EP1409719A1 - Method for detecting known mutations in tube - Google Patents

Abstract

The invention concerns a method for detecting a mutation in a target nucleic acid comprising amplification of the target DNA, specific hybridization of a probe with the DNA target, extension of the probe by selective addition of alpha S-phosphothioatedesoxynucleotide complementary of the mutation in a tube A and adding an alpha S-phosphothioatedesoxynucleotide complementary of the natural base corresponding to said mutation in a tube B; the resulting extended probe being resistant to digestion by an exonuclease, particularly by exonuclease III.

Description

 Method for detecting known tube mutations

The present invention relates to a method for detecting a mutation in a target nucleic acid comprising amplification of the target DNA, specific hybridization of a probe with the target DNA, extension of the probe with selective addition of an αS-phosphothioatedésoxynucleotide complementary to the mutation in a tube A and addition of an αS-phosphothioatedésoxynucleotide complementary to the natural base corresponding to said mutation in a tube B; the probe thus extended being resistant to digestion by an exonuclease, in particular by exonuclease III. The detection of the mutation and of the natural base is carried out by direct or indirect measurement in tubes A and B.

Mutations in germ cells or in somatic lines can have dreadful consequences on the organism, for example by causing hereditary genetic diseases or the appearance of cancer. The effect of a mutation is closely linked to its location in DNA. In the case of a mutation in a coding region, the loss of the function of the coded protein can be observed. If the mutation is in a regulatory region, DNA expression can be abolished or increased. A mutation in a gene involved in cancer in the germ line does not necessarily mean that the individual concerned will actually contract a tumor, but only that the risk of it is increased. In addition, when trying to diagnose the invasive potential of an already established tumor, we do not know in advance which mutations to expect because they can be on several genes or in several places of the same uncomfortable. Therefore, it appears necessary to have a simple, rapid, and reliable test, which can easily detect many mutations. The need for a technique for detecting mutations, typing or even studying polymorphism is increasingly felt in the industry, either for allow the discovery of new biological targets of interest, either to know precisely the genetic profile of a tumor or of a patient and to consider suitable therapies. This need has led to the development of various techniques such as LCR, SSCP and RFLP but they remain difficult to implement on a large scale.

The objective underlying the present invention has been to develop a technique allowing the rapid and easy determination of nucleotides to be identified and consequently the diagnosis of mutations and polymorphisms of genes, or the identification of pathogenic microorganisms or genetically modified. More specifically, the problem lies in a compilation of different techniques combining, within the same tube, the amplification of the DNA of a sample and the detection of a given nucleotide. This method is easy to use, generates signals that do not require tedious processing and complicated interpretation.

In the context of the present invention, a system has been developed in which all the steps leading to the results are carried out in the same tube which is based on the amplification of the target DNA, the specific hybridization of a probe (in this case serving as an oligonucleotide primer) with the target DNA, extending the probe with selective addition of an αS- phosphothioated deoxynucleotide to the 3 'end of the primer complementary to the target DNA; the primer thus elongated being resistant to digestion by an exonuclease, in particular by exonuclease III. Thus, the probe remains present in the tube only when the following conditions are met: a) hybridization between the probe and the target DNA of the sample, and b) presence of a complementary base in the target DNA allowing the incorporation of the αS-phosphothioatedésoxynucleotide into the probe; which prevents its degradation by nuclease. The key steps of this process are illustrated in the example presented in Figure 1 below. The technique described in US 4,656,127 consists in the incorporation of a thio-dNTP which protects from the degradation of the exonuclease. However, the method according to the invention offers the advantage of speed, simplicity of implementation and ease of interpretation of the results. Indeed, the use of two separate tubes A and B, one being intended for the detection of the mutated base (tube A) and the other being intended for the detection of the normal base corresponding to said mutated base (tube B), allows excellent reliability (presence of a positive control, whatever the genotype to be tested) and a direct interpretation of the results. A higher number of tubes can also be used. Thus, in a particular and advantageous case, four tubes are used, in order to be able to test the presence of each base on the target DNA. This allows to refine the analysis when the tested base is very polymorphic.

A second advantage of the method according to the invention is conferred by the attachment of one of the primers to the tube used for the amplification and thus anchoring the amplification products on the walls of the tubes. The advantage of this anchoring is to be able to then carry out all the reactions leading to the colored development, including washes in the same tube which in particular avoids the risks of contamination and represents a significant time saving, especially knowing that the use the same solid support for all stages of the process facilitates automation.

A third advantage of the present invention is to differentiate between homozygous and heterozygous carriers of the targeted mutation thanks to the use of two separate tubes. Indeed, the revelation results in a coloration in only one of the two tubes if the mutation is present in the homozygous state, while the coloration is present in the two tubes if the mutation is present in the heterozygous state. Furthermore, the result can be obtained in 30 to 40 minutes after PCR amplification and does not require any particular heavy environment. In addition, certain steps can be combined (exonuclease and revelation in particular) in order to reduce the implementation time without modifying the specificity. Thanks to such a method, the detection experiment can be repeated, unlike the technique described in US 4,656,127. Indeed, the use of the solid support makes it possible to conserve the strand of nucleic acid to be analyzed and the exonuclease degrading the unprotected probe, the hybridization and detection step can be repeated in the same tube if necessary.

The industrialization of such a process thus seems much easier because the realization of all the stages in the same tube including the PCR, the different incubations and the different washes make it possible to envisage a rapid automation of the process on any commercialized automated molecular biology platform.

Description

The present invention relates to a method allowing the identification of a known mutation or polymorphism in a nucleic sequence comprising the amplification of the region of interest by PCR, this amplification step being advantageously carried out using a primer attached to the wall of two tubes A and B (asymmetric PCR); hybridization of a specific probe designed so that its end is positioned just upstream from the base to be revealed; elongation of this probe by means of a polymerase with a modified nucleotide, advantageously a phosphothionucleotide, in particular an αS- phosphothioatedésoxynucleotide, complementary to the mutation to be revealed (tube A) and complementary to the normal base corresponding to the mutation to be revealed ( tube B); the action of an exonuclease so that only the elongated probes are not degraded. The detection of the presence or absence of a mutation is carried out by direct or indirect revelation of the probe. Advantageously, all the stages of the method are carried out in the same tube (from PCR amplification to revelation) so that the presence of a mutation is revealed directly by the appearance of a coloration in the tube used for PCR (see Figure 1 ). The presence of the mutation can also be detected by other detection methods, in particular fluorescence, or by using radioactive probes (see below).

Thus, in a first aspect, the invention relates to a method for detecting a mutation located in position n in a target nucleic acid, characterized in that it comprises the following steps: a) amplification on at least two solid supports distinct A and B of the region of interest comprising said mutation using at least one primer linked in 5 'to the supports, b) dehybridization of the DNA strands and elimination of the strands in suspension by washing, c) hybridization a probe with the DNA strands linked to solid supports A and B, the 3 ′ end of said probe hybridizing at most to nucleotide n-1 of said strands, d) elongation reaction of the probe hybridized in step c) by incorporation in the 5'-3 'direction of nucleotides complementary to said DNA strands by means of a reaction mixture comprising a DNA polymerase and a nucleotide derivative resistant to degradation by an exonuclease (dNTP *), the reaction mixture uti used for support A comprising a dNTP * complementary to said mutation and the reaction mixture used for support B comprising a dNTP * complementary to the normal base corresponding to said mutation, e) degradation by said exonuclease so that only the probes extended to step d) are not degraded, washing, f) direct or indirect revelation of the non-degraded probe, said revelation being positive either in the case where the DNA strand on the support A contains the mutation, or in the case where the DNA strand on support B contains the normal base corresponding to said mutation. The binding of the 5 ′ primer to the supports (step a) is advantageously a sufficiently strong bond so that the DNA remains attached to the support during the various steps of the process. It can be a covalent bond, but also a non-covalent bond, such as an avidin-streptavidin / biotin bond, or an antibody / antigen type bond.

In step c), the probe hybridizing at most to the nucleotide n-1 of said strands means that the probe can also hybridize to n-2, n-3, n-4 ... It will then be necessary therefore provide, during the elongation step (d), the nucleotides complementary to the missing bases in order to allow the elongation of the probe to the mutated base for which the dNTP * is supplied.

A "probe" is defined as being a nucleotide fragment comprising for example from 10 to 100 nucleotides, in particular from 15 to 35 nucleotides, having a specificity of hybridization under determined conditions to form a hybridization complex with a target nucleic acid. The probes according to the invention can carry a labeling agent allowing or improving their detection.

Of course, the probe also serves as a primer in the context of the invention since the objective is to incorporate a nucleotide modified in position n corresponding to the position of the mutation that is sought. The 3 ′ end of the probe therefore ends at the maximum and preferably at n-1.

The probe can be marked by means of a marker chosen, for example, from radioactive isotopes, enzymes, in particular enzymes capable of acting on a chromogenic, fluorigenic or luminescent substrate (in particular a peroxidase or an alkaline phosphatase) or alternatively enzymes producing or using protons (oxidase or hydrolase); chromophoric chemical compounds, chromogenic, fluorigenic or luminescent compounds, nucleotitic base analogs, and ligands such as biotin. The labeling of the probes according to the invention is carried out by elements selected from ligands such as biotin, avidin, streptavidin, dioxygenin, haptens, dyes, luminescent agents such as radioluminescent, chemiluminescent, bioluminescent, fluorescent, phosphorescent agents. Another possibility is to label the probe with a peptide comprising an epitope recognized by a given antibody. The presence of this antibody can be revealed by means of a second labeled antibody.

In this method, the probe is advantageously labeled with one of the abovementioned molecules, said molecules allowing the direct or indirect appearance of a coloration when the non-degraded probe is present on the support, said coloration being preferably detectable by optical reading or simple observation. “Optical reading” means any measurement of absorption, transmission or emission of light which may possibly be at a specific wavelength either directly from DNA (260 nm for example), or from any marker molecule linked to the probe. This definition also includes any measurement of the fluorescence emitted by markers (fluorescein and / or phycoerythrin). Advantageously, therefore, in step f), the presence or absence of the mutation is detected either by optical reading, or by simple observation of a coloration on the solid support.

The solid support used to anchor the primer can be a plastic material (polystyrene, polycarbonate for example), or nylon or glass, so that this support is a tube, a membrane or a ball on which the region of interest is amplified for its analysis, that is to say the detection of a base change. Advantageously, the support is a tube (individual or in a bar or in a plate) used for amplification, and therefore compatible with the various thermal cyclers (Perkin Elmer 9700 for example). The tubes can also be any ELISA type tube or plate on which covalent attachment of nucleic acids can be carried out. Different methods of immobilizing an oligonucleotide on a support are possible and are described in particular in US 6,030,782. These methods can be a direct immobilization by chemical bond for example or an indirect immobilization (via a linker or a conjugate such as streptavidin for example).

In a preferred embodiment, supports A and B are tubes on which covalent attachment of nucleic acids can be carried out. Preferably, these tubes are Nucleolink ™ strips (NUNC, catalog reference No. 248259) which have a special coating allowing the direct covalent attachment of oligonucleotides by their 5 ′ phosphate end (Rasmussen, SR et al., Anal. Biochem , 198: 138-142 (1991)). The format of this process is thus the standard 96-well format (12 strips of 8 wells), but the strips being breakable, the desired number of tubes can be used. Other formats can be used, in particular if other fixing methods are used. For example, it is possible to attach the nucleic acids by disulfide bridge by following the method recommended in US 6,300,782.

Preferably used in step d) an αS-phosphothioatedésoxynucleotide, preferably αS-dATP, αS-dTTP, αS-dCTP, αS-dGTP, αS-dUTP or αS-dITP and in step e) an exonuclease, including exonuclease III. The term "exonuclease" means any natural or modified enzyme having an exonuclease activity. One can also consider the use of DNA polymerase having a pyrophophorolysis activity (in the presence of a high concentration of pyrophosphate, this enzyme adds a pyrophosphate on the last phosphodiester bond and therefore releases the nucleotide at 3 '. This product is available from Promega under the brand READIT ™, and variants using a luciferase revealing system is available under the brand READase ™. Generally, a well receives a DNA, then a probe and the incorporation of only one nucleotide (dNTP *) is allowed. Therefore, at least two tubes are required for each DNA to be tested, one receiving the normal base and the other receiving the mutated base.

Thus, the method described above is characterized in that two tubes are used, one being intended for the detection of the mutated base (tube A) and the other being intended for the detection of the normal base corresponding to said mutated base (tube B). Of course, several series of tubes A and B can be used, in particular in a 96-well plate and a tube C as a negative control for each series of tubes A and B. In the preferred embodiment, said dNTP * is an αS - phosphothioatedésoxynucleotide such as αS-dATP, αS-dTTP, αS-dCTP, αS-dGTP, αS-dUTP or αS-dITP which is incorporated at the 3 ′ end of the probe. This can be done for example by LCR, or preferably by asymmetric PCR. The αS-phosphothioatedésoxynucleotides can be easily incorporated into polynucleotides by all the polymerases and reverse transcriptases tested, which makes it possible to use DNA polymerases at a more advantageous cost price than in other detection of mutations. “DNA polymerase” is understood to mean any natural or modified enzyme having polymerase activity. Mention may be made, for example, of pol exo- DNAs, in particular T7 or the klenow fragment.

Advantageously, steps e) and f) are carried out simultaneously in the same reaction mixture comprising said exonuclease and the means necessary to reveal the coloration. These means depend on the marker or the ligand which is on the probe.

Another aspect of the invention relates to a device or kit making it possible to implement the method defined above.

Such a kit is characterized in that it includes: tubes A and B in which at least one primer making it possible to amplify the region comprising the specific mutation is linked in 5 ′ by a covalent bond, reaction mixtures A and B each comprising a different αS- phosphothioatedesoxynucleotide selected from αS-dATP, αS dTTP, αS-dCTP, S-dGTP, αS-dUTP and S-dITP, the reaction mixture used for support A comprising an αS-phosphothioatedésoxynucleotide complementary to said mutation and the reaction mixture used for support B comprising an S-phosphothioatedésoxynucleotide complementary to the normal base corresponding to said mutation. This kit can also comprise at least one element selected from an exonuclease, in particular exonuclease III, a reagent making it possible to reveal the coloration, a DNA polymerase and various buffers or solutions necessary for the implementation of the method.

Advantageously, the kit according to the invention comprises a series of tubes A and B, each series making it possible to detect a given mutation and tubes C as negative controls. Said tubes can be NUNC tubes.

In another aspect, the invention relates to the use of the method and the kit described above for the detection of gene mutations implicated in diseases, in particular in hereditary genetic diseases, in particular hemochromatosis, anemia sickle cell β and α thalassemia, cystic fibrosis, hemophilia, neurodegenerative diseases and mutations in the genes involved in cancer. An exhaustive list of mutations in these genes is given on the following website: ftp://ncbi.nlm.nih.gov/repositoι-v/OMIM/morbidιnap The method and the kit according to the invention are also useful for studying the polymorphism of genes or any genetic region and for the detection and / or identification of genetically modified organisms (GMOs).

legends

Figure 1A: PCR amplification in solid phase

Amplification of the genetic region of interest Figure 1B: denaturation The double strand of DNA is denatured, then the washes allow only the anchored strand to be preserved

Figure 1C: incorporation of a modified nucleotide

An enzymatic reaction catalyzes the elongation of a probe resulting in the insertion of a modified nucleotide, for example an αS-phosphothioatedésoxynucleotide at the 3 'end of the probe. Two reactions in the two tubes A and B are necessary for each sample with the incorporation of a single base to detect the normal genotypes (tube B) and / or mutants (tube A).

Figure 1D: detection

The elongated probe is protected from the degrading action of the exonuclease and a blue color develops during incubation with the substrate. The non-elongated probe is eliminated, no coloration is obtained. For example, detection can be performed with a FITC-labeled probe and an anti-labeled antibody.

FITC.

Figure 1E: very easy visual interpretation of the results The results for 4 series of tubes A and B (for 4 individuals or 4 different mutations in the same individual) are presented. Positive results are blue (dark gray in the text) and negatives are colorless. For each individual, whether mutated or normal, a coloration is obtained. In the case of heterozygote, a coloration is obtained in the two wells. Figures 2A and 2B: detection of C282Y and H63D mutations responsible for hemochromatosis.

Figure 3: primers used for the detection of mutations responsible for cystic fibrosis. F = "Forward" R = "Reverse"

(1) corresponds to the exon of the CFTR gene in which the mutation is found

(2) corresponds to the fixed oligonucleotide = primer B (3) corresponds to the modified nucleotide which will be incorporated during the extension: A = αS- dATP, T = αS-dTTP, C = S-dCTP, G = αS- dGTP

Figures 4A, 4B, 4C, 4D, 4E, 4F and 4G: detection of 7 mutations responsible for cystic fibrosis.

FIGS. 5A and 5B: detection of the C282Y and H63D mutations responsible for hemochromatosis (preferred method according to the invention in which the degradation and revelation steps are coupled).

Example 1: protocol for implementing the process according to the invention

The method according to the present invention makes it possible to determine the genotype of a sample, the latter being previously amplified using a primer fixed to the wall of the tube. The tubes used are the Nucleolink strips (NUNC), the fixing of the primer is carried out according to the indications of the supplier.

1. PCR amplification of the region of interest

In a tube containing the primer B previously fixed, introduce the different components in accordance with the different suppliers and allowing the amplifictaion of the region to be analyzed by asymmetric PCR: PCR buffers, dNTP, primer A 1 μM final, primer B 0.12 μM final, Taq polymerase and DNA to be tested. Note: The amplification products obtained in the liquid phase can be discarded or kept for analysis on a 1.5% agarose gel stained with ethidium bromide.

2. Dehybridization wash the well with distilled water; place 25 μl of 0.4M NaOH in each well and leave the plate for 5 minutes at room temperature; remove the soda and wash with distilled water.

3. Hybridization and elongation

Dispense 25 μl of N (normal) or M (mutant) hybridization solution into their respective tubes; these two solutions being composed of 0.05 μM probe, Bst DNA polymerase (Biolabs) 0.4 U, Bst 1 X buffer, Solution (SSC 2.5X - Blocking

0.25% reagent (Amersham) and differing only in the presence of modified dNTP

(dNTP *) 10 μM;

Incubate 15 minutes at 50 ° C.

4. Washes

Empty the wells and wash with 2.5% NaCl solution.

5. Enzymatic digestion - Place 25 μl of solution containing 0.01 U of Exonuclease III in its buffer per well (final concentrations: 50 mM Tris, 1 mM DTT, 10 mM MgC12); Incubate 10 minutes at 37 ° C.

6. Washes Empty the wells and wash with a PBS IX, T een 0.1% washing solution. 7. Revelation

- Add 25 μl of anti-FITC-POD antibody (Boehringer) l / 2000th in PBS-

BSA 3% in each well and leave at room temperature 10 minutes; - Empty the well and wash with a PBS IX, 0.1% Tween solution;

Deposit 25 μl of TMB substrate (Tetramethylbenzidine - Sigma) per well;

Incubate 15 minutes at room temperature;

It is possible to stop the reaction with 25 μl of H2SO4.

8. Results

Reading can then be done with the naked eye; a blue color appearing in the positive wells. It is also possible to read the optical density at 655 nm using a microplate reader or at 450 nm if the reaction has been stopped.

9. Interpretation of results

The genotype of a given sample can be determined: by reading with the naked eye: a blue color appears in the positive wells and the negative wells remain colorless. The four possible coloring benefits are described below:

Normal case

Case 2 Mutant

Case 3 Heterozygous

Case 4 Negative control

- by reading the optical density at 655 nm (or 450 nm if the reaction is stopped).

We determine the ratio R = [DO (N) / DO (M] If R> 2 then the genotype is Normal If 0.5 <R <2 then the genotype is Heterozygous If R <0.5 then the genotype is Mutant

Example 2: diagnosis of hemochromatosis, detection of mutations C282Y and H63D responsible for hemochromatosis.

1. PCR amplification of the region of interest In a tube containing the fixed primer B, introduce:

Final concentration

PCR buffer 10X I X

BSA 10 mg / ml 1 mg / ml

MgC12 50 mM 3 mM dNTP 10 mM 0.20 mM

Primer A 25 pmole / μl 0.5 μM

Primer B 3 pmole / μl 0.06 μM

Taq polymerase 5U / μl 0.02 U / μl

Sterile water qs 25 μl 11.9 μl

DNA to be tested 1 ng / μl

2. Dehybridization

3. Hybridization and elongation

Distribute 25 μl of N (normal) or M (mutant) hybridization solution in their respective tube, the solutions differing by αthiodGTP (normal base for C282Y and

H63D) in the case of the normal solution; αthiodATP (mutant base for C282Y) in the case of the C282Y mutant solution or αthiodCTP (mutant base for H63D) in the case of the H63D mutant solution.

Detection of the C282Y mutation:

Primers used:

- Primer A 5'CATGAAGTGGCTGAAGGATAA3 '(SEQ ID N ° l) - Primer B 5'GCACTCCTCTCAACCCCCA3' (SEQ ID N ° 2) - Probe marked FITC 5'FITC-GGAAGAGCAGAGATATACGT3 '(SEQ ID

# 3)

Normal case: incorporation of an αS-dGTP, region of SNP C282Y and its complementary region, included in the region amplified by the primers SEQ ID N ° 1 and SEQ ID N ° 2, the probe SEQ ID N ° 3 being underlined, the polymorphic base being in bold.

GGGAAGAGCAGAGATATACGTGATGAGAGT (SEQ ID N ° 4) CCCTTCTCGTCTCTATATGCACTACTCTCA (SEQ ID N ° 5)

Mutant case: incorporation of an αS-dATP, region of SNP C282Y and its complementary region, included in the region amplified by the primers SEQ ID No. 1 and SEQ ID No. 2, the probe SEQ ID No. 3 being underlined, the polymorphic base being in bold.

GGGAAGAGCAGAGATATACGTA CCCTTCTCGTCTCTATATGCATTACTCTCA (SEQ ID N ° 7)

Detection of the H63D mutation: Primers used:

- Primer A 5 'ACATCTGGCTTGAAATTCTACT3' (SEQ ID N ° 8)

- Primer B 5 'TCTCCAGGTTCACACTCTCT3' (SEQ ID N ° 9)

- Probe marked FITC 5 'FITC-CC AC ACGGCGACTCTC AT3' (SEQ ID N ° 10)

Normal case: incorporation of an αS-dGTP, region of SNP H63D and its complementary region, included in the region amplified by the primers SEQ ID No. 8 and SEQ ID No. 9, the probe SEQ ID No. 10 being underlined, the polymorphic base being in bold. TATGATCATGAGAGTCGCCGTGTGGAGCCC (SEQ ID No ll) ATACTAGTACTCTCAGCGGCACACCTCGGG (SEQ ID N ° 12)

Mutant case: incorporation of an αS-dCTP, region of SNP H63D and its complementary region, included in the region amplified by the primers SEQ ID No. 8 and SEQ ID No. 9, the probe SEQ ID No. 10 being underlined, the polymorphic base being in bold.

TATGATGATGAGAGTCGCCGTGTGGAGCCC (SEQ ID N ° 13) ATACTACTACTCTCAGCGGCACACCTCGGG (SEQ ID N ° 14)

The results are shown in Figure 2.

Example 3: Diagnosis of cystic fibrosis, detection of seven mutations responsible for cystic fibrosis.

Frequencies (%) * frequencies calculated from Cyctic Fibrosis Mutation Data Base February 2000 (http://www.genet.cikkids.on.ca/cftr/newfreq/All.html).

Primers and probes used (see Figure 3) Note: The protocol used and identical to the general description, the use of Nucleolink strips (NUNC) allows testing on a 96-well format 7 mutations in 6 people. The results are shown in Figure 4.

Example 4: Improvement of the protocol, coupling of the exonuclease digestion and revelation steps.

Steps 1 to 4 are identical to those of Example 1, only the following steps are modified so that digestion with Exonuclease III and revelation by the antibody are carried out in a single step. - Deposit per well 25 μl of solution containing 0.01 U of Exonuclease III (New England Biolabs) in its buffer, 2.5 μl of anti-FITC-POD antibody (Boehringer Mannheim) l / 200th in PBS-BSA 3 % and 0.25 μl Tween 20; Incubate 10 minutes at 37 ° C;

Perform 3 washes with washing solution PBS IX, Tween 0.1%; - Add 25 μl of TMB and incubate for 15 minutes at 37 ° C;

The results presented in Figure 5 are interpreted as shown in Example I.

Example 5: Improvement of the Protocol, Using a Streptavidin / Biotin System (Biotynilated Probe and Conjugated Streptavidin)

Steps 1 to 2 are identical to those of Example I, only the following steps are modified so that the final development is carried out using streptavidin, the probe having been previously coupled to a biotin. 3. Hybridization and elongation

Dispense 25 μl of N (normal) or M (mutant) hybridization solution into their respective tubes; these two solutions being composed of: 0.05 μM biotinylated probe, Bst polymerase (New England Biolabs) 0.4 U, Bst 10 X buffer: 2.5 μl, Solution (SSC 2.5 Blocking Reagent 0.25% (Amersham )) and differing only in the presence of the modified 10 μM dNTP. Incubate 15 minutes at 50 ° C.

4. Washes

Empty the wells and wash with a solution containing 2.5% NaCl.

5. Enzymatic digestion - Place 25 μl of solution containing 0.01 U of Exonuclease III (New England Biolabs) in its buffer per well; Incubate for 10 minutes at 37 ° C.

6. Washes

Empty the wells and perform 3 washes with PBS IX washing solution, 0.1% Tween.

7. Revelation

Add 25 μl of Streptavidin 1 mg / ml diluted to l / 2000th in PBS); Incubate for 10 minutes at room temperature.

8. Perform 3 washes with PBS IX washing solution, 0.1% Tween. 9. Add 25 μl of TMB and incubate for 15 minutes at 37 ° C.

10. Results and interpretation of the results as indicated in Example 1.

Claims

1. Method for detecting a mutation located in position n in a target nucleic acid, characterized in that it comprises the following steps: a) amplification on at least two distinct solid supports A and B of the region of interest comprising said mutation using at least one primer linked in 5 ′ to the supports, b) dehybridization of the DNA strands and elimination of the suspended strands by washing, c) hybridization of a probe with the DNA strands linked to solid supports A and B, the 3 'end of said probe hybridizing at most to nucleotide n-1 of said strands, d) elongation reaction of the probe hybridized in step c) by incorporation into the 5'-3 'direction of nucleotides complementary to said DNA strands by means of a reaction mixture comprising a DNA polymerase and a nucleotide derivative resistant to degradation by an exonuclease (dNTP *), the reaction mixture used for the support A including a complementary dNTP * of said mutation and the reaction mixture used for support B comprising a dNTP * complementary to the normal base corresponding to said mutation, e) degradation by said exonuclease so that only the probes elongated in step d) are not degraded , washing, f) direct or indirect revelation of the non-degraded probe, said revelation being positive either in the case where the DNA strand on the support A contains the mutation, or in the case where the DNA strand on the support B contains the normal base corresponding to said mutation.

2. Method according to claim 1 characterized in that the probe is labeled with molecules selected from enzymes, in particular enzymes capable of acting on a chromogenic, fluorigenic or luminescent substrate (in particular a peroxidase or an alkaline phosphatase), chromophoric chemical compounds, chromogenic, fluorigenic or luminescent compounds, nucleotitic base analogs, and ligands such as biotin, said molecules allowing the direct or indirect appearance of a coloration when the non-degraded probe is present on the support, said coloration being preferably detectable by optical measurement or simple observation.

3. Method according to one of claims 1 and 2 characterized in that one detects in step f) the presence or absence of the mutation either by optical reading, or by simple observation of a coloration on the solid support.

4. Method according to one of claims 1 to 3 characterized in that the supports A and B are tubes on which a covalent fixing of nucleic acids can be carried out, preferably tubes made of a plastic material such as polystyrene, or polycarbonate, in particular tubes of the Nucleolink ™ type.

5. Method according to one of the preceding claims, characterized in that in step d) an αS-phosphothioatedésoxynucleotide, preferably αS-dATP, αS- dTTP, αS-dCTP, αS-dGTP, αS-dUTP or aS-dITP.

6. Method according to one of the preceding claims, characterized in that in step e) exonuclease III is used.

7. Method according to one of the preceding claims, characterized in that two tubes are used, one being intended for the detection of the mutated base (tube A) and the other being intended for the detection of the corresponding normal base to said mutated base (tube B).

8. Method according to one of the preceding claims, characterized in that several series of tubes A and B are used, in particular in a 96-well plate.

9. Method according to one of the preceding claims, characterized in that a tube C is also used as negative control.

10. Method according to one of the preceding claims, characterized in that steps e) and f) are carried out simultaneously in the same reaction mixture comprising said exonuclease and the means necessary to reveal the coloration.

11. Device or kit for implementing the method according to one of the preceding claims, characterized in that it comprises: - tubes A and B in which at least one primer for amplifying the region comprising the specific mutation is linked in 5 ′ by a covalent bond, reaction mixtures A and B each comprising a different αS- phosphothioatedésoxynucleotide selected from αS-dATP, αS dTTP, αS-dCTP, αS-dGTP, αS-dUTP and αS-dITP, the mixture reaction mixture used for support A comprising an αS-phosphothioatedésoxynucleotide complementary to said mutation and the reaction mixture used for support B comprising an αS-phosphothioatedésoxynucleotide complementary to the normal base corresponding to said mutation.

12. Kit according to claim 11 characterized in that it further comprises at least one element selected from an exonuclease, in particular exonuclease III, a reagent for revealing the coloration, a DNA polymerase and various buffers or solutions necessary for the implementation of the process.

13. Kit according to one of claims 11 and 12 characterized in that it comprises a series of tubes A and B, each series making it possible to detect a given mutation.

14. Kit according to one of claims 11 to 13 characterized in that it further comprises tubes C as negative controls.

15. Kit according to one of claims 11 to 14 characterized in that said tubes are tubes made of a plastic material such as polystyrene, or polycarbonate, in particular tubes of the Nucleolink ™ type.

16. Use of the method according to one of claims 1 to 10 and of the kit according to one of claims 11 to 15 for the detection of gene mutations involved in diseases, in particular in hereditary genetic diseases, in particular hemochromatosis , sickle cell anemia, β and α thalassemia, cystic fibrosis, hemophilia, neurodegenerative diseases and mutations in the genes involved in cancer.

17. Use of the method according to one of claims 1 to 10 and of the kit according to one of claims 11 to 16 for the study of the polymorphism of genes or of any genetic region.

18. Use of the method according to one of claims 1 to 10 and of the kit according to one of claims 11 to 16 for the detection and / or identification of genetically modified organisms (GMOs).