC] AGGTAGAAGCATC AGAG X 3 ^' (SEQ ID NO: 004)

The set in square brackets 5 ^'segment of the oligonucleotide [UAAUCUGUAA GAGCAGAUCC CUGGACAGGC AA GGAAUAC] included ^2' -0-Me-nucleotide modifications:

Modifications: A = (2 ^{'-0-methyl-adenosine),} G = ^(2' -0-methyl-guanosine); C = (2 ^'-0-methyl cytosines); U = (2 ^{'-0-methyl-uridine)}

X = 3 ^'phosphate group for blocking a possible extension by polymerase.

The nucleotides and nucleotide modifications are linked together with phosphodiester bonds. The 3 ^' end of the controller oligonucleotide is blocked with a phosphate group to prevent possible extension by the polymerase.

The primer extension reaction was continued directly as an amplification reaction (homogeneous assay).

For this purpose, another primer (primer 2) was added to the reaction mixture before starting the primer extension reaction. This second primer can bind to the 3 ^' segment of the primer extension product synthesized in the primer extension reaction. Furthermore, this second primer can support an amplification reaction, starting from the first primer extension product, which is synthesized during the synthesis phase, which is subsequently removed in the controlling phase from its template strand by the controller. Primer 2: P2G3-5270-7063

5 ^' CT AC AG AACT AG AC AAG AT GT AACT AC AATGTT 6

G CT CAT ACT AC AATGTC ACTT ACTGTAAG AG C AG A 3 ^' (SEQ ID NO: 005)

This oligonucleotide comprises the following modifications:

6 = HEG linker

The segment used as primer in the reaction is underlined. This segment is capable of complementarily binding to the 3 ^' segment of the first primer extension product and initiating a second primer extension reaction using the first primer extension product as a template.

This primer oligonucleotide comprises a copyable region and a non-copyable region. The copyable region comprises (positions 1-13 of the 3 ^' end which can bind to sequence of the FVL gene within hgDNA and positions 14-35 which, while not complementary to the sequence of the FVL gene, bind during amplification can bind the first primer extension product). The copyable area can be summarized as "basic structure of the second primer" or "minimal structure of the second primer".

The non-copyable region (positions 36 to 70 from the 3 ^'end which is not complementary to bind to the sequence of FVL- gene) is separated by HEG modification of copiable area, which the continuation of the synthesis at positions 36-70 during synthesis prevents the first primer extension product. The non-copyable region provides an example of an additional sequence variant P2, which can be integrated on the second primer oligonucleotide.

The first primer extension reaction and the second primer extension reaction result in a duplex comprising the first and second primer extension products. Further use of both primers and the controller oligonucleotide (and repeated temperatures of 55 ° C and 65 ° C) resulted in exponential amplification involving both primer extension steps and strand separation by controller oligonucleotide. During the amplification phase, the first primer oligonucleotide continued to serve as an amplification primer.

Four approaches have been prepared:

Approach 1 contains the template M2SF5-M001-200 (Perfect Match Situation) in a concentration of 300 fmol / l (corresponds to approx. 2e6 copies / batch).

Approach 2 contains the template M2SF5-M001-200 (Perfect Match Situation) in a concentration of 300 amol / l (corresponds to approx. 2x10 ^L 3 copies / batch).

Approach 3 does not contain a template and thus forms a control. Approach 4 contains as the template M2SF5-WT01-200 (single mismatch situation) in 300 pmol / l concentration (about 2x 10 ^L 9 copies per batch).

Primer 1 was used at 5 pmol / L, the controller oligonucleotide at 2 pmol / L and primer 2 at 1 pmol / L. The other reaction conditions were: Amplification solution 2.

To readjust the presence of genomic DNA in the assay, 100 ng of freshly denatured fish DNA (salmon DNA) was added per reaction.

A primer extension reaction (synthesis phase and controlling phase).

The thermal reaction conditions were 2 min at 55 ° C (synthesis phase) and then 5 min at 65 ° C (controlling phase).

The synthesis phase of the primer extension reaction of the first primer took place primarily at 55 ° C. At this temperature, the controller was in complex with the first primer and was thus in a non-active state. The controlling phase took place at 65 ° C. At this temperature, the controller at least partially dissociated from the first primer oligonucleotide and thus could interact with formed primer extension products. The melting temperature of the first region of the first primer with its primer binding site on the template was about 45 ° C in amplification solution 2. Thus, the synthesis phase was carried out at a reaction temperature of about Tm + 10 ° C, based on Tm of template / first primer complex. Due to a higher concentration of the first primer (5 pmol), a sufficient amount of the first primer was free in the synthesis phase to bind to the template and initiate the reaction. As the temperature was raised to 65 ° C, the yield of the synthesis phase decreased significantly. At this temperature, the controller was partially released from its binding with the primer (Tm of the complex comprising the first primer and controller in Amplification Solution 1 was 63 ° C). Therefore, the controlling phase was at approx.

Tm + 2 ° C. relative to Tm of controller / first primer complex.

Amplification reaction (repeat of primer extension reactions)

The thermal reaction conditions were cyclic alternating temperature changes, each followed by a 5 minute time interval at 65 ° C for a 2 minute time interval at 55 ° C. The amplification was followed for 100 cycles. Detection was carried out at 65 ° C for Eva Green fluorescence signal.

The successful synthesis of primer extension products (referred to herein as amplification) could be detected by an increase in the EvaGreen fluorescence signal over time. The temperature changes and real-time monitoring were performed with the StepPne Plus Real-Time PCR device from Thermofisher.

Fig. 31 shows a typical course of the EvaGreen signal. On the Y-axis is the increase of the fluorescence signal (Delta Rn) and on the X-axis is the reaction time (as cycle number) applied. Arrows mark individual reaction approaches. The selected positions belong to the following approaches:

Arrow 1: 300 fmol / l perfect match matrix (about 2x10 ^L 6 copies / batch)

Arrow 2: 300 amol / l perfect match die (about 2x10 ^L 3 copies / batch)

Arrow 3: no die

Arrow 4: 300 pmol / l mismatch template (about 2x 10 ^L 9 copies per batch).

The increase of the fluorescence signal can be seen both in the perfect match and in the mismatch variant of the template, the signal of the mismatch variant (4) appearing later despite a 1000-fold excess. With the single mismatch, a delay of about 15 cycles is observed. The time delay (= number of cycles) is a direct measure of discrimination by the controller. Using a Perfect-Match template results in the synthesis of a complementary strand of a primer extension product. This extension product is complementary to both the Perfect Match template and the controller oligonucleotide used. In contrast, using a mismatch sequence, the synthesis of the first primer extension product results in the generation of a complementary strand of the extension product which, while having complete complementarity to the mismatch template, but thereby complements with the third region of the controller -Oligonucleotide differs. This deviation occurs in the 5 ^' -store segment of the extension product, which should react with the controller oligonucleotide to allow the strand displacement process to proceed. As shown in the present example, the mismatch interferes with strand separation by the controller oligonucleotide.

This result illustrates the importance of the base composition in the controller oligonucleotide: deviations from the complementarity between the controller oligonucleotide and the primer extension product can lead to slowing or even interrupting the amplification.

In this example, it was shown that although the sequence ends of the perfect match template and the mismatch template were completely identical and thus the potential for binding of both primer oligonucleotides was the same, both reactions proceeded completely differently: with a complete complementarity between the Controller oligonucleotide and the 5 ^' segment of the extension product of the first primer oligonucleotide proceeded according to the amplification. An interruption of the strand separation during the controlling phase by a non-complementary sequence variant (in this case by a mismatch) led to the reduction of the strand separation, which was expressed in the suppression of the amplification kinetics.

Thus, a primer extension product made in a primer extension reaction can be used as the starting nucleic acid in an amplification procedure.

Example 2: Influence of a mismatch between a first primer and a controller on the strand separation (controlling phase).

Similar to the first example, an amplification reaction was used to illustrate an effect of a controlling phase (strand separation by a controller) after a synthesis phase.

The synthesis phase takes place under reaction conditions which allow a primer extension reaction on a template. However, different controllers were used for the respective strand separation (controller phase): perfect match and mismatch controller oligonucleotide to the primer used during the synthesis phase. To demonstrate the effect of such a single mismatch between a first primer and a controller, repeated primer extension reactions (synthesis phases) and controlling phases were performed under cyclic temperature conditions. Thus, an amplification of a first primer extension product resulted.

The amplification served as a detection method for the controlling phase: only if the strand separation can proceed successfully and the second primer oligonucleotide can bind to the 3 ^' segment of the first primer extension product, an amplification takes place. Due to the high sensitivity of this method (because of its exponential character) and its ability to quantify (time-dependent signal detection depending on concentration), amplification was used as a detection method for successful or unsuccessful strand separation during a controlling phase , The real-time monitoring of the synthesis of resulting amplification products was carried out in this example with the intercalating dye Eva Green.

The following template was used:

Template-sequence template leading to a first primer extension product with a perfect match match to the controller oligonucleotide:

M2SF5-M001 -200

5 ^' GCT CATA CT ACAATGTCA CT TA CTGTAA GAGCAGATCC CTGGACAGGC AA

GGAATACAGGTA AAAAA 3 ^' (SEQ ID NO: 001)

The binding sequence for the first primer oligonucleotide is underlined.

The second primer oligonucleotide binds to the reverse complement of the double underlined sequence.

The following primers were used:

The first primer oligonucleotide (SEQ ID NO: 2) served as a primer extension primer and as an amplification primer.

P1 F5-200-AE2053 5 ^' AACT CAG ACAAG ATGTG ATTTTTT ACCTGT AT [CUCU GAUGCUUC] 1 TACCTGTATTCC 3 ^' (SEQ ID NO: 003)

The segment used as the primer in the reaction is underlined.

This oligonucleotide comprises the following modifications:

1 = C3 linker served to terminate the synthesis of the second primer extension product.

Segment of the primer [CUCU GAUGCUUC] included 2 ^'-0-Me modifications and served as the second primer region capable of binding the first portion of the controller oligonucleotide:

A = (2 ^{'-0-methyl-adenosine),} G = ^(2' -0-methyl-guanosine); C = (2 ^{'-0-methyl-cytosine);} U = (2 ^{'-0-methyl-uridine)}

The second primer oligonucleotide served as a second amplification primer:

P2G3-5270-7063

5 ^' CT AC AG AACT CAG ACAAG AT GT AACT AC AATGTT 6

G CT CAT ACT AC AATGTC ACTT ACTGTAAG AG C AG A 3 ^' (SEQ ID NO: 005)

modifications:

6 = HEG linker

Both the first primer and the second primer are capable of supporting amplification with a perfect-match controller oligonucleotide.

The following perfect match controller oligonucleotide was used:

AD F5-1001-503

5 ^' [UAAUCUGUAA GAGCAGAUCC CUGGACAGGC AA GG AA U AC] AG GT AG AAG CAT C AGAG X 3 ^' (SEQ ID NO: 004)

X = 3 ^' phosphate group to block a possible extension by the polymerase. The following mismatch controller oligonucleotide was used:

MD2AD-F5-01 1-5 5 ^' - GCTC TAATCTGTAA GAGCAGATCC CTG [GAC AGGC AA AGAAUACAGG] TA GAAGCATC AGAG X 3 ^' (SEQ ID NO: 007)

The set in square brackets middle segment of the oligonucleotide [AGGC GAC AA AGAAUACAGG] included 2 ^{'-0-Me-nucleotide} modifications: A = ^(2' -0-methyl-adenosine), G = (2 ^'-0-methyl Guanosine); C = (2 ^{'-0-methyl-cytosine);} U = (2 ^{'-0-methyl-uridine)}

X = 3 ^' phosphate group to block a possible extension by the polymerase.

The nucleotides and nucleotide modifications are linked together with phosphodiester bonds. The 3 ^' end is blocked with a phosphate group to prevent possible extension by the polymerase.

In the mismatch controller oligonucleotide, an A nucleotide (mismatch variant) was used in position -24 (from the 3 ^' end) instead of a G nucleotide (perfectly match variant). The nucleotide is highlighted in bold. This position forms a mismatch with the 3 ^'- terminal nucleotide of the first primer set.

The template was used in concentrations of 1-3 pmol / l. No template was used in the control reaction (= negative control). Primer 1 was 5 pmol / L, the respective

Controller oligonucleotide used at 2 pmol / l and primer 2 at 1 pmol / l.

The further reaction conditions were:

• Amplification Solution 2

• To replicate the presence of genomic DNA in the assay, 100 ng of freshly denatured fish DNA (salmon DNA) was added per reaction.

The synthesis phase of the primer extension reaction of the first primer took place primarily at 55 ° C. At this temperature, the controller was in complex with the first primer and thus in a non-active state. The controlling phase took place at 65 ° C. At this temperature, the controller at least partially dissociated from the first primer oligonucleotide and thus could interact with formed primer extension products. The melting temperature of the first region of the first primer with its primer binding site on the template was about 45 ° C in amplification solution 2. Thus, the synthesis phase was carried out at a reaction temperature of about Tm + 10 ° C, based on Tm of template / first primer complex. Due to a higher concentration of the first primer (5 pmol), a sufficient amount of the first primer was free in the synthesis phase to bind to the template and initiate the reaction. As the temperature was raised to 65 ° C, the yield of the synthesis phase decreased significantly. At this temperature, the controller was partially released from its binding with the primer (Tm of the complex comprising first primer and controller in amplification solution 1 was 63 ° C). Therefore, the controlling phase was around Tm + 2 ° C. relative to T m of controller / first primer complex.

In the amplification, the thermal reaction conditions were cyclically alternating

Temperature changes, each followed by a 5 minute time interval at 65 ° C for a 1 minute time interval at 55 ° C. The amplification was typically over 120 cycles, i. Followed 120 x (1 min 55 ° C + 5 min 65 ° C) = 120 x 6 min = 12 h. The successful amplification could be detected by an increase in the EvaGreen fluorescence signal over time.

Analysis of primer extension reaction (and amplification reaction)

To analyze the amplification reaction and to evaluate the resulting

Amplification products were used the following techniques:

Fluorescence signal of an intercalating dye (EvaGreen)

Melting curve analysis of the resulting amplification products

Figure 32A shows a typical course of the EvaGreen fluorescence signal in the course of an allele-specific amplification reaction using a perfect match controller oligonucleotide. On the Y-axis is the fluorescence signal of the EvaGreen dye and on the X-axis the reaction time (as cycle number) is plotted. Arrow 1 marks in Fig. 32A a perfect match amplification approach. Due to the perfect match controller oligonucleotide, the template can be amplified and an increase in the fluorescence signal occurs from cycle 27 onwards. Arrow 2 marks a negative control approach that does not contain a template and thus does not generate an amplification signal during the course of the experiment.

Figure 32B shows a typical course of the EvaGreen fluorescence signal in the course of an allele-specific amplification reaction using a mismatch controller oligonucleotide. On the Y-axis is the fluorescence signal of the EvaGreen dye and on the X-axis the reaction time (as cycle number) is plotted. Arrow 1 marks a mismatch amplification approach. Due to the mismatch controller oligonucleotide, the template can not be amplified. Arrow 2 marks a negative control approach that does not contain a template and thus does not generate an amplification signal during the course of the experiment. The fluorescence signal from the mismatch controller oligonucleotide approach and negative control are nearly congruent, indicating how much the amplification in the mismatch situation is suppressed.

Figure 32C shows the melting curves of the allele-specific amplification products of Figures 32A and 32B. The Y-axis plots the derivative of the fluorescence signal versus temperature, and the temperature is plotted on the X-axis. Two characteristic peaks were found, marked with arrows 1 and 2. The peak at position 1 with a melting point near 65 ° C belongs to the mismatch controller oligonucleotide approach. The signal curve can not be distinguished from negative control approaches (= amplification reaction without template). the opposite is the peak at position 2 with a melting point near about 85 ° C. This peak belongs to the perfect match controller oligonucleotide approach and is specific for the amplification product formed. The results suggest that in the perfect-match situation, specific amplification products with a defined melting point close to about 85 ° C are formed. In contrast, in mismatch controller oligonucleotides, the

Amplification reaction suppressed. The fluorescence signals of the mismatch controller oligonucleotide batches were not in this example from the negative control

differ. This shows how strong the amplification suppression is in the mismatch situation.

In summary, it is stated: a nucleotide mismatch positioned in the controller oligonucleotide in the second region of the controller oligonucleotide to the corresponding first region of the primer can prevent amplification.

Starting from this example, it can be seen that sequence variant-specific

Amplification systems comprising a sequence variant-specific primer and a corresponding complementary sequence variant-specific controller oligonucleotide can be assembled.

Example 3

Primer extension reaction using a template and block oligonucleotides with LNA modifications to limit a primer extension reaction.

In this example, the use of human genomic DNA (hgDNA) as the source of a target sequence is shown wherein the primer extension reaction is performed using a first primer oligonucleotide and a controller oligonucleotide. To limit the progress of the synthesis, block oligonucleotides were used which bound complementarily to the template strand in the 3 ^' direction from the primer prior to the initiation of a primer extension reaction by hybridization. The synthesis was carried out at 55 ° C for 15 min. During this synthesis phase, the first primer region binds to the primer binding site in the template and is extended by the polymerase, thereby resulting in a primer extension product. The controller was added prior to the start of the primer extension reaction and was present in the double-stranded complex with the primer during this synthesis phase in a non-active form.

Upon completion of the synthesis phase, the reaction temperature was increased to 65 ° C for 5 minutes so that the complex comprising the controller and primer could dissociate at that temperature and the controller could now interact with the primer extension product formed during the synthesis phase and separate it from the matrix strand.

The target sequence was a sequence segment of the Factor V Leiden gene (Homo sapiens coagulation factor V (F5), mRNA, referred to herein as the FVL gene). Target sequence:

5 ^' TGACGTGGAC ATCATGAGAG ACATCGCCTC TGGGCTAATA GGACTACTTC

TAATCTGTAA

GAGCAGATCC CTGGACAGGC AAGGAATACA GGTATTTTGT CCTTGAAGTA ACCTTTCAGA

3 ^' (SEQ ID NO: 008)

The binding sequence for the first primer oligonucleotide is underlined (primer binding site). The binding site for the block oligonucleotide is double-underlined.

The block oligonucleotide:

Pl-EXB-1000-101

5 ^' {CCA GAGGCGATG} T ATCTCATGAT GTCCACAACA CTGTAGTATG GTCTTGTTAA GCAAAAA 3 ^' X (SEQ ID NO: 009)

The curly-braced sequence segment {CCA GAGGCGATG} contains LNA modifications.

The first primer and controller oligonucleotide were designed and synthesized for FVL mutation variant of the gene.

The first primer oligonucleotide:

P1 F5-200-AE2053

The segment used as the primer in the reaction is underlined.

This oligonucleotide comprises the following modifications:

The segment of the primer [CUCU GAUGCUUC] included 2 ^'-0-Me modifications and served as the second primer region capable of binding the first portion of the controller oligonucleotide: This sequence can not take the die in the region next to the primer binding site bind complementary and is thus available for interaction with the controller oligonucleotide.

The first primer comprises in its first region a sequence which can specifically bind to the sequence of the Factor V Leiden gene within the genomic DNA such that synthesis by a polymerase can be started. The second region of the first primer comprises a sequence which does not specifically hybridize to the sequence of the FVL gene. Furthermore, the first primer comprises a further sequence segment which connects to the 5 ^' end of the second region. This segment does not participate in the specific primer extension of the factor 5 Leiden segment. The function of this segment is mainly seen in the delay of side reactions.

The following controller oligonucleotide was used:

AD F5-1001-503

5 ^' rUAUCUGUAA GAGCAGAUCC CUGGACAGGC AA GGAAUAC1AGGTAGAAGCATC

AGAG X 3 ^' (SEQ ID NO: 004)

X = 3 ^' phosphate group to block a possible extension by the polymerase.

The nucleotides and nucleotide modifications are linked together with phosphodiester bonds. The 3 ^' end of the controller oligonucleotide is blocked with a phosphate group to prevent possible extension by the polymerase. This controller can bind with its segment (positions underlined above) to the first expected primer extension product complementarily:

fUAAUCUGUAA GAGCAGAUCC CUGGACAGGC AA GGAAUAC1 AGGTA fSEO ID NO: 0101

The controller oligonucleotide was designed so that a perfect match situation results in the sequence of the Factor V Leiden mutation of the FVL gene. The controller oligonucleotide comprises first, second and third regions.

All reactions were performed in Amplification Solution 2.

The dNTPs used included: dATP, dGTP, dCTP, dUTP (instead of dTTP).

The polymerase used was Bst 2.0 Warm-Start Polymerase from NEB.

The primer extension reaction was set up as follows:

Approximately 50,000 haploid genomic equivalents (HGE), 150 ng of hgDNA in 40 pl, FVL-WHO standard, double-stranded, were placed in reaction solution 2 in contact with a block oligonucleotide (0.3 pmol / l) and heated by heating denatured (5 min at 95 ° C) and then cooled to room temperature. Subsequently, in the reaction, the first primer (2 mitioI / I) was added together with the controller oligonucleotide (1 pmol / L), followed by Bst-2.0 Warm Start Polymerase (about 1 unit), and dNTPs (about 250 ml / l). I) was added and the reaction volume brought to 50 ml. The resulting reaction mixture was incubated under stringent primer extension conditions (Amplification Solution 2, temperature of about 55 ° C) for about 15 min. During this phase, the first primer is extended, with the genomic DNA as template. This resulted in a primer extension product. Since during this phase the controller oligonucleotide is complexed by the first primer (and thus in an inactive state), the primer extension product formed was in the double-stranded complex with the template. In order to remove this product from the template sequence-specific, the reaction mixture was heated to 65 ° C and incubated for about 5 min. During this phase, the primer extension product from binding to the template was at least partially displaced by the controller. The 3 ^' segment of the primer extension product spontaneously dissociated under selected reaction conditions. Such a primer extension product can be used, for example, in a subsequent amplification reaction in analogy to Example 1.

Such an arrangement of block oligonucleotides on a template and thus limiting the length of a primer extension product can be used, for example, in providing a nucleic acid fragment to be used as a starting nucleic acid in a specific exponential amplification. Although such a start nucleic acid as a primer extension reaction also without a block oligonucleotide take place (Fig. 33 A and B). However, the undefined length of a primer extension fragment that may result from copying the template strand may be a sequence unspecific, e.g. require a temperature-related strand separation (Fig. 33 C). The binding of a second amplification primer takes place in the middle region of such a primer extension product (FIGS. 33 C and D).

In contrast, the use of a block oligonucleotide allows an almost arbitrary specific limitation on the length of a primer extension product, regardless of the length of a template strand (Figures 34A and B). Furthermore, the block oligonucleotide favors sequence-dependent separation of formed primer extension products even prior to initiation of amplification. In this case, for example, first a synthesis phase of a primer extension and then a controlling phase (sequential arrangement of steps). In another embodiment, the synthesis phase and the controlling phase may proceed with the separation of the primer extension product in one step and take place in parallel with each other).

As a result, a specific primer extension product is generated and separated sequence-specifically from the template with the assistance of a controller, without having to resort to a nonspecific denaturation step (Figures 34 B and C). Such a primer Extension product can be used as starting nucleic acid for further amplification (Figures 34D and E). This can increase the specificity of creating a starting nucleic acid.

The block oligonucleotide preferably does not itself serve as a primer. This can be done for example by blocking its 3 ^'OH group. The block oligonucleotide thus comprises at least one sequence segment which is complementary to the template strand on which the primer extension reaction also takes place. This segment (blocking segment) is preferably sufficiently long, or may include modifications, to form a stable duplex upon reaction conditions of a primer extension reaction with the template strand. Furthermore, such a block oligonucleotide may also comprise sequence segments that are not complementary to the template strand. For example, such sequence segments may flank the segment which is to bind to the template and block the primer extension reaction on both sides. For example, the block oligonucleotide may be located in a sequence segment of a target nucleic acid or placed at one of its ends. The block oligonucleotide is thus located such that it is located in the 3 ^' direction of the expected primer extension product on the template and prevents the polymerase from further copying the template strand.

The goal of a primer extension reaction may be the production of a starting nucleic acid chain for a subsequent amplification reaction. Such a starting nucleic acid chain is used at the beginning of an amplification reaction. Their function can be seen as representing the initial template which allows for correct positioning of primers, the synthesis portions between both primers, and the initiation of binding and extension events. In certain embodiments, a start-up nucleic acid chain comprises a target sequence.

By binding primers to their corresponding primer binding sites (PBS 1 and PBS 2) and initiating appropriate primer extension reactions, generation of first primer extension products occurs. These are synthesized as specific copies of the nucleic acid chain present at the beginning of the reaction.

In certain embodiments, the nucleic acid sequence (starting nucleic acid chain) to be inserted into the reaction mixture prior to the start of the amplification reaction may be identical to the nucleic acid sequence to be amplified. The amplification reaction only increases the amount of such a nucleic acid chain.

In certain embodiments, the nucleic acid to be amplified and the starting nucleic acid chain differ in that the starting nucleic acid chain prescribes the arrangement of individual sequence elements of the nucleic acid chain to be amplified, but the sequence composition of the starting nucleic acid chain can deviate from the sequence of the nucleic acid chain to be amplified. For example, in the context of primer binding and Extension during amplification new sequence contents (based on the starting nucleic acid chain) are integrated into the nucleic acid chain to be amplified. Furthermore, sequence elements of a nucleic acid chain to be amplified may differ from such sequence elements of a starting nucleic acid chain in their sequence composition (eg primer binding sites or primer sequences). The starting nucleic acid serves only as an initial template for the specific synthesis of the nucleic acid chain to be amplified. This initial template may remain in the reaction mixture until the end of the amplification. Due to the exponential nature of the amplification, however, the amount of nucleic acid chain to be amplified at the end of an amplification reaction is greater than the amount of starting nucleic acid chain added to the reaction.

The starting nucleic acid sequence, in certain embodiments, comprises a target sequence or its partial segments which comprise at least one expected sequence variant of a polymorphic locus of the target sequence.

A start nucleic acid further comprises at least one predominantly single-stranded sequence segment, to which at least one of the primers of the amplification system can bind predominantly complementary to its 3 ^' segment, so that the polymerase used such a primer, when hybridized to the starting nucleic acid chain, may extend template-specific incorporation of dNTPs.

A start-up nucleic acid, which may comprise multiple sequence variants in a polymorphic locus of a target sequence, preferably further comprises at least a first target sequence segment that is characteristic and unitary for all target sequence variants. In certain embodiments, a starting nucleic acid comprises at least two target sequence segments (a first target sequence segment and a second target sequence segment) located on either side of a polymorphic locus of a target sequence, thus flanking the sequence variants of a target sequence from both sides.

The length of a polymorphic locus of a starting nucleic acid nucleus may comprise regions of one nucleotide up to 200 nucleotides, in particular from one nucleotide up to 50 nucleotides, in particular from one nucleotide up to 20 nucleotides. The lengths of uniform sequence segments (first and second unitary sequence segment of a starting nucleic acid) can comprise the following regions for at least one of the two unitary sequence segments: from 4 to 200 nucleotides, in particular from 6 to 100 nucleotides, in particular from 8 to 50 nucleotides.

In certain embodiments, the startup nucleic acid chain may comprise at least one sequence segment which is not amplified. Such a start nucleic acid chain is thus not identical to the sequence to be amplified. Such portions not to be amplified may be, for example, as a consequence of sequence preparation steps or as a consequence of preceding sequence manipulation steps represent a sequence segment of a starting nucleic acid chain.

In a preferred embodiment, the starting nucleic acid sequence to be inserted into the reaction mixture prior to initiation of the reaction includes at least one target sequence.

In certain embodiments, such a starting nucleic acid chain includes at least one target sequence and still other non-target sequence sequences. During amplification, sequence segments comprising the target sequence are multiplied exponentially and other sequence segments are either not or only partially exponentially propagated.

Construction of a starting nucleic acid ketone

An example of such a start nucleic acid chain is a nucleic acid sequence which includes a target sequence or its equivalents (for example, a sequence complementary to the target sequence) and which comprises a sequence fragment A and comprises a sequence fragment-B.

Sequence fragment-A of the starting nucleic acid chain comprises a sequence which has significant homology with the sequence of one of the two primers used in the amplification or is substantially identical to the copiable portion of the 3 ^' segment of the one primer. Upon synthesis of a complementary strand to this segment, a complementary sequence is generated which represents a corresponding primer binding site.

The sequence fragment B of the starting nucleic acid chain comprises a sequence which is suitable for complementarily binding a corresponding further primer or its 3 ^' segment to form an extension-capable primer-template complex, wherein sequence fragment A and sequence fragment B are relative to each other predominantly / preferably are not complementary.

In a preferred embodiment, the reaction mixture of an amplification process is given a starting nucleic acid chain comprising a target sequence which has the following properties:

Sequence segment-5 (called segment 5, S5 in Figure 34) which comprises a sequence having significant homology with the sequence of the first region of the first primer or substantially identical to the copiable portion of the first region of the first primer , This segment-5 is located in the 5 ^' segment of the starting nucleic acid chain and is flanked by a non-duplicable oligonucleotide tail (analogous to the first primer oligonucleotide), preferably this segment forms a boundary of the copiable nucleic acid chain strand in 5 ^' . Direction.

Sequence fragment-7 (called segment 7, S7) which comprises a sequence which is capable of complementary binding of a second primer or its 3 ^' segment to Training an extension-capable primer-template complex is suitable. Preferably, the segment 7 lies in the 3 'direction of segment 5 of the starting nucleic acid chain (FIG. 34).

The target sequence, which lies partially or completely between segment 5 and segment 7 (in FIG.

34 this portion of the target sequence is referred to as segment 6, S6). In a preferred embodiment, the target sequence comprises segment 6 and at least one of segment 5 and / or segment 7.

The start nucleic acid chain may comprise flanking sequence segments in the 3 ^' segment (designated as segment 8 in Fig. 33) which are not amplified.

In a further embodiment, the reaction mixture of an amplification method is given a starting nucleic acid chain comprising a sequence complementary to the target sequence (equivalent of a target sequence), which has the following properties:

Sequence segment-5 (called segment 5, S5 in Figure 34) which comprises a sequence having significant homology with the sequence of the first region of the first primer or substantially identical to the copiable portion of the first region of the first primer , This segment-5 is located in the 5 ^' segment of the starting nucleic acid chain and is flanked by a non-copyable oligonucleotide tail (analogous to the first primer oligonucleotide), preferably this segment forms a boundary of the copiable nucleic acid chain strand in 5 ^' . Direction.

The sequence fragment-7 (called segment 7, S7), which comprises a sequence which is suitable for the complementary binding of a second primer or its 3 ^' segment to form an extension-capable primer-template complex. Preferably, the segment 7 lies in the 3 'direction of segment 5 of the starting nucleic acid chain (FIG. 34).

The sequence complementary to the target sequence, which lies partially or completely between segment 5 and segment 7 (in FIG. 34 this portion of the sequence is referred to as segment 6, S6). In a preferred embodiment, the sequence comprises segment 6 and at least one of segment 5 and / or segment 7.

Functioning of the starting nucleic acid chain

At the beginning of the amplification reaction, the starting nucleic acid chain serves as a template for the initial generation of respective primer extension products. It thus represents the starting template for the nucleic acid chain to be amplified. The starting nucleic acid chain does not necessarily have to be identical to the nucleic acid chain to be amplified. By binding and extending both primers during the amplification reaction, essentially the two primers determine which sequences are generated at both terminal segments of the nucleic acid chain to be amplified as part of the amplification. In a preferred embodiment of the process, non-denaturing reaction conditions are maintained for a double strand during the exponential amplification process. Therefore, it is advantageous if the starting nucleic acid chain has a restriction in its polymerase-extendable 5 ^' sequence segment, resulting in a stop in the enzymatic extension of a corresponding primer. This limits the length of the primer extension fragments generated under reaction conditions. This can have an advantageous effect on the strand displacement by the controller oligonucleotide and lead to a dissociation of the respective strand, so that primer binding sites are converted into a single-stranded state and thus become available for a recapture of primers.

Example 4 Influence of a Controller Oligonucleotide on the Primer Extension Reaction in a Parallel Synthesis Phase and Controlling Phase:

The reactions were carried out in Amplification Solution 2.

The following matrices were used (DNA matrices):

P1 Ex-400-4001

C TTACAG TAAGTGACATTGTAG TATG AGC GATCC CTGGACAGGC AA GGAATACAGGTA

A 3 ^' (SEQ ID NO: 01 1)

P1 EX-400-4002

C TTACAG TAAGTGACATTGTAG TATG AGC GATCC CTGGACAGGC AA GAATACAGGTA A

(SEQ ID NO: 012)

P1 EX-400-4003

C TTACAG TAAGTGACATTGTAG TATG AGC GATCC CTGGACAGGC AA AATACAGGTA A

(SEQ ID NO: 013)

P1 EX-400-4004

C TTACAG TAAGTGACATTGTAG TATG AGC GATCC CTGGACAGGC AA GGAATAAAGGTA

A (SEQ ID NO: 014)

P1 EX-400-4005

C TTACAG TAAGTGACATTGTAG TATG AGC GATCC CTGGACAGGC AA AGAATACAGGTA

A (SEQ ID NO: 015)

DNA templates with iso-dC

P1 EX-400-4201 (is identical to SEQ ID NO 1 1 but has an iso-dC instead of the bold G at position 47 in the sequence shown below :) C TTACAG TAAGTGACATTGTAG TATG AGC GATCC CTGGACAGGC AA GGAATACAGGTA A 3 ^' (SEQ ID NO: 01 1)

CTTACAGTAA GTGACATTGT AGTATGAGCG ATCCCTGGAC AGGCAA 1 GAATACAGGTA A (SEQ ID NO: 016)

P1 EX-400-4202 (is identical to SEQ ID NO 1 but has i an iso-dC instead of G at position 43 :)

C TTACAG TAAGTGACATTGTAG TATG AGC GATCC CTGGACAG1 C AA GGAATACAGGTA A (SEQ ID NO: 017)

1 = 5-Me-iso-dC (nucleotide can form only with iso-dG a complementary nucleobase. There is no "typical Watson-Crick" base pairing with one of the dNTP used ^'s, so that overcoming this position only by mismatch Education can take place).

The templates were varied in their sequence composition so that resulting primer extension products can interact differently with the controller oligonucleotide. Depending on the sequence composition of the template, either a perfect-match agreement or a mismatch in the complex of primer extension product / controller could be generated.

To test for a polymerase error, templates were used which include an iso-dC at certain positions. Since this nucleotide does not comprise a natural correlate, a polymerase must generate a mismatch and only when this mismatch is overcome can the displacement of the probe (see above) take place. Thus, matrices with Iso-dC represent an example of the primer extension reactions that result from mismatch formation (e.g., due to a polymrease defect). Iso-dC matrices are intended to illustrate only the changes in the behavior of the primer extension reactions and the influence of the controller on the behavior of the polymerases / synthesis of complementary strands.

The following primers were used:

SEQP1 F5 300-35X

5 'AC GAAG CTCGCAAGAAC TCAG AG TGTG CTCGAC AC TACCTGTATTCC 3 ^' (SEQ ID NO: 018)

The first primer area is underlined. With this segment, the primer can bind to perfect-match templates.

This primer does not include a segment that can interact with the first region of the controller oligonucleotide. Thus, upon extension of this primer, a controller oligonucleotide can not separate the formed primer extension product from the template strand. P1 F5-001 -1003

5 ^' TMR - [CU GAUGCUUC] 1 TACCTGTATTCC 3' (SEQ ID NO: 019)

1 = C3-LINKER

The first primer area is underlined. With this segment, the primer can bind to perfect match templates.

The square segment [CU GAUGCUUC] contains 2 ^' -0-Me modifications and represents the second region of the primer.

TMR = tetramethyl-rhodamine at the 5 ^' end

The following controller oligonucleotide was used:

AD F5-1001-503

5 ^' [UAAUCUGUAA GAGCAGAUCC CUGGACAGGC AA GG AA U AC] AG GT AG AAG CAT C AGAG X 3 ^' (SEQ ID NO: 020)

The 5 ^'segment of the oligonucleotide [UAAUCUGUAA GAGCAGAUCC CUGGACAGGC AA GGAAUAC] included ^2' -0-Me-nucleotide modifications:

X = 3 ^' phosphate group to block a possible extension by the polymerase.

The controller oligonucleotide can be a perfect match in this example with certain primer extension products. It can mismatch with other primer extension products.

To monitor the progress of the primer extension reaction, a fluorescent probe was used which can bind to the 5 ^' segment of the templates used. Displacement of this probe from binding with this 5 ^' segment of the respective template reduces the signal from the probe (intramolecular quenching between dT-BHQ1 and FAM reporter)

Fluorescent probe:

P2D-LUX-1000-101

FAM-5 ^' TAGTATGAGC TTTT 1G CT CAT AC2 AC AATGTCACTT A CTGTAA GAGCAGA (SEQ ID NO: 021) 1 = HEG

2 = dT-BHQ1

The probe was used in 0.2 pmol / L concentration. Matrices were used at a concentration of 0.5 μg / L, primers were used at 1 μg / L concentration, and controllers (when used as indicated) were used at 2 μg / L. Bst-2.0 warm-start (NEB) was used in a concentration of 4 units / 10 mI.

The reactions were carried out in a StepOne Plus instrument at a temperature of 55 ° C. The signal detection took place via FAM channel. The reaction was monitored continuously (sampling interval = 10 sec). As a control of the signal intensity served on the one hand reaction approaches without polymerase (but with all other components) or alternatively with polymerase but without template.

The Tm of PBS (perfect match) of the template with the first region of the primer was approximately

45 ° C. The Tm of controller oligonucleotide / primer (P1 F5-001-1003) was about 57 ° C. The reaction temperature of the primer extension reaction was 55 ° C. The reaction proceeded for 100 min.

The results of individual reactions are summarized in FIG.

The kinetics of individual reactions were evaluated on the basis of the change in the fluorescence signal.

The following shows the evaluation of representative data records:

Reaction 1 (Figure 36A): With perfect-match binding of a primer in the absence of a controller, rapid primer extension and probe displacement occurred, so that more than 70% of the probes were already separated from the 5 ^' at the first signal acquisition. Segment of the matrices were detached and the signal was greatly reduced already at the beginning of the measurement.

Reaction 2 (Figure 36A): With perfect match binding of a primer in the presence of a controller, there was also fast primer extension and probe displacement, which, however, is slower compared to reaction 1 without controller.

Reaction 3 (Figure 36A): served as a probe reference signal in the absence of a polymerase.

Reactions 4-6 (Figure 36B) show reactions with a primer which does not interfere with the

Controller in the first area can interact (this primer has no second area, which can bind complementary to the first area of the controller). The presence of the controller seems to have no detectable influence on the course of this reaction. At selected reaction conditions, the controller hardly disturbs the course of this reaction.

Introduction of a mismatch in primer binding site in the template

Reactions 7 and 8 show that the absence of a complementary nucleotide in the template (3 ^' -terminal mismatch) results in complete prevention of the primer extension reaction (Figure 37A). Analogous reaction behavior was observed for matrices P1 EX-400-4003, P1 EX-400-4004, P1 EX-400-4005, P1 EX-400-4201 (absence of 2 terminal

Nucleotides, a mismatch in the middle of PBS, a substitution of G for A (mismatch), a substitution of G for iso-dC). In none of the reactions was the probe displaced. This shows that the presence of a controller oligonucleotide does not adversely affect the

Discrimination.

Reaction 10 (Figure 37B): Demonstrates the overcoming of an iso-dC position in the template in the absence of a controller and the continuation of synthesis until displacement of the probe using a first primer oligonucleotide (P1 F5-001-1003). Although delayed reaction kinetics can be seen (displacement of the probe is much slower than with the perfect match template), a complementary primer extension product can still be synthesized in good yields (probe displaced).

Reaction 1 1 (Figure 37 B): Shows the influence of the controller present in the reaction: The overcoming of the mismatch position succeeds much more slowly. This is related to the fact that the primer extension product formed during the reaction can be released during the reaction and forms a complex with the controller that has a higher Tm than the primer / controller complex. The prematurely detached, incomplete primer extension product preferably remains in complex with the controller and is thus removed from the reaction ("trapping" of incomplete primer extension products). This prevents the polymerase from being able to overcome the iso-dC nucleotide. The presence of the controller thus exerts a "corrective effect" on the polymerase: while a polymerase is basically capable of overcoming such a mismatch, in combination with the controller, this property of the primer extension system is altered to such an extent a complete synthesis of defective primer extension products is suppressed. The intermediate primer extension products are removed from further extension which proceeds during a primer extension reaction (on-line control).

Reaction 12: served as the reference signal for the probe in the absence of a polymerase.

Reaction 13 (Figure 38A): Shows the overcoming of an iso-dC position in the template in the absence of a controller and the continuation of synthesis until displacement of the probe using a primer oligonucleotide which does not comprise a second region (SEQP1F 300-35X). Although delayed reaction kinetics are observed (displacement of the probe is much slower than with the perfect-match template), a complementary primer extension product can still be synthesized in good yields (probe displaced).

Reaction 14: However, the presence of a controller oligonucleotide does not appear to affect the behavior of the primer extension system in such a primer design: the primer used has no second region, unlike the primer used in reaction 11.

Overall, this example demonstrates the ability of a primer extension system to modify / prevent the overcoming of a mismatch by the polymerase in the presence of a controller oligonucleotide and a first primer.

Example 5

Application of a synthesized nucleic acid chain as a starting nucleic acid chain in one

Amplification.

The nucleic acid chain obtained by a primer extension reaction can be derived from

Matrizenstrang be replaced and used in another method.

The execution of this amplification method was described in the PCT application

PCT / EP2017 / 07101 1 and the European application 16185624.0 already described. For details of the execution of the amplification, the skilled person is referred to this application.

For example, in a method of amplifying nucleic acid chains with a controller oligonucleotide (see Examples 1 and 2). Such an amplification method comprises several steps shown in FIGS. 40-42. These figures show schematically the interaction of components in an exponential amplification of a nucleic acid chain to be amplified in individual steps.

Thus, the nucleic acid chain provided by a primer extension can be used, for example, as a starting nucleic acid chain in an allele discrimination amplification as a template.

FIG. 43A schematically shows a start nucleic acid chain and components of the amplification system in the preparation prior to the amplification start:

Starting nucleic acid (start NS) comprising a target sequence.

Primer 1 (P1.1), primer 2 (P2.1), an activator oligonucleotide (C1.1).

Components for primer extension reaction: polymerase (Pol) and dNTPs Fig. 43B shows schematically the result of the amplification:

The primer extension product P1.1 -Ext from P1 .1 and the primer extension product 2.1-Ext. These products (P1 .1 -Ext, P2.1 -Ext) can form different complex forms with each other and with activator oligonucleotide (depending on the concentration ratio and reaction conditions). Specifically, these forms may comprise complexes of P1.1-Ext / C1.1 and / or P1-Ext and / or P1-Ext / C1.1 / P2.1-Ext.

The P1-Ext comprises a 3 ^' segment which is not complementarily bound by the activator oligonucleotide. This segment serves as a binding partner for the oligonucleotide probe.

Fig. 44 shows schematically potential positions of a polymorphic locus within a target sequence (positions 1 to 6) and their corresponding sequence segment positions in individual components of an amplification system. The polymorphic loci of a target sequence shown schematically comprise 2 to 50 nucleotides, in particular 4 to 30 nucleotides, which are characteristic and specific for an allelic variant of a target sequence.

Arrangement 1 (P1): polymorphic locus (N2) of the target sequence superimposed on the first primer (first region) and activator oligonucleotide (second region). These components of the amplification system can thus be constructed specifically and characteristically for the respective sequence variant of the target sequence. In this arrangement, a target sequence specific second primer is used, which is not sequence variant specific.

Array 2 (P2): polymorphic locus (N2) of the target sequence superimposed on the first primer (first region) and activator oligonucleotide (second region). These components of the amplification system can thus be constructed specifically and characteristically for the respective sequence variant of the target sequence. In this arrangement, a target sequence specific second primer is used, which is not sequence variant specific. Arrangement P2 differs from P1 mainly in that N2 lies predominantly in the 3 ^' terminal sequence segment of the first primer. This may possibly result in a better specificity of the amplification.

Arrangement 3 (P3): Polymorphic locus (N2) of the target sequence overlays only the activator oligonucleotide (third region), with the corresponding sequence segment of the activator oligonucleotide in the 5 ^' segment of the synthesized portion of the first primer extension product. The activator oligonucleotide of the amplification system can thus be constructed specifically and characteristically for the respective sequence variant of the target sequence. In this arrangement, a target sequence-specific first and second primer is used, which are not specific for sequence variants. Due to the possible proximity of the second blocking moiety, the binding of the activator oligonucleotide to the first Primer extension product can be influenced by nucleotide modifications of the second blocking unit.

Arrangement 4 (P4): polymorphic locus (N2) of the target sequence overlays only the activator oligonucleotide (third region). The activator oligonucleotide of the amplification system can thus be constructed specifically and characteristically for the respective sequence variant of the target sequence. In this arrangement, a target sequence specific first and second primer is used, which are not sequence variant specific. This sequence segment of the activator oligonucleotide lies in the 5 ^' direction of the second blocking unit and may comprise several DNA nucleotide monomers, eg from 5 to 30.

Arrangement 5 (P5): polymorphic locus (N2) of the target sequence superimposed on the second primer and the activator oligonucleotide (third region). These components of the amplification system can thus be constructed specifically and characteristically for the respective sequence variant of the target sequence. In this arrangement, a target sequence specific first primer is used, which is not sequence variant specific.

Array 6 (P6): polymorphic locus (N2) of the target sequence overlays the second primer and the activator oligonucleotide (third region, near the 5 ^' end). These components of the amplification system can thus be constructed specifically and characteristically for the respective sequence variant of the target sequence. In this arrangement, a target sequence of specific first primer is used, which is not sequence variant specific.

The design differences of individual elements also result in differences for the primer extension products synthesized during amplification.

Fig. 45 shows schematically potential positions of a polymorphic locus with sequence variance of only one nucleotide within a target sequence (positions 1 to 6) and their corresponding sequence segment positions in individual components of an amplification system.

Arrangement 1 (P1): polymorphic locus (N2) of the target sequence superimposed on the first primer (first region) and the activator oligonucleotide (second region). These components of the amplification system can thus be constructed specifically and characteristically for the respective sequence variants of the target sequence. In this arrangement, a target sequence specific second primer is used, which is not sequence variant specific.

Arrangement 2 (P2): polymorphic locus (N2) of the target sequence superimposed on the first primer (first region) and the activator oligonucleotide (second region). These components of the amplification system can thus be specific and characteristic of the respective Sequence variants of the target sequence can be constructed. In this arrangement, a target sequence specific second primer is used, which is not sequence variant specific. Arrangement P2 differs from P1 primarily in that N2 may be predominantly in the 3 ^' terminal sequence segment of the first primer or even comprises the 3 ^' terminal nucleotide. As a result, a further increase in the specificity of the amplification can optionally be achieved.

Arrangement 3 (P3): polymorphic locus (N2) of the target sequence superimposes only the activator oligonucleotide (third region) with the corresponding sequence segment of the activator oligonucleotide in the 5 ^' segment of the synthesized portion of the first primer extension product. The activator oligonucleotide of the amplification system can thus be constructed specifically and characteristically for the respective sequence variant of the target sequence. In this arrangement, a target sequence specific first and second primer is used, which are not sequence variant specific. Because of the possible proximity of the second blocking moiety, binding of the activator oligonucleotide to the first primer extension product can be affected by nucleotide modifications of the second blocking moiety.

Arrangement 4 (P4): polymorphic locus (N2) of the target sequence overlays only the activator oligonucleotide (third region). The activator oligonucleotide of the amplification system can thus be constructed specifically and characteristically for the respective sequence variant of the target sequence. In this arrangement, a target sequence specific first and second primer is used, which are not sequence variant specific. This sequence segment of the activator oligonucleotide lies in the 5 ^' direction of the second blocking unit. This segment of the activator oligonucleotide may comprise multiple DNA nucleotide monomers, eg, from 5 to 30, wherein the N2-corresponding sequence segment may be flanked by at least 3 to 15 DNA nucleotide building blocks on both sides.

Arrangement 5 (P5): polymorphic locus (N2) of the target sequence superimposed on the second primer and the activator oligonucleotide (third region). These components of the amplification system can thus be constructed specifically and characteristically for the particular sequence variant of the target sequence. The arrangement can be made such that the 3 ^' -terminal nucleotide of the second primer corresponds to the N2 locus. In this arrangement, a target sequence specific first primer is used, which is not sequence variant specific.

Array 6 (P6): polymorphic locus (N2) of the target sequence overlays the second primer and the activator oligonucleotide (third region, near the 5 ^' end). These components of the amplification system can thus be constructed specifically and characteristically for the particular sequence variant of the target sequence. In this arrangement, a target sequence of specific first primer is used, which is not sequence variant specific. Differences in the design of individual elements also result in differences for the primer extension products synthesized during amplification.

FIGS. 46-54

Fig. 46 shows schematically an embodiment with topography of a specific amplification system and a start-up nucleic acid chain with a polymorphic locus (N2) in certain embodiments in which the N2-corresponding segment of the activator oligonucleotide lies in the second region. A specific P1 .1 may preferably bind specifically to the complementary position of a specific sequence variant of the starting nucleic acid (SN 1.1) under reaction conditions and initiate the synthesis of the P1 .1-Ext. In the course of the amplification, this results in the formation of P1.1 text and P2.1 text. No competitor primer is used.

Fig. 47 schematically shows an embodiment with topography of a specific one

Amplification system and a start-up nucleic acid chain with a polymorphic locus (N2) in certain embodiments, in which the N2 corresponding segment of the activator oligonucleotide lies in the second region. A specific P1 .1 may preferably bind specifically to the complementary position of a specific sequence variant of the starting nucleic acid (SN 1.1) under reaction conditions and initiate the synthesis of the P1 .1-Ext. In the course of the amplification, this results in the formation of P1.1 text and P2.1 text. No competitor primer is used. The binding to another sequence variant (SN 1.2) is less efficient due to the mismatch with position (N) within the primer binding site of SN 1 .2. The amplification is thus started less efficiently.

Fig. 48 schematically shows an embodiment with topography of a specific one

Amplification system and a starting nucleic acid chain with a polymorphic locus (N2) in certain embodiments, in which the N2 corresponding segment of the activator oligonucleotide lies in the second region (2). The N2 locus includes the 3 ^'-terminal nucleotide and / or the ^3' -terminal segment of the first primer. A specific P1 .1, with a complementary 3 ^' -terminal nucleotide can bind under reaction conditions preferably specifically to the complementary position of a specific sequence variant of the starting nucleic acid (SN 1.1) and initiate the synthesis of the P1 1 -ext. In the course of the amplification, this results in the formation of P1.1 text and P2.1 text. No competitor primer is used. The binding and initiation of primer extension at another sequence variant (SN 1 .2) is less efficient due to the mismatch with position (N) within the primer binding site of SN 1 .2. The amplification is thus started less efficiently.

Fig. 49 shows schematically an embodiment with topography of a specific amplification system and a starting nucleic acid chain with a polymorphic locus (N2) in certain embodiments in which the N2-corresponding segment of the activator oligonucleotide lies in the third region (3). It becomes a target sequence-specific but not Sequence variant-specific first and second primer used. One for all sequence variants of a target nucleic acid unitary P1.1 and P2.1, can bind to the starting nucleic acid chain and initiate the synthesis of the P1 1-Ext or P2.1 -ext. In the course of the amplification, this leads to the formation of P1 .1-Ext and P2.1-Ext. No competitor primer is used. The separation of both synthesized complementary primer extension products P1 .1 Ext and P2.1 -Ext is preferably carried out specifically by a complementary binding of P1 1-Ext to the activator oligonucleotide. The separation of strands of another sequence variant synthesized using (SN 1 .2) is less efficient due to the mismatch with position (N) to the corresponding sequence segment of the activator oligonucleotide. The amplification of the SN 1 .2 sequence variant is thus less efficient or only insignificant or not at all. The position of the sequence segment (3) corresponding to N2 of the target sequence is in the vicinity of the second blocking moiety so that the interaction between the activator oligonucleotide and the respective first primer extension product is affected by modifications used in the second blocking moiety can.

Fig. 50 shows schematically an embodiment with topography of a specific amplification system and a starting nucleic acid chain with a polymorphic locus (N2) in certain embodiments in which the N2-corresponding segment of the activator oligonucleotide lies in the third region (4). A target sequence specific but not sequence variant specific first and second primer is used. One for all sequence variants of a target nucleic acid unitary P1.1 and P2.1, can bind to the starting nucleic acid chain and initiate the synthesis of the P1 1-Ext or P2.1 -ext. In the course of the amplification, this leads to the formation of P1 .1-Ext and P2.1-Ext. No competitor primer is used. The separation of both synthesized complementary primer extension products P1 .1 Ext and P2.1 -Ext is preferably carried out specifically by a complementary binding of P1 1-Ext to the activator oligonucleotide. The separation of strands of another sequence variant synthesized using (SN 1 .2) is less efficient due to the mismatch with position (N) to the corresponding sequence segment of the activator oligonucleotide. The amplification of the SN 1 .2 sequence variant is thus less efficient or only insignificant or not at all. The position of the sequence segment (4) corresponding to N2 of the target sequence is at a distance from the second blocking moiety, such that the interaction between the activator oligonucleotide and the respective first primer extension product of modifications used in the second blocking moiety in FIG Essentially unaffected. The segment of activator oligonucleotide corresponding to N2 is preferably made of DNA monomers using between 4 to 20 DNA monomers and at least 4 to 10 DNA monomers located around position-4 on both sides. 51 schematically shows an embodiment with topography of a specific amplification system and a starting nucleic acid chain with a polymorphic locus (N2) in certain embodiments, in which the N2-corresponding segment of the activator oligonucleotide lies in the third region (5). The N2 locus also includes the 3 ^' terminal nucleotide of the second primer. A specific P2.1 having a complementary 3 ^' -terminal nucleotide may preferentially bind under reaction conditions specifically to the complementary position of a specific sequence variant starting from strands complementary to the starting nucleic acid (SN 1.1) and preferably the synthesis of P2.1-Ext specifically initiate. During the amplification process, P1.1-Ext and P2.1-Ext are formed. No competitor primer is used. The binding to another sequence variant (SN 1.2) is less efficient due to the mismatch with position (N) within the primer binding site of SN 1 .2. The amplification is thus started less efficiently.

52 schematically shows an embodiment with topography of a specific amplification system and a start-up nucleic acid chain with a polymorphic locus (N2) in certain embodiments, in which the N2-corresponding segment of the activator oligonucleotide lies in the second region. A specific P1 .1 may preferably bind specifically to the complementary position of a specific sequence variant of the starting nucleic acid (SN 1.1) under reaction conditions and initiate the synthesis of the P1 .1-Ext. During the amplification process, P1.1-Ext and P2.1-Ext are formed. The binding to another sequence variant (SN 1 .2) is less efficient due to the mismatch with position (N) within the primer binding site of SN 1.2. The amplification is thus started less efficiently.

To increase the specificity of a competitor primer (P 5.1) is added to the reaction, which is able to bind predominantly complementary to the sequence variants of the target sequence, the amplification of which must be suppressed. Due to a complementary binding with such primer binding sites, a competitor primer may preferentially bind and be extended by the polymerase. The resulting product blocks the single-stranded primer binding sites for interaction of the first amplification primer. In certain embodiments, the 3 ^' end of a competitor primer binds within the second blocking moiety of the activator oligonucleotide so that no extension of this primer on the activator oligonucleotide can occur. The competitor primer does not include a second region and thus can not interact with the first region of the activator oligonucleotide. This prevents the extension product of the competitor oligonucleotide from being detached from the template with the assistance of an activator oligonucleotide.

Fig. 53 shows schematically an embodiment with topography of a specific amplification system and a starting nucleic acid chain with a polymorphic locus (N2) in certain embodiments in which the N2-corresponding segment of the activator oligonucleotides lies in the second region (2). The N2 locus also includes the 3 ^' terminal Nucleotide of the first primer. A specific P1 .1, with a complementary 3 ^' -terminal nucleotide, can under reaction conditions preferably specifically bind to the complementary position of a specific sequence variant of the starting nucleic acid (SN 1.1) and initiate the synthesis of the P1 1 -text. In the course of the amplification, this results in the formation of P1.1 text and P2.1 text. Binding to another sequence variant (SN 1 .2) and extension by a polymerase is less efficient due to the mismatch with position (N) within the primer binding site of SN 1 .2. The amplification is thus started less efficiently.

To increase the specificity, a competitor primer (P 5.2) is added to the reaction, which is able to bind predominantly complementary to the sequence variants of the target sequence whose amplification must be suppressed. Due to a complementary binding with such primer binding sites, a competitor primer can preferentially bind to certain sequence variants (designated here by N) and be extended by the polymerase. The resulting product blocks the single-stranded primer binding sites for interaction of the first amplification primer.

In certain embodiments, the 3 ^' end of a competitor primer binds within the second blocking moiety of the activator oligonucleotide so that no extension of this primer on the activator oligonucleotide can occur. The competitor primer does not include a second region and thus can not interact with the first region of the activator oligonucleotide. This prevents the extension product of the competitor oligonucleotide from being detached from the template.

Fig. 54 shows schematically an embodiment with topography of a specific amplification system and a start-up nucleic acid chain with a polymorphic locus (N2) in certain embodiments in which the N2-corresponding segment of the activator oligonucleotide lies in the third region (3). A target sequence specific but not sequence variant specific first and second primer is used. One for all sequence variants of a target nucleic acid unitary P1.1 and P2.1, can bind to the starting nucleic acid chain and initiate the synthesis of the P1 1-Ext or P2.1 -ext. During the amplification, P1 .1-Ext and P2.1 -xt are formed. The separation of both synthesized complementary primer extension products P1.1 -Ext and P2.1 -Ext is preferably carried out specifically by complementary binding of P1.1 -Ext to the activator oligonucleotide. The separation of strands of another sequence variant synthesized using (SN 1.2) is less efficient due to the mismatch with position (N) to the corresponding sequence segment of the activator oligonucleotide. The amplification of the SN 1 .2 sequence variant is thus less efficient or only insignificant or not at all. The position of the sequence segment (3) corresponding to N2 of the target sequence is in the vicinity of the second blocking moiety so that the interaction between the activator oligonucleotide and the respective first primer extension product is affected by modifications used in the second blocking moiety can. To increase the specificity of a competitor primer (P 5.3 or P5.4) is added to the reaction, which is able to bind mainly complementary to the sequence variants of the target sequence (N), whose amplification must be suppressed. Due to complementary binding with such primer binding sites, a competitor primer may preferentially bind to certain sequence variants (designated N herein) and be extended by the polymerase. The resulting product blocks the single-stranded primer binding sites for interaction of the first amplification primer.

In certain embodiments, the competitor primer oligonucleotide (P 5.3) is longer than the first region of the first primer oligonucleotide such that its 3 ^' end binds within the fourth blocking moiety of the activator oligonucleotide (fourth blocking moiety is analogous to the second Blocking unit composed and blocks a primer extension on the activator oligonucleotide), so that no extension of this primer on the activator oligonucleotide can take place. The competitor primer can cover the segment of the template which can predominantly complement P1 .1 completely (P 5.3) or partially (P 5.4). The competitor primer does not include a second region and thus can not interact with the first region of the activator oligonucleotide. This prevents the extension product of the competitor oligonucleotide from being detached from the template with the assistance of an activator oligonucleotide.

Such amplification can be carried out alone or in combination, for example with a downstream PCR.

Figures 55-57 schematically show the topography of components of the first amplification system.

The starting nucleic acid 1.1 comprises (in the 5 ^' -3 ^' direction) the following segments: M1 Ύ, M1.5, M1.4, M1.3, M1.2, M1.1, M1.X.

The first primer oligonucleotide comprises (in the 5 ^' -3 ^' direction) the following segments: the first region (P1.1 .1) and the second region (P1.1 .2).

The controller oligonucleotide (C1 .1) comprises (in the 5 ^' -3 ^' direction) the following segments: the third region (01 .1.3), the second region (C1 .1.2) and the first region (C.1.1.1 ).

The controller oligonucleotide (C1 .2) comprises (in the 5 ^' -3 ^' direction) the following segments: the third region (C1 .2.3), the second region (C1 .2.2) and the first region (C.1.2.1 ).

The second primer P2.1 comprises (in the 5 ^' -3 ^' direction) the following segments: P2.1.1.

The second primer P2.2 comprises (in the 5 ^' -3 ^' direction) the following segments: P2.2.1.

The second primer P2.3 comprises (in the 5 ^' -3 ^' direction) the following segments: P2.3.1.

The first primer extension product (P1.1 Ext) comprises (in the 5 ^' -3 ^' direction) the following

Segments: P1.1 E6, P1.1 E5, P1.1 E4, P1.1 E3, P1.1 E2, P1.1 E1. The second primer extension product (P2.1 -Ext) comprises (in the 5 ^' -3 ^' direction) the following segments: P2.1 E5, P2.1 E4, P2.1 E3, P2.1 E2, P2.1 E1 ,

The primer extension products P1.1 -Ext and P2.1 -Ext which are preferably obtained during the first amplification can form a complementary double strand and together constitute the second amplification fragment 1 .1, which serve as start nucleic acid 2.1 for the second amplification can.

Where P1.1 .1 can bind predominantly complementary to M1.1 and can be extended by the polymerase and P2.1.1 can bind to P1.1 E1 complementarily and can be extended. P1 1 -Ext and P2.1-Ext represent the nucleic acid to be amplified which serves as starting nucleic acid 2.1 for the second amplification. P2.1, P2.2. and P2.3 represent variants of second primers and result in equal amplification fragments.

Fig. 56 shows schematically the topography of the second amplification system:

The third primer oligonucleotide comprises (in the 5 ^' -3 ^' direction) the following segments: P3.1.2, P3.1.1, where P3.1.2 is not complementary to the starting nucleic acid 1.1 or to P2.1 -Ext. P3.1 .1 is essentially complementary to P2.1 E1 of the P2.1 text.

The fourth primer oligonucleotide comprises (in the 5 ^' -3 ^' direction) the following segments: P4.1.2, P4.1.1, where P4.1.2 is not complementary to the complementary strand of the starting nucleic acid 1 .1 or to P1 1 -Ext , P4.1.1 is essentially complementary to P1 .1 E1 of P1 1-Ext.

The preferably obtained during the second amplification primer extension products P3.1 -Ext and P4.1 -Ext can form a complementary double strand and together represent the second amplification fragment 2.1.

P3.1 -Ext comprises (in the 5 ^' -3 ^' direction) the following segments: P3.1 E7, P3.1 E6, P3.1 E5, P3.1 E4,

P3.1 E3, P3.1 E2, P3.1 E1. The segments P3.1 .E5 to P3.1 E3 are identical in their sequence to P1.1 E4 to P1.1 E2.

P4.1 -Ext comprises (in the 5 ^' -3 ^' direction) the following segments: P4.1 E7, P4.1 E6, P43.1 E5, P4.1 E4,

P4.1 E3, P43.1 E2, P4.1 E1. The segments P4.1 E5 to P4.1 E3 are identical in their sequence to P2.1 E4 to P2.1 E2.

FIGS. 57-58 show variants of the third primer (P3.1, P3.2, P3.3) and of the fourth primer (P4.1, P4.2, P4.3), the 3 ^' segment of the respective primer may be shifted in relation to each other.

The coupling of both amplifications using starting nucleic acid chain synthesized by the method according to the invention can be summarized as follows:

The method comprises the steps:

A) Provision of a nucleic acid fragment comprising a first target sequence (a start nucleic acid chain) B) providing a first amplification system comprising:

A first primer oligonucleotide

A second primer oligonucleotide

• A controller oligonucleotide

• A first polymerase

• Substrates for the first polymerase (dNTPs) and appropriate buffer solution

C) providing a second amplification system comprising:

A third primer oligonucleotide

A fourth primer oligonucleotide

A second polymerase comprising a thermostable polymerase

Substrates for the second polymerase (dNTPs) and appropriate buffer solution

• A detection system

D) performing a first amplification using the starting nucleic acid chain as the initial template strand and the first amplification system to obtain a first amplification fragment 1 .1 comprising the first target sequence, and comprising a first primer extension product and a second primer extension product, which can form a complementary duplex, wherein the first primer extension product results from template-dependent extension of a first primer by means of a polymerase using the start nucleic acid chain and / or the second primer extension product as template and the second primer extension product results from template-dependent extension of one second primer by means of a polymerase using the first primer extension product as a template, wherein the first and the second primer extension product mutually serve as templates for the respective primer extension can and

wherein both complementary strands of the first amplification product 1 .1 can be at least partially converted into single-stranded form with the assistance of the controller oligonucleotide, so that a renewed primer binding to each complementary Seqmente of the synthesized primer extension Produtke is possible and

the reaction conditions of the first amplification used comprise at least one temperature step permitting hybridization and template-dependent primer extension of both primers of the first amplification system and comprising at least one temperature step in which the first primer extension product is displaced from the second primer extension product With the use of the controller oligonucleotide is separated, wherein the reaction conditions used no spontaneous separation of the first primer Allow extension product from the second primer extension product in the absence of the controller oligonucleotide. Wherein the first amplification is carried out until the desired amount of the first amplification product 1.1 is synthesized.

E) performing a second amplification using at least one of the two strands of the first amplification fragment 1.1 as an initial template strand and using the second amplification system to obtain a second amplification fragment 2.1 comprising a third primer extension product and a fourth primer - Extension product, which can form a complementary double strand, both strands of the amplification fragment 2.1 can both serve as templates in a primer extension, wherein the reaction conditions used the second amplification at least in a temperature step, a hybridization of the two primers of the second amplification Allow system and a template-dependent primer extension of each bound to complementary regions primer of the second amplification system and allow at least in a further temperature step, a separation of a double strand include and a third primer extension product and a fourth primer extension product, wherein the third and fourth primer extension products are converted into single stranded form such that re-primer binding and extension may occur. Wherein the second amplification is carried out until the desired amount of the second amplification product 2.1 is synthesized.

In detail, the properties of components of the respective amplification system, of the nucleic acid fragment comprising a first target sequence, as well as the reaction conditions used, determine the course of the two amplification reactions.

In general, the first amplification takes place with the assistance of the controller oligonucleotide. The separation of the two synthesized primer extension products takes place at least in part depending on the sequence composition of the first primer extension product and its complementarity with the composition of the controller oligonucleotide.

During the second amplification, a second amplification fragment 2.1 is amplified essentially without the involvement of the controller oligonucleotides.

In the course of both amplification reactions both desired amplification products (amplification fragment 1 .1 and amplification fragment 2.1) can be formed, as well as their intermediate stages (intermediates) (FIG. 58). The composition of the intermediates depends essentially on the provided components of the first and second amplification systems.

In the following, some molecular processes and the resulting products and the potential intermediates will be exemplarily and schematically explained. According to a first aspect of the invention, a method for amplification is provided. The method comprises the steps:

1) a first amplification with the steps

1.A) hybridizing a first primer oligonucleotide to the 3 'segment of a template nucleic acid fragment (template strand, starting nucleic acid chain) of a first nucleic acid to be amplified which comprises a first target sequence, wherein the first primer oligonucleotide comprises the following regions:

A first region which can sequence-specifically bind to the 3 'segment of a template strand of the first nucleic acid to be amplified and is complementary to at least a portion of the target sequence;

A second region which connects to the 5 'end of the first region or is linked via a linker, the second region being capable of being bound by a controller oligonucleotide and of a polymerase used for the first amplification among the selected ones

Reaction conditions remain essentially unkopiert;

1.B) extension of the first primer oligonucleotide when hybridized to complementary segments of a first nucleic acid to be amplified by the first template-dependent polymerase to obtain a first primer extension product which comprises, in addition to the first primer oligonucleotide, a polymerase-synthesized region Substantially complementary to the template strand of the first to be amplified

Nucleic acid comprising a first target sequence, wherein the first primer extension product and the template strand of the first nucleic acid to be amplified are present substantially as a duplex under reaction conditions of the first amplification used;

1 .C) binding of a controller oligonucleotide to the first primer extension product, wherein the controller oligonucleotide comprises the following ranges:

A first region capable of binding to the second region of the first primer and / or the first primer extension product;

A second region that is substantially complementary or fully complementary to the first region of the first primer oligonucleotide and / or the first primer extension product, and

• a third area that is at least part of the polymerase

in the synthesized region of the first primer extension product in the

Is substantially complementary or fully complementary; wherein the controller oligonucleotide does not serve as a template for primer extension of the first primer oligonucleotide, and the controller oligonucleotide comprises a sequence segment which is complementary or substantially complementary to a strand of the first nucleic acid to be amplified, and

the controller oligonucleotide binds to the first region of the first primer extension product and

and binding the controller oligonucleotide to the second region of the first primer extension product, as well as at least partially to the synthesized region of the first primer extension product, displacing complementary portions of the template strand of the first nucleic acid to be amplified; wherein the polymerase synthesized portion of the first primer extension product comprising the second primer oligonucleotide complementary segment of the first primer extension product becomes single-stranded under reaction conditions

1 .D) hybridizing a second primer oligonucleotide to the single-stranded one

A complementary segment of the first primer extension product, wherein the second primer oligonucleotide comprises a region capable of hybridizing sequence-specifically to the synthesized region of the first primer extension product and comprising at least a portion of a target sequence

1 .E) extension of the second primer oligonucleotide by the first polymerase using the first primer extension product as a template to yield a second primer extension product comprising, in addition to the second primer oligonucleotide, a polymerase synthesized region comprising at least a portion the first target sequence, wherein the first primer extension product and the second primer extension product form a first double-stranded amplification product under reaction conditions of the first amplification; and;

1 .F) If necessary Repetition of the steps of the first amplification

) a second amplification with the steps (Figure 58):

2.A) hybridizing a third primer oligonucleotide to the second primer extension product of the first amplification product, the third primer oligonucleotide comprising a first region capable of substantially sequence-specific binding to a segment of the second primer extension product;

2.B) extension of the third primer oligonucleotide by a second polymerase using the second primer extension product as a template to give a third primer extension product (P3.1-Ext part 1) containing, in addition to the third primer oligonucleotide, one of the Polymerase comprises a synthesized area that includes a

Sequence segment comprises, which is substantially complementary to the second primer extension product or to the first nucleic acid to be amplified or to a proportion the first target sequence, wherein the second primer extension product and the third primer extension product (P3.1-Ext part 1) are present as a double strand;

2C) hybridizing a fourth primer oligonucleotide to the first primer extension product of the first amplification product, the fourth primer oligonucleotide comprising a first region capable of substantially sequence-specific binding to the polymerase-synthesized region of the first primer extension product;

2D) extension of the fourth primer oligonucleotide by the second polymerase using the first primer extension product as template to yield a fourth primer extension product (P4.1-Ext Part 1) which synthesized one from the polymerase in addition to the fourth primer oligonucleotide Area includes, in the

Is substantially complementary to the first primer extension product and comprises portions of the target sequence, wherein the first primer extension product and the fourth primer extension product (P4.1-Ext Part 1) are present as a duplex;

2E) Separation of the double strand from the first primer extension product and the fourth primer extension product (P4.1 -Ext part 1) and the double strand from the second primer extension product and the third primer extension product (P3.1 - Ext Part 1) ;

2.F) hybridizing a third primer oligonucleotide to the fourth primer extension product (obtained in step 2D, P4.1-Ext part 1), the third primer oligonucleotide comprising a first region substantially sequence-specific to a segment of the nucleotide fourth primer extension product (P4.1-Ext Part 1);

2.G) extension of the third primer oligonucleotide by a second polymerase using the fourth primer extension product (P4.1-Ext Part 1) as a template to give a complete third primer extension product (P3.1-Ext), the the third primer extension product (P3.1-Ext) and the fourth primer extension product (P4.1-Ext Part 1) are present as a double strand;

2H) hybridizing a fourth primer oligonucleotide to the third primer extension product (obtained in step 2B, P3.1 -ext part 1), wherein the fourth primer oligonucleotide comprises a first region which is substantially sequence-specific to that synthesized by the polymerase Area of the third primer extension product can bind;

2I) extension of the fourth primer oligonucleotide by the second polymerase using the third primer extension product (P3.1-Ext Part 1) as template to give a complete fourth primer extension product (P4.1 -Ext), the third primer Extension product (P3.1-Ext Part 1) and the fourth primer extension product (P4.1-Ext) are present as a double strand; 2J) Separation of the double strand from the third primer extension product (P3.1 Ext Part 1) and the complete fourth primer extension product (P4.1 Ext) and the double strand from the fourth primer extension product (P4.1-Ext part 1) and the complete third primer extension product (P3.1-ext);

2.K) hybridizing a third primer oligonucleotide to the complete fourth primer extension product (obtained in step 2I, P4.1 -Ext), wherein the third primer oligonucleotide comprises a first region substantially sequence-specific to a segment of the fourth Primer extension product (P4.1-Ext);

2.L) extension of the third primer oligonucleotide by a second polymerase using the complete fourth primer extension product (P4.1 -Ext) as template to give a complete third primer extension product (P3.1-Ext), the complete the third primer extension product (P3.1-Ext) and the complete fourth primer extension product (P4.1-Ext) are present as a double strand;

2M) hybridizing a fourth primer oligonucleotide to the complete third primer extension product (obtained in step 2G, P3.1 -Ext), the fourth primer oligonucleotide comprising a first region substantially sequence specific to the polymerase synthesized region of the full third primer extension product can bind;

2N) extension of the fourth primer oligonucleotide by the second polymerase using the complete third primer extension product (P3.1-Ext) as template to yield a complete fourth primer extension product (P4.1-Ext), the complete third primer Extension product (P3.1-Ext) and the complete fourth primer extension product (P4.1-Ext) are present as a double strand;

20) Separation of the double strands formed in steps 2L and 2N from the complete third primer extension product (P3.1-Ext) and the complete fourth primer extension product (P4.1-Ext)

2.P) If necessary Repetition of the steps of the second amplification with propagation of the complete third primer extension product (P3.1-Ext) and the complete fourth primer extension product (P4.1 -Ext).

wherein a detection system is added to the reaction mixture.

The amount of yields of individual products and intermediates depends on several factors. For example, higher concentrations of individual primers generally favor the yields of products / intermediates. Furthermore, the formation of products / intermediates can be influenced by the reaction temperature as well as the binding / affinity of individual reactants to each other (affinity of the binding of individual primers to their complementary primer binding sites within Template strands): in general, for example, longer oligonucleotides bind better than shorter oligonucleotides at higher temperatures, and CG content may also play a role in complementary sequence segments: CG-richer sequences also bind more strongly at higher temperatures than AT-rich sequences. Furthermore, modifications such as MGB or 2-amino-dA or LNA can increase the binding strength of primers to their respective complementary segments, which also results in preferential binding of primers at higher temperatures.

It can be deduced from this that the design of sequence segments of individual primer sequences can influence the yields of certain products / intermediates and thus their enrichment during amplification can be influenced.

A method of amplifying a nucleic acid (Figs. 56-58), comprising the steps of:

a) a first amplification with the steps:

Provision of a starting nucleic acid 1.1, which comprises a target sequence

Hybridizing a first primer oligonucleotide (P1.1) to a nucleic acid to be amplified with a target sequence (either starting nucleic acid 1.1 or P2.1 -Ext), wherein the first primer oligonucleotide (P1.1) comprises the following ranges:

A first region (P1.1.1) which can bind sequence-specific to a region of the nucleic acid to be amplified (P2.1 E1),

A second region (P1.1.2) which connects to the 5 'end of the first region or is linked via a linker, the second region being capable of being bound by a controller oligonucleotide and of the polymerase used

Reaction conditions remain essentially unkopiert;

Extension of the first primer oligonucleotide (P1.1) by a first

Polymerase to obtain a first primer extension product (P1 1-Ext), which in addition to the first primer oligonucleotide (P1 .1) comprises a synthesized region (P1 .1 E1 to P1.1 E4), which is substantially complementary to that amplifying nucleic acid or to the target sequence, wherein the first primer extension product and the nucleic acid to be amplified are present as a double strand;

Binding of a controller oligonucleotide (C1.2) to the first primer extension product (P1.1 -Ext), wherein the controller oligonucleotide (C1.2) comprises the following ranges:

A first region (01 .2.1) which can bind to the second region (overhang) of the first primer extension product (P1.1 E6), A second region (C1.2.2) which is complementary to the first region of the first primer oligonucleotide (P1.1 .1), and

• a third area (C1 .2.3) that is at least part of the

synthesized region of the first primer extension product (P1.1 E4) is substantially complementary; and

wherein the controller oligonucleotide (C1 .1) is not used as a template for a

Primer extension of the first primer oligonucleotide (P1 .1), and the first controller oligonucleotide (C 1 .1) to the first primer extension product (P1 .1 E6, P1 .1 E5, P1 .1 E4) with displacement of the to this area

complementary region (P2.1 E1, P2.1 E2) of the to be amplified

Nucleic acid binds;

Hybridizing a second primer oligonucleotide (P1.1) to the first primer extension product, wherein the second primer oligonucleotide (P2.1) comprises a region (P2.1.1) that is sequence-specifically attached to the synthesized region of the first primer extension product (P1.1). P1.1 E1) can bind,

Extension of the second primer oligonucleotide (P.2.1) by the first

Polymerase to give a second primer extension product (P2.1 - Ext), which in addition to the second primer oligonucleotide (P2.1) a

synthesized region (P2.1 E4 to P2.1 E1) which is substantially identical to the nucleic acid or the target sequence to be amplified, wherein the first primer extension product (P1 1-Ext) and the second

Primer extension product (P2.1) a first double-stranded

Form amplification product; and

Steps of the first amplification are repeated until the desired amount of first amplification products has been synthesized.

b) a second amplification with the steps:

Hybridizing a third primer oligonucleotide (P3.2) to the second and / or the fourth primer extension product (P1 .1-Ext. Or P4.1-Ext), wherein the third primer oligonucleotide (P3.2) has a first Comprises a region (P3.1 .1) which can sequence-specifically bind to a region of the second primer extension product (P2.1 E1) and the fourth primer extension product (P4.1 E2),

Extension of the third primer oligonucleotide (P3.2) by a second polymerase to obtain a third primer extension product (P3.2-Ext) which, in addition to the third primer oligonucleotide (P3.2), has a synthesized region (P3.1 E5 to P3.1 E2 or P3.1 E5 to P3.1 E1), which in

Substantially complementary to the second primer extension product (P2.1- Ext) or to the target sequence, wherein the second primer extension product (P2.1) and the third primer extension product (P3.1) are present as a double strand;

Hybridizing a fourth primer oligonucleotide (P4.2) to the first primer extension product (P1 1 -Ext) and / or to the third primer

Extension product (P3.1 -Ext) wherein the fourth primer oligonucleotide (P4.2) comprises a first region (P4.1.1) that is sequence-specifically to the synthesized region of the first primer extension product (P1.1 E1) and the third primer extension product (P3.1 E2),

Extension of the fourth primer oligonucleotide (P4.2) by the second

Polymerase to obtain a fourth primer extension product (P4.2-Ext), which in addition to the fourth primer oligonucleotide comprises a synthesized region (P4.1 E5 to P4.1 E2 or P4.1 E5 to P4.1 E1), the is substantially complementary to the first primer extension product (P1.1 -Ext) or identical to the target sequence, wherein the first primer extension product (P1 1-Ext) and the fourth primer extension product (P4.1-Ext) are present as a double strand;

Separation of the double strand from the first primer extension product (P1 1-Ext) and the fourth primer extension product (P4.2-Ext) and the double strand from the second primer extension product (P2.1 -Ext) and the third primer extension product (P3.1-Ext) and the double strand from the fourth primer extension product (P4.1-Ext) and the third primer extension product (P3.1-Ext);

Hybridizing the third primer oligonucleotide (P3.2) to the fourth primer extension product (P4.2-Ext) and extension of the third primer oligonucleotide (P3.2) by the second polymerase; and

Hybridizing the fourth primer oligonucleotide to the third primer extension product (P3.2-Ext) and extending the fourth primer oligonucleotide (P4.2) by the second polymerase.

Claims

claims

1 . A method of synthesizing a gene complementary to a target sequence

Nucleic acid sequence, wherein

a) a sample comprising a nucleic acid polymer comprising the target sequence M, wherein the target sequence in 5'-3 'orientation comprises the sequence sections MS and MP and MP is arranged directly in the 3' direction of MS, contacted with the following components becomes:

b) an oligonucleotide primer P, which in the 5'-3 'orientation comprises the sequence sections PC and PM and PM is arranged directly in the 3' direction of PC, wherein PM has the [the hybridizing] sequence complementary to the sequence section MP [ can bind sequence-specifically] and PC can not bind to M [or a sequence directly adjacent to MP in the 3 'direction];

c) a controller oligonucleotide C which in 5'-3 'orientation the

Sequence sections CS, CP and CC, where CP is located immediately in the 3 'direction of CS and immediately in the 5' direction of CC, and where CS is at least to the 3 ^' segment of MS (immediately in the 5' direction of MP lying) and CP and CC has the [the hybridizing] sequence complementary to the sequence section PM and PC, and wherein CS comprises modified nucleotide building blocks such that CS can not serve as template for the activity of the template-dependent nucleic acid polymerase;

d) a template-dependent nucleic acid polymerase, in particular a DNA polymerase, and substrates of the template-dependent nucleic acid polymerase (in particular ribonucleoside triphosphates or deoxyribonucleoside triphosphates) and suitable cofactors,

wherein a primer extension product P 'is obtained, which in addition to the

Sequence areas PC and PM comprises a synthesized area PS, which in the

Is substantially complementary to the target sequence MS,

and where

either the reaction conditions are selected, and / or the length and melting temperature of PC and / or MS are selected such that P 'can form a double strand with M and P' can form a double strand with C.

2. The method according to claim 1, wherein the sequence section CS at its 3 'end immediately in the 5' direction of the sequence section CP has a sequence section CS 'of FIG contains up to 15 nucleotide positions of nucleic acid analogues,

especially from 2'0-Alkylribonukleotiden exists.

3. The method according to any one of the preceding claims, wherein M is a

Sequence portion MB directly in the 5 'direction of MS, and further wherein a block oligonucleotide B, which can hybridize to MB, is brought into contact with the sample, and wherein

a. B comprises nucleoside analogs selected such that a B hybrid to MB does not permit the MB-dependent nucleic acid polymerase reaction on MB or

b. the template-dependent nucleic acid polymerase is selected such that a hybrid of B to MB [even though B consists of natural nucleosides or deoxynucleosides] is the response of the template-dependent ones

Nucleic acid polymerase not allowed on MB.

The method of claim 3, wherein B is contacted with the sample before the template-dependent nucleic acid polymerase is contacted with the sample.

The method of any one of the preceding claims, wherein CS is identical to MS and CP is identical to MP.

6. The method according to any one of the preceding claims, wherein the formation of the

Double strand of P 'and C is preferred over the formation of the double strand of P' with M.

7. The method according to any one of the preceding claims, characterized in that the method is carried out substantially isothermal.

The method according to any one of the preceding claims, wherein the sample is not contacted (or comprises) with a primer oligonucleotide which bind to and from a sequence located in the PS region

matrix-dependent nucleic acid polymerase can be a synthesis of a counterstrand to PS (in other words: the method does not lead to exponential

Amplification of M).

9. The method according to any one of the preceding claims, characterized in that MS has a length of 20 nucleotides to 200 nucleotides.

10. The method according to any one of the preceding claims, characterized in that P has a length in the range of 15 nucleotides to 100 nucleotides.

1 1. The method according to one of the preceding claims, characterized in that PC has a length in the range of 5 nucleotides to 85 nucleotides, in particular that PC has between 50% and 300% of the length of the sequence section PM.

12. The method according to any one of the preceding claims, characterized in that C has a length in the range of 20 nucleotides to 100 nucleotides.

13. The method according to any one of the preceding claims, characterized in that the sample comprises a variant VM of the target sequence M, which> 85%, in particular> 95%,> 92%,> 94%,> 96% or even> 98% is identical to M, wherein a section VMS of the variant is highly identical to the section MS, and a section VMP is highly identical to the section MP, and VM in at least one position VMM is different from the sequence M, in particular one or more substitution (s) , Insertion (s) and / or deletion (s).

14. The method according to claim 13, characterized in that VMM has a length of 1 to 20 nucleotides, in particular of 1 to 3 nucleotides.

The method of claim 13 or 14, wherein VMM is included in that of VMS

Sequence section lies.

16. The method according to any one of the preceding claims 13 to 15, characterized in that the sections MP and VMP> 99%, in particular 100%, are identical.

17. The method according to any one of the preceding claims 13 to 16, characterized in that the sections MS and VMS outside of the section VMM> 99%, in particular 100%, are identical.

18. The method according to any one of the preceding claims 13 to 17, characterized in that VMM <30 nucleotide positions, in particular <25, <15 or <10 nucleotide positions in the 5 'direction from VMP to VM is arranged.

19. The method according to one of the preceding claims 13 to 18 (Fig. 59), characterized

characterized in that further a second controller oligonucleotide VC is brought into contact with the sample comprising in the 5'-3 'orientation the sequence sections VCS, VCP and VCC, where VCP is immediately in the 3' direction of VCS and immediately in FIG - Vcc direction is arranged, and wherein VCS at least to the 3 ^' segment of VMS (immediately in the 5' direction of VMP lying) is identical and VCP and VCC to the sequence section PM and PC complementary having [the hybridizing] sequence and wherein VCS comprises modified nucleotide building blocks such that VCS can not serve as a template for the activity of the template-dependent nucleic acid polymerase.

The method of claim 13 or 14, wherein VMM is at least partially encompassed by the sequence portion encompassed by VMP.

21. The method according to claim 20, characterized in that the sections MS and VMS are> 95%, in particular> 98%,> 99% or even 100% identical.

22. The method according to any one of the preceding claims 13, 14, or 19 to 21 (Fig. 60), characterized in that further a second oligonucleotide primer VP is brought into contact with the sample, which in 5'-3 'orientation the Sequence sections VPC and VPM and VPM is located immediately in 3 'of VPC, where VPM complementary to the sequence section VMP of the target sequence VM [the hybridizing] Has sequence [essentially sequence-specific binding] and VPC can not bind to VM [or a sequence immediately adjacent to VMP in 3 '].

23. The method according to any one of the preceding claims 13, 14, or 19 to 20, characterized in that VMM is at the 5 'end of VMP, in other words that the 3' end of VPM hybridizes with VMM.

24. The method according to any one of the preceding claims 13, 14, or 19 to 23, characterized in that further a competitor oligonucleotide KP is brought into contact with the sample which hybridizes with VMP.

25. The method according to any one of the preceding claims, characterized in that the reaction conditions selected include a reaction temperature in the range of 25 ° C to 80 ° C.

26. A kit for carrying out a method according to one of claims 1 to 25,

full:

an oligonucleotide primer P which comprises the sequence segments PC and PM in the 5'-3 'orientation and PM is arranged directly in 3' of PC, wherein PM refers to a genomic sequence M of a eukaryotic organism or of a pathogenic bacterium, in particular of a mammal in particular, to a human target sequence comprising a primer binding site capable of binding MP and failing to bind PC to a sequence located directly in the 3 'direction of MP;

a controller oligonucleotide C comprising, in the 5'-3 'orientation, the sequence sections CS, CP and CC, where CP is located immediately in 3' of CS and immediately in 5 'of CC, and where CS is identical to one immediately in 5 'direction of MP lying sequence is MS and CP is identical to MP and CC to the

PC sequence comprising complementary nucleotide building blocks, so that CS can not serve as template for the activity of a template-dependent nucleic acid polymerase.

The kit of claim 26, further comprising a block oligonucleotide B capable of hybridizing to a sequence portion of the target sequence MB immediately adjacent to the 5 'direction of MS, wherein B comprises nucleoside analogs selected such that a hybrid of B MB does not allow the reaction of a template-dependent nucleic acid polymerase on MB.

28. The kit according to claim 26 or 27, further comprising

a second oligonucleotide primer VP, which in 5'-3 'orientation the

Sequence sections VPC and VPM and VPM is located immediately in 3 'of VPC, where VPM can bind to a genomic sequence VM comprising a primer binding site VMP, where VM is> 85%, in particular>95%,>92%,> 94% ,> 96% or even> 98% is identical to M, but in at least one Position is different from M, and VPC can not bind to a sequence located directly in the 3 'direction of VMP;

and or

a second controller oligonucleotide VC, which in 5'-3 'orientation the

Sequence sections VCS, VCP and VCC, wherein VCP is located immediately in the 3 'direction of VCS and immediately in the 5' direction of VCC, and wherein VCS identical to a (immediately in the 5 'direction of VMP lying) genomic sequence VMS which is part of a variant VM which is> 85%, in particular> 95%,

> 92%,> 94%,> 96% or even> 98% identical to M, but different in at least one position from M, and VCP is identical to VMP and VCC has the sequence complementary to the sequence section VPC [hybridizing] sequence, and wherein VCS comprises modified nucleotide building blocks such that VCS can not serve as a template for the activity of a template-dependent nucleic acid polymerase, and / or

a competitor oligonucleotide KP which hybridizes with VMP.

29. The kit according to any one of claims 26 to 28, further comprising a

matrix-dependent nucleic acid polymerase, in particular a DNA polymerase, and optionally substrates of the template-dependent nucleic acid polymerase (in particular ribonucleoside triphosphates or deoxyribonucleoside triphosphates) and suitable cofactors.

30. The kit of any of claims 26 to 29, wherein said kit does not comprise a primer oligonucleotide which bind to a sequence portion located on the counterstrand of M and from which, by the template-dependent nucleic acid polymerase, a synthesis of a substantially to the 5 ' End of MP sequence located on M identical sequence (in other words: the kit does not allow to amplify the sequence located in the 5 'direction of MP to M exponentially).