EP3994277A1 - Method and test kit for bisulphite modification of dna - Google Patents

Abstract

The present application relates to a method and a test kit for carrying out a reaction for bisulphite modification of DNA in order to determine the patterns of methylation of the DNA, characterised in that, after a deamination reaction using bisulphite (e.g. sodium bisulphite or ammonium bisulphite) has taken place, the modified DNA is bound to a rough solid phase and all additional necessary method steps are carried out on this rough solid phase. Finally, the modified high-purity DNA is separated from this solid phase. The method can be carried out manually or automatically. The rough solid phase is a non-mineral material with a rough surface.

Description

METHOD AND TEST KIT FOR BISULFITE MODIFICATION OF DNA

The present application relates to a method and a test kit for carrying out a reaction for bisulfite modification of DNA to determine the

Methylation pattern of the DNA, characterized in that after

Deamination reaction using bisulfite (e.g. sodium bisulfite or

Ammonium bisulfite) the modified DNA is bound to a rough solid phase and all further necessary process steps are carried out on this rough solid phase. Finally, the modified, highly pure DNA is detached from this solid phase. The method can be carried out manually or automatically.

[0002] The rough solid phase is a non-mineral material with a rough surface. A rough surface is understood to be a non-smooth or structured surface of a material that is preferably made of metal, plastic or rubber. An arrangement of e.g. plastic granules in one

Cavity produce a structure which functions as a non-smooth surface and can therefore also be used according to the invention.

DNA methylation is an epigenetic mechanism that occurs in most

Organisms is found. Its main functions in prokaryotes are aimed at protecting against parasitic DNA and controlling the accuracy of replication. In

In vertebrates, the predominant methylation site is the 5-carbon of cytosine within the CpG dinucleotide sites. More than half of the genes contain short (~ 1 kb) CpG-rich regions called CpG islands, while the rest of the genome has no CpGs. While CpG sites in CpG islands are predominantly unmethylated, most CpG sites outside of CpG islands are normally methylated. The elucidation of the function of CpG methylation has proven difficult and appears to vary with context. The CpG methylation is on several

Fundamental mechanisms involved, i.e. in gene regulation, the inactivation of X chromosomes, the imprinting of genomes and the maintenance of

Chromosome stability. In addition, DNA methylation is an abnormal one

Characteristic of malignant tumors and represents an early event during carcinogenesis. In tumors, global genome methylation decreases (genome-wide

Hypomethylation), while several specific genes are methylated (gene-specific hypermethylation). Hypomethylation typically affects repetitive elements of DNA, while hypermethylation usually occurs within CpG islets. nowadays DNA methylation analysis has become an important tool for studying cancer, gene expression, genetic diseases, and many other important aspects of biology. The study of DNA methylation is also in the

medical diagnostics have become increasingly important.

Most of the techniques for studying DNA methylation depend on a previous deamination of cytosine using bisulfite (sodium bisulfite or

Ammonium bisulfite). In the presence of bisulfite, unmethylated cytosine is converted to uracil, while methylated cytosine is not affected. Accordingly, the epigenetic information is converted into DNA sequence information and can therefore be determined by standard molecular biological methods such as PCR and DNA sequencing.

This is currently achieved by the "bisulfite modification" technique described by Frommerm M., et al., Proc Natl Acad Sci U S A 89 (1992) 1827-31. In this protocol, DNA was denatured with NaOH and then incubated for 16 hours in the presence of 3.1 M sodium bisulfite and 0.5 M hydroquinone to obtain a

Achieve deamination of cytosine to uracil while leaving methylated cytosine unaffected. The epigenetic information of the DNA in

Converted sequence information that can be examined via PCR and other hybridization-based methods. Recently, several technical improvements to the bisulfite methods have been developed WO 01/98528 (DE 100 29 915; US Application 10 / 311,661), EP 1 294 945 B1, US 7,118,868 B2, US 7,968,295 B2, US

8,241,855 B2, US 8,257,950 B2. These patents describe a bisulfite conversion in which the DNA is incubated with a bisulfite solution having a concentration range between 0.1 mol / 1 to 6 mol / l in the presence of a denaturing reagent and / or solvent and at least one radical scavenger. Several suitable denaturing reagents and free radical scavengers are described in this patent application.

In US 9,868,756 B2, DNA is bound to a surface on the basis of a silicate material after the bisulfite treatment. The following steps (washing the bound DNA, desulphonation of the DNA, further washing steps) take place on the solid phase. This material (solid phase) is a glass fleece or a glass membrane, magnetic glass particles or hydroxyapatite. In the

In patent specification EP 1394173, the DNA is bound to a mineral solid phase with a bisulfite reagent before incubation and all steps for bisulfite modification (deamination, washing steps, desulfonation, washing steps) take place on the solid phase. This material is also a glass tile or a glass membrane magnetic glass particles or hydroxyapatite. In US 9,868,756 B2 it is explicitly described in column 6, lines 15-18 that paramagnetic substances are not suitable for the implementation. ("Paramagnetic substances are not useful as they are only drawn to a magnetic very weakly which is not sufficient for a method according to this invention.")

[0007] These materials all embody what are known as mineral solid phases. It follows from this that, according to the known state of the art, the mineral properties of the solid phase - including the pores which these materials form - are decisive for the binding of the bisulfite-treated DNA.

These processes can be performed relatively easily manually. However, the automated implementation is extremely difficult. In addition, the solid phases used are expensive and, in particular with magnetic glass particles, also have the problem that they are often very difficult to separate or often clump together, which has a strong negative effect on the efficiency of the bisulfite modification.

The prior art also includes the document WO 2004/053115 A1. This describes a method and kit for isolating a target cell, a cell organelle or a virus from a sample, using, inter alia, a non-specific or little specific binding between a target cell, a cell organelle or a virus with a magnetic microsphere.

Object of the invention

[0010] The object of the invention was to eliminate the disadvantages of the solutions described in the prior art. The aim of the present invention was to provide a

To provide a method for bisulfite modification of DNA, which is easy to carry out and which should be ideally suited in particular for automated implementation and in this context completely dispenses with known mineral materials for binding and bisulfite modification of DNA.

Solution of the task

The object was achieved according to the features of the patent claims.

The present invention achieves these objects in all of the points defined. The essence of the invention is the knowledge that free nucleic acids or nucleic acids released by lysis can be bound to a solid phase with a rough surface under specific binding conditions, where they are washed and finally eluted from this rough surface. The term "rough surface" is to be understood as meaning that by touching the

Surface can be seen that it is not smooth (laid-open specification WO 2016/169677 Al). Materials made of plastic, metal or non-metal can preferably be used as non-mineral solid phases. Non-mineral solid phases in the sense of this

Invention are materials that do not consist of glass, silicon dioxide, an ion exchanger or hydroxyapatite. An arrangement of per se non-rough materials in a cavity can also lead to the creation of a “rough” or structured surface due to corners or edges being formed.

The term "rough surface" is to be understood in such a way that by touching or looking at the surface it can be seen that it is not smooth. However, it can also be a surface that has a structure (e.g. grooves). This structure removes the smoothness of the surface, even if the structure, i.e. the grooves, itself can be smooth. According to the invention, such surfaces are referred to as “structured surfaces”. If it is not possible to tell whether a surface is smooth or rough by looking at or touching the surface, a test can be carried out in which a laser beam is aimed at that surface. If the surface is smooth, the laser will only work in

Main direction reflected on the surface. In the case of rough surfaces, scattering occurs in all spatial directions. Such a test has been described on the website of the University of Kiel (http: //www.tf.uni- kiel.de/ matwis / amat / semitech_en / kap_3 / illustr / oberflaechenstrukture.pdf), page 7.

Surprisingly, it was found that after the deamination reaction, all further process steps necessary for bisulfite modification of DNA, which were previously carried out using mineral solid phases, can be carried out very easily and quickly using the rough surfaces. Given the

Disclosure of WO 2016/169677 A1, this was by no means to be expected, since there it was pointed out in paragraph [0012] that an elution of the bound nucleic acids from the solid phase is possible by means of a low salt buffer. It would therefore also have been possible for the bisulfite to act like such a low salt buffer and prevent the attachment to a non-mineral solid phase. It is all the more surprising that the known reagents for the bisufite modification of the DNA can be retained.

Ideally, the process can be carried out both manually and automatically. With regard to automated bisulfite modification of DNA, there are currently no suitable solutions.

The manual method according to the invention for bisulfite modification of DNA is carried out in a preferred variant as follows. Instead of classic mineral ones Materials for binding the DNA are plastic granules with a rough surface, which are preferably paramagnetic. Several plastic granulates, the surface of which has been mechanically roughened (size approx. 1-2 mm x 0.5-1 mm), are placed in a 2.0 ml reaction vessel for this purpose. The bisulfite modification reaction (deamination and / or desulfonation step as well as necessary washing steps) are carried out with reagents from a commercially available kit for bisulfite modification of DNA (innuCONVERT Bisulfite Basic Kit; Analytik Jena AG). By means of the novel solid phase according to the invention based on a rough surface, the following process steps are carried out:

1. After bisulfite treatment of a DNA by mixing the DNA with the

Reagents from the commercial kit (Conversion Reagent and Conversion Buffer) and a subsequent incubation of the reaction mixture at 85 ° C. for 45 minutes, the reaction mixture is transferred to the 2.0 ml reaction vessel with the granules. The binding of the DNA to the surface of the rough plastic granulate is initiated by adding a binding buffer, which contains an alcoholic component and other additives, or by adding just one alcohol. After a short incubation, the supernatant is removed from the plastic granulate by placing the reaction vessel in a magnetic trap.

2. The bound modified DNA is washed with an alcoholic washing buffer

washed and the washing buffer then completely removed.

3. The desulfonation reaction of the DNA bound to the plastic granulate follows.

For this purpose, a desulfonation buffer is added to the reaction vessel with the granulate

(innuCONVERT Bisulfite Basic Kit; Analytik Jena AG) was added and the mixture was incubated for a few minutes. After the incubation period, the supernatant is completely removed from the plastic granulate.

4. This is followed by further washing steps with alcoholic washing buffers and then the drying of the plastic granulate.

5. The modified DNA is finalized by adding a low salt buffer from

Granules according to the invention detached.

As the method according to the invention shows in its manual variant, it is possible in a simple manner that after treating a DNA with a

Bisulfite reagent all process steps necessary for a bisulfite modification of DNA are of the kind that none of the previously used mineral

Materials in the form of glass fleece or glass membrane, glass particles or hydroxyapatite are needed more. The use of plastic material, the surface of which has a roughness, is sufficient for all necessary process steps.

The means and method according to the invention also reveal further advantages. For the processing of larger sample volumes, it is necessary to parallelize processes and, in the most effective case, to automate them. With regard to the process of bisulfite modification of DNA, there are a large number of commercially available products for manual processing, but very few products for processing large sample sizes. Automated solutions cannot be found commercially and must be implemented individually by users on automation platforms.

[0017] Methods for parallel sample processing are based on the use of

magnetic glass particles on which the bisulfite modification reaction takes place.

It is known that the handling of magnetic particles requires multiple process steps and, in particular, the respective step of the magnetic separation of the particles is time-consuming. In addition, these particles are very expensive.

Surprisingly, it has been shown that the agent according to the invention is ideally suited to carry out an automated bisulfite modification of DNA.

In a preferred embodiment variant, the material with the rough surface is located within a pipette tip, so that reagents can flow past this material. For example, the same material that was used for manual bisulfite modification can also be placed in a pipette tip.

[oo2i] After the bisulfite treatment of the DNA has taken place, all further steps of the bisulfite modification process are carried out automatically within a pipette tip, the DNA being bound to the surface of the rough material of the invention.

The method according to the invention runs in the form of a "walk-away process" as follows:

1. After bisulfite treatment of a DNA by mixing the DNA with the reagents from the commercial kit (Conversion Reagent and Conversion Buffer) and a subsequent incubation of the reaction mixture at 85 ° C. for 45 minutes, a binding buffer is added to the reaction mixture. 2. The reaction mixture is mixed with an alcohol and / or an alcohol and other components. The mixture is drawn up with a pipette tip, in which the rough material is arranged vertically, and the liquid is moved past the rough material by repeatedly pipetting up and down. After the last pipetting out, the pipette tip according to the invention is empty. The previously bisulfite-treated DNA is now on the surface of the rough plastic granulate in the pipette tip.

3. Remove the pipette tip according to the invention from the sample.

4. Immersing the pipette tip according to the invention in a washing buffer solution.

Repeated pipetting up and down (the liquid moves past the material). After the last pipetting out, the pipette tip according to the invention is empty. 5. The desulphonation reaction of the DNA bound to the plastic granulate then takes place inside the pipette tip. This is done by pipetting up and down a desulfonation buffer (innuCONVERT Bisulfite Basic Kit; Analytik Jena AG).

6. This is followed by further washing steps with alcoholic washing buffers and then the drying of the plastic granulate, always only by repeatedly opening and closing

Pipette off.

7. Finally, the modified DNA is detached from the granulate according to the invention by adding a low salt buffer

The materials selected and placed vertically in the pipette tip for binding the bisulfite-treated DNA for all further necessary process steps can be extremely different. Rough materials can be used, modified plastic materials whose surfaces are not smooth but structured. This also includes so-called composite materials, which are mixtures of polymers and, for example, organic components or metallic components. It is only essential to provide a roughened or structured surface (not a smooth

Surface). The architecture of the plastic material is also not limiting (round, rectangular, etc.). It is only important that the material can be brought into a pipette tip and also remains in this position and that a liquid can be washed around it at any time without the liquid having to pass through the material introduced.

A pipette tip can also be used in which there is (from an injection molded part manufactured) that the binding material is already in place and no longer has to be brought into the tip.

Surprisingly, a further automated bisulfite modification can also be carried out. No pipette tip is used here.

A device platform that is a commercially available magnetic particle processor (e.g. KingFisher Flex for DNA / RNA extraction and processing of 96 samples) is used and misappropriated.

It is a device for extracting nucleic acids by means of magnetic particles. The device uses plastic combs into which magnetic bars move, which then move magnetic particles in a walk-away process and immerse them in the buffers required for a standard extraction. These plastic combs were used for the method according to the invention for purposes other than those intended by their lower end being mechanically roughened. The method according to the invention for bisulfite modification of DNA was then implemented automatically by means of the device. In contrast to the

This time, the pipette tip variant binds the DNA to the rough surface of the plastic combs and goes through all the necessary steps following the initial deamination reaction in a walk-away workflow. The procedure is extremely simple and allows up to 96 samples to be processed in parallel.

The present invention thus ideally enables the implementation of the objective already mentioned. The method of bisulfite modification of DNA including all the necessary process steps does not require any mineral materials known from the prior art, but only roughened surfaces.

With the invention, a completely new platform technology for the bisulfite modification of DNA is available, which has a number of very clear advantages over the known methods which use mineral materials for the method. In particular, the automated implementation is quick and easy for the first time.

The invention is explained below using examples, the

The examples listed do not represent limitations of the invention.

Working examples Example 1:

Automated bisulfite modification of DNA by means of a pipette tip with contained rough plastic granules and using a commercially available automatic extraction device

The automated bisulfite modification was carried out with the InnuPure C16 automatic extraction device (Analytik Jena AG). This automatic extraction system is based on a magnetic particle nucleic acid extraction, but was used for the process “for a different purpose” without magnetic particles.

For carrying out the reaction, the inventive rough

Plastic material placed in the lower third of a 1 ml pipette tip vertical. The reagents necessary for the bisulfite modification of the DNA were partly taken from the commercially available kit (innuCONVERT Bisulfite Basic Kit; Analytik Jena AG).

For the bisulfite modification, 5 pg of genomic DNA with 70 ml conversion reagent and 30 ml conversion buffer (innuCONVERT Bisulfite Basic Kit; Analytik Jena AG) was mixed in a 2.0 ml reaction vessel and mixed for 45 minutes at 85 ° C and 800 rpm incubated.

During the incubation, a deep well plate was filled with the following reagents:

Well 1: 250 mΐ ethanol

Well 2: 1 ml Washing Solution HS (Analytik Jena AG)

Well 3: 1 ml Desulfonation Buffer (innuCONVERT Bisulfite Basic Kit; Analytik Jena AG)

Cavity 4: 1 ml Washing Solution LS (Analytik Jena AG)

Well 5: 1 ml 80% ethanol

Well 6: 1 ml 80% ethanol

Well 7: 100 mΐ Elution Buffer (innuCONVERT Bisulfite Basic Kit; Analytik Jena AG)

The reaction mixture described above was given after the incubation in the cavity 1, which was filled with 250 mΐ 99.8% ethanol. A further 5 ml Binding Optimizer (Analytik Jena AG) were added to this reaction mixture. The automated process was then carried out on the Innupure CI 6.

The reaction mixture of the cavity 1 was carried out by means of the

Mix the pipette tip by pipetting up and down in such a way that the solution is on the side the rough plastic granules introduced into the tip flows past. 100 repetitions were performed. In this step, the bisulfite-modified DNA binds to the rough plastic surface of the granules placed in the pipette tip. After binding the DNA, the bound DNA was washed. This was done in cavity 2, which was filled with an alcoholic washing buffer (Washing Solution HS). Washing was carried out by pipetting up and down 10 times.

For the desulfurization reaction, the DNA bound to the rough plastic granules was brought into contact with desulfonation buffer (4 times AuF and pipetting off). An incubation time of 2 minutes with Desulfonation Buffer was observed for each pipetting step.

The DNA bound to the plastic granules was then washed successively in three additional cavities containing alcoholic washing buffers (Washing Solution LS, 80% ethanol, 80% ethanol) by pipetting in and out.

Following the last washing step, the tip according to the invention and the rough plastic granules contained in it were dried by pipetting air in and out 60 times and the remaining ethanol was thus removed. The nucleic acids were eluted by pipetting the AuF 150 times and pipetting off with 100 ml elution buffer which had previously been tempered to 50 ° C. by the device. The total volume of elution BuFfer was 100 m³.

The process is extremely simple and quick and shows that commercially available

Automatic extraction machines can be used for carrying out the method according to the invention with the agent according to the invention corresponding thereto. The time required compared to a spin column-based extraction is less.

In order to compare the method according to the invention with a commercially available product based on mineral materials, a bisulfite modification kit (based on spin filter columns) from Stratec Molecular (InviGene Bisulfite Conversion Kit) was tested. The instructions as described in the kit manual were followed exactly.

After bisulfite modification reactions had been carried out, successful bisulfite modification was detected by means of various real-time PCR assays.

A real-time PCR assay specific for the actin beta gene locus was used to quantify the total amount of bisulfite-modified DNA. The Actin Beta gene locus does not contain any CpG sites, therefore, after the bisulfite modification reaction, all cytosines from this gene locus are converted into uracils and these are detected as thymines in a real-time PCR assay. This assay was used to verify that the genomic DNA is bisulfite modified.

The following primers and Taq-man probes were used for this.

Forward primer: 5'-CCCTTAAAAATTACAAAAACCACAA-3 '

Reverse Primer: 5'- GG AGG AGGTTT AGT AAGTTTTTT G -3 '

Taq-man probe: 5 '-F AM- ACC ACC ACCC AACACAC AAT AACAAAC ACA-BHQ- 1 -3'

Real-time PCR approach:

Forward primer (50 pmol / mΐ): 0.1 mΐ

Reverse primer (50 pmol / mΐ): 0.1 mΐ

Taq-man probe (25 pmol / mΐ): 0.1 mΐ

InnuMIX qPCR MasterMix Probe (Analytik Jena): 7.5 mΐ

Bisulfite-modified or genomic DNA: 1.5 mΐ

PCR grade H ₂ 0: 5.7 mΐ

The real-time PCR was carried out in the CFX96 real-time system by the company Biorad.

Amplification conditions:

Step 1: Denaturation 95 ° C / 120 "

Step 2: amplification 40 cycles (95 ° C / 4 "; 57 ° C / 40")

FIG. 1 shows a real-time PCR from the β-actin assay. (gray curves: genomic DNA, magenta curves: no template control; blue and green curve samples DNA after the respective bisulfite modification reaction).

The results show that the genomic DNA could be successfully modified using the automated method with the InnuPure CI 6 extraction machine and a rough plastic material according to the invention and that the recovery rate of the modified DNA was significantly better than in the comparative method from Stratec Molecular .

The cytosine free flagment (CFF-1) assay amplifies genomic and bisulfite-modified DNA with the same efficiency and is therefore suitable for quantifying the yield of bisulfite-modified DNA. It enables the direct comparison of input DNA and output DNA of the bisulite modification reaction. In the case of genomic DNA, the sense and the antisence strand serve as templates. In contrast, only the sense strand serves as a template in bisulfite-modified DNA, because the antisense strand (contains cytosines) is not available for the amplification reaction after the bisulfite modification.

That is why there is a theoretical loss of one Ct value for bisulfite-modified DNA, since the template is halved after the bisulfite modification.

The sequence of the primem and Taq-man probe are as follows. Forward primer: 5 '-T AAG AGT AAT AATGGATGG ATG ATG-3'

Reverse Primer: 5'-CCTCCCATCTCCCTTCC-3 '

Taq-man probe: 5'- F AM- ATGGATG AAGAAAGAAAGGATG AGT-BHQ- 1 -3 'Real-Time PCR approach:

Forward primer (50 pmol / m²) 0.1 m²

Reverse primer (50 pmol / mΐ) 0.1 mΐ

Taq-man probe (25 pmol / mΐ) 0.1 mΐ

InnuMIX qPCR MasterMix Probe (Analytik Jena) 7.5 mΐ

Bisulfite-modified e or genomic DNA 1.5 mΐ

PCR grade H ₂ 0 5.7 mΐ

The real-time PCR was carried out in the CFX96 real-time system by Biorad: Amplification conditions:

Step 1: Denaturation 95 ° C / 120 "

Step 2: amplification 40 cycles (95 ° C / 4 "; 52 ° C / 40")

FIG. 2 shows a real-time PCR from the CFF-1 assay. (magenta curves: No.

Template control; gray curves: genomic DNA; blue and green curves samples DNA after bisulfite modification reaction). Here, too, the results are better than with the comparison procedure. As a further analysis, a CFP 415 bp assay (cytosine-ffee primer binding site) was carried out with bisulfite-modified DNA. Since this assay is used to amplify long DNA sequences, this assay provides information about the degraded DNA during the bisulfite modification and during the purification of bisulfite-modified DNA. The sequences from the primers are as follows:

Forward primers: 5 ATGGGT AAGGAT ATG AAGTT AAT-3 '

Reverse Primer: 5'- TATCACTTAATCACCTCCTAAACTA-3 '

Real-time PCR approach:

Forward primer (50 pmol / m²): 0.1 m²

Reverse primer (50 pmol / mΐ): 0.1 mΐ

innuMix qPCR DSgreen Standard (Analytik Jena): 7.5 mΐ

Bisulfite-modified e or genomic DNA: 1.5 mΐ

PCR grade H ₂ 0: 5.8 mΐ

The real-time PCR was carried out in the CFX96 real-time system from Biorad:

Amplification conditions:

Step 1: Denaturation 95 ° C / 120 "

Step 2: Amplification 40 cycles (95 ° C / 4 "; 58 ° C / 40")

FIG. 3 shows a real-time PCR of the CFP 415 bp assay. (magenta curves: No Template Control, green and blue curves: samples DNA after

Bisulfite modification reaction).

The results show less degraded DNA after the bisulfite modification with automated implementation with the InnuPure CI 6 in comparison with the spin filter-based kit from Stratec Molecular.

As the results show, it is possible with the agent according to the invention and the method according to the invention, using only standard reagents which are used for carrying out bisulfite modification reactions, by means of fewer pipetting steps with an automatic pipetting device, which is normally with Magnetic particles works to bind bisulfite-modified DNA, to desulfonate and purify it. It can be seen that the yields are almost 100% and thus significantly better results can be achieved compared to commercial products. Embodiment 2: Automated bisulfite modification of DNA using a KingFisher Flex magnetic particle processor and the use of roughened plastic combs

The automated purification was done with the magnetic particle processor

KingFisher Flex (ThermoFisher Scientific). Used this instrument

Plastic combs into which magnetic rods penetrate and which then move magnetic particles in a walk-away process, which are used to isolate nucleic acids. These plastic combs were used outside of their normal intended use to carry out the fiction, contemporary method. The plastic material of the combs is polypropylene. According to the invention, the plastic combs were roughened using a grinding machine. The reagents used for bisulfite modification of the nucleic acids were partly taken from the commercial kit “innuCONVERT Bisulfite Basic Kit”; Analytik Jena AG, taken. For the bisulfite modification 5 gg of genomic DNA with 70 mΐ conversion

Reagent and 30 ml Coversion Buffer (innuCONVERT Bisulfite Basic Kit; Analytik Jena AG) mixed together in a 2.0 ml reaction vessel and incubated for 45 minutes at 85 ° C and at 800 rpm. During the incubation, the deep well plates were for use in

KingFisher Flex machines filled with the following reagents:

Deep well plate 1: 250 ml ethanol

Deep well plate 2: 1 ml Washing Solution HS (Analytik Jena AG)

Deep well plate 3: 1 ml desulfonation buffer (innuCONVERT Bisulfite Basic Kit; Analytik Jena AG)

Deep well plate 4: 1 ml Washing Solution LS (Analytik Jena AG)

Deep well plate 5: 1 ml 80% ethanol

Deep well plate 6: 1 ml of 80% ethanol

Deep well plate 7: 100 ml Elution Buffer (innuCONVERT Bisulfite Basic Kit; Analytik Jena AG)

The reaction mixture described above was after the incubation in the cavity 1 given, which was filled with 250 mΐ 99.8% ethanol. A further 5 ml Binding Optimizer (Analytik Jena AG) were added to this reaction mixture. The automated process was then carried out on the KingFisher Flex machine.

The reaction mixture of cavity 1 was mixed by means of the rough plastic combs according to the invention by repeating vertical movements (moving in and out within the deep well plate cavity). In this step, the bisulfite-modified DNA binds to the rough plastic surface of the plastic combs. After binding of the DNA, it was washed by vertical movement of the comb in the cavity of the deep well plate 2 with the Washing Solution HS (Analytik Jena AG) contained therein

For the desulfonization reaction, the rough plastic combs were slowly moved vertically up and down in desulfonation buffer for 8 minutes.

The bisulfite-modified DNA bound to the rough plastic combs was then successively transferred to three further deep-well plates containing alcoholic washing buffers (Washing Solution FS, 80% ethanol, 80% ethanol), each for 30 seconds washed slowly moving up and down vertically.

After the last washing step, the plastic combs were dried on the foot for 10 minutes and the remaining ethanol was removed. The bisulfite-modified DNA was eluted from the rough plastic combs by moving the plastic combs vertically for 10 minutes in elution buffer, which had previously been heated to 80 ° C. by the device. The total volume of elution buffer was 100 ml.

The method is extremely simple and fast and shows that with the commercially available automatic extraction KingFisher Flex an automated bisulfite modification of up to 96 sample DNAs can be carried out in parallel by modifying the plastic combs alone. The modified DNA was again analyzed using various real-time PCR assays. The kit from Stratec Molecular (InviGene Bisulfite Conversion Kit), which works on the basis of mineral solid phases, was again included as a comparative product.

After bisulfite modification reactions had been carried out, successful bisulfite modification was verified using various real-time PCR assays.

A real-time PCR assay specific for the actin beta gene locus was used to quantify the total amount of bisulfite-modified DNA. The Actin Beta gene locus does not contain any CpG sites, so all cytosines from this gene locus are converted into uracils after the bisulfite modification reaction and these are detected as thymine in a real-time PCR assay. This assay was used to check whether the genomic DNA was bisulfite-modified.

The following primers and Taq-man probes were used for this. Forward primer: 5'-CCCTTAAAAATTACAAAAACCACAA-3 '

Reverse Primer: 5'- GG AGG AGGTTT AGT AAGTTTTTT G -3 '

Taq-man probe: 5 '-F AM- ACC ACC ACCC AACACAC AAT AACAAAC ACA-BHQ- 1 -3'

Real-T ime-PCR approach:

Forward primer (50 pmol / m²): 0.1 m²

Reverse primer (50 pmol / mΐ): 0.1 mΐ

Taq-man probe (25 pmol / mΐ): 0.1 mΐ

InnuMIX qPCR MasterMix Probe (Analytik Jena): 7.5 mΐ

Bisulfite-modified or genomic DNA: 1.5 mΐ

PCR grade H ₂ 0: 5.7 mΐ

The real-time PCR was carried out in the CFX96 real-time system from Biorad.

Amplification conditions:

Step 1: Denaturation 95 ° C / 120 "

Step 2: amplification 40 cycles (95 ° C / 4 "; 57 ° C / 40")

FIG. 4 shows a real-time PCR from the β-actin assay. (gray curves: genomic DNA, magenta curves: no template control; blue and green curve samples DNA after the respective bisulfite modification reaction).

The results show that the genomic DNA could successfully be subjected to bisulfite modification of DNA using the automated method with the KingFisher Flex automatic extraction device and the roughened plastic combs. The process according to the invention is better in terms of performance than the commercially available comparison process.

The cytosine free fragment (CFF-1) assay amplifies genomic and bisulfite-modified DNA with the same efficiency and is therefore suitable for quantifying the yield of bisulfite-modified DNA. It enables the direct comparison of input DNA and output DNA of the bisulite modification reaction. In the case of genomic DNA, the sense and the antisence strand serve as templates. In contrast, only the sense strand is used for bisulfite modified DNA as a template because the antisense strand (contains cytosines) is not available for the amplification reaction after the bisulfite modification. That is why there is a theoretical loss of one Ct value for bisulfite-modified DNA, since the template is halved after the bisulfite modification.

The sequence of the primers and the Taq-man probe are as follows.

Forward Primer: 5'- TAAGAGT AATAATGGATGGATGATG-3 '

Reverse Primer: 5'-CCTCCCATCTCCCTTCC-3 '

Taq-man probe: 5'- F AM- ATGGATG AAGAAAGAAAGGATG AGT-BHQ- 1 -3 '

Real-time PCR approach:

Forward primer (50 pmol / m²) 0.1 m²

Reverse primer (50 pmol / mΐ) 0.1 mΐ

Taq-man probe (25 pmol / mΐ) 0.1 mΐ

InnuMIX qPCR MasterMix Probe (Analytik Jena) 7.5 mΐ

Bisulfite-modified e or genomic DNA 1.5 mΐ

PCR grade H ₂ 0 5.7 mΐ

The real-time PCR was carried out in the CFX96 real-time system from Biorad:

Amplification conditions:

Step 1: Denaturation 95 ° C / 120 "

Step 2: amplification 40 cycles (95 ° C / 4 "; 52 ° C / 40")

FIG. 5 shows a real-time PCR from the CFF-1 assay. (magenta curves: No.

Template control; gray curves: genomic DNA; blue and green curves samples DNA after bisulfite modification reaction).

A CFP 415 bp assay (cytosine-ffee primer binding site) with bisulfite-modified DNA was carried out as a further analysis. Since this assay is used to amplify long DNA sequences, this assay provides information about the degraded DNA during the bisulfite modification and during the refinement of bisulfite-modified DNA. The sequences from the primers are as follows: Forward primers: 5 ATGGGT AAGGAT ATG AAGTT AAT-3 '

Reverse Primer: 5'-TATCACTTAATCACCTCCTAAACTA-3 '

Real-time PCR approach:

Forward primer (50 pmol / m²): 0.1 m²

Reverse primer (50 pmol / mΐ): 0.1 mΐ

innuMix qPCR DSgreen Standard (Analytik Jena): 7.5 mΐ

Bisulfite-modified or genomic DNA 1.5 mΐ

PCR grade LEO: 5.8 mΐ

The real-time PCR was carried out in the CFX96 real-time system from Biorad

carried out:

Amplification conditions:

Step 1: Denaturation 95 ° C / 120 "

Step 2: Amplification 40 cycles (95 ° C / 4 "; 58 ° C / 40")

FIG. 6 shows a real-time PCR of the CFP 415 bp assay. (magenta curves: No Template Control, green and yellow curves: samples DNA after

Bisulfite modification reaction).

The results show less degraded DNA after the bisulfite modification by means of the method according to the invention in comparison to the commercial product.

Exemplary embodiment 3: Manual bisulfite modification using paramagnetic

Plastic granules with a roughened surface finish

For the manual implementation of the bisulfite modification reaction by means of the method according to the invention, 4 mechanically roughened paramagnetic plastic granules were placed in a 2.0 ml reaction vessel.

The chemicals used for the bisulfite modification of the nucleic acids were partly taken from the commercial extraction kit innuCONVERT Bisulfite Basic Kit; Analytik Jena AG taken.

For the bisulfite modification 5 gg of genomic DNA with 70 ml conversion reagent and 30 ml conversion buffer (both solutions from the innuCONVERT Bisulfite Basic Kit; Analytik Jena AG) mixed in a 2.0 ml reaction vessel and incubated for 45 minutes at 85 ° C and at 800 rpm.

After the bisulfite modification had taken place, the reaction mixture was transferred into the 2.0 ml reaction vessel with the plastic granules. To bind the DNA to the plastic granules, 250 ml of 99.8% ethanol and 5 ml of Binding Optimizer (Analytik Jena AG) were added and the vessel was shaken for 10 minutes at room temperature and at 1400 rpm.

After the incubation, the 2.0 ml reaction vessel was placed in a magnetic trap, the paramagnetic granules were separated and the supernatant was removed

This was followed by the addition of 1 ml Washing Solution HS (Analytik Jena AG). The jar was inverted three times. The reaction vessel was left in the magnetic trap. The supernatant was then removed from the plastic granules.

The desulfonation reaction of the DNA bound to the plastic granules then took place. For this purpose, 1 ml desulfonation buffer (innuCONVERT Bisulfite Basic Kit; Analytik Jena AG) was added to the 2.0 ml reaction vessel with the plastic granules and incubated for 10 minutes at room temperature without shaking. After the incubation period, the supernatant was completely removed from the plastic granules. For this purpose, the reaction vessel was left in the magnetic trap.

1 ml Washing Solution C (buffer from innuCONVERT Bisulfite Basic Kit; Analytik Jena AG) was added to the 2.0 ml reaction vessel with the plastic granules, and the reaction vessel was inverted three times. The 2.0 ml reaction vessel remained in the magnetic trap. The supernatant was then removed from the plastic granules.

This was followed by three further washing steps with alcohol-containing washing buffers, 1 ml Washing Solution BS (innuCONVERT Bisulfite Basic Kit; Analytik Jena AG), 1 ml of 80% ethanol and 1 ml of 80% ethanol.

After the last washing step, the 2.0 ml reaction vessel with the plastic granules was incubated at 65 ° C. for 10 minutes and 500 rpm with the lid open in order to remove the remaining alcohol.

Finally, the bisulfite-modified DNA was detached from the plastic granulate according to the invention by adding elution buffer (innuCONVERT Bisulfite Basic Kit; Analytik Jena AG). For this, 100 ml of elution buffer were added to the plastic granules and the reaction vessel was incubated for 10 minutes at 65 ° C. and at 500 rpm.

The 2.0 ml reaction vessel with the plastic granules was placed in a magnetic trap, the granules were separated and the eluate was transferred to a new 2.0 reaction vessel. The Spin Filter column-based extraction kit from Stiatec (InviGene Bisulfite Conversion Kit) was used for comparison. The instructions as described in the kit manual were followed exactly. After bisulfite modification reactions had been carried out, successful bisulfite modification was detected using various real-time PCR assays.

A real-time PCR assay specific for the actin beta gene locus was used to quantify the total amount of bisulfite-modified DNA. The Actin Beta gene locus does not contain any CpG sites, therefore, after the bisulfite modification reaction, all cytosines from this gene locus are converted into uracils and these are detected as thymines in a real-time PCR assay. This assay was used to check whether the genomic DNA was bisulfite-modified.

The following primers and T aq-man probes were used for this. Forward primer: 5'-CCCTTAAAAATTACAAAAACCACAA-3 '

Reverse Primer: 5'- GG AGG AGGTTT AGT AAGTTTTTT G -3 '

Taq-man probe: 5'-F AM-ACCACCACCCAACACACAATAACAAACACA-BHQ- 1 -3 '

Real-T ime-PCR approach:

Forward primer (50 pmol / m²): 0.1 m²

Reverse primer (50 pmol / mΐ): 0.1 mΐ

Taq-man probe (25 pmol / mΐ): 0.1 mΐ

InnuMIX qPCR MasterMix Probe (Analytik Jena): 7.5 mΐ

Bisulfite-modified or genomic DNA: 1.5 mΐ

PCR grade H ₂ 0: 5.7 mΐ

The real-time PCR was carried out in the CFX96 real-time system from Biorad.

Amplification conditions:

Step 1: Denaturation 95 ° C / 120 "

Step 2: amplification 40 cycles (95 ° C / 4 "; 57 ° C / 40")

FIG. 7 shows a real-time PCR from the β-actin assay. (gray curves:

genomic DNA, magenta curves: No Template Control; red and green curve samples DNA after the respective bisulfite modification reaction). The results show that the genomic DNA could be successfully modified with the aid of the manual method of the invention.

The cytosine free fragment (CFF-1) assay amplifies genomic and bisulfite-modified DNA with the same efficiency and is therefore suitable for quantifying the yield of bisulfite-modified DNA. It enables the direct comparison of input DNA and output DNA of the bisulite modification reaction. In the case of genomic DNA, the sense and the antisence strand serve as templates. In contrast, only the sense strand serves as a template in bisulfite-modified DNA, because the antisense strand (contains cytosines) is not available for the amplification reaction after the bisulfite modification.

That is why there is a theoretical loss of one Ct value for bisulfite-modified DNA, since the template is halved after the bisulfite modification.

The sequence of the primers and the Taq-man probes are as follows: Forward primer: 5 '-T AAG AGT AAT AATGGATGG ATG ATG-3'

Reverse Primer: 5'-CCTCCCATCTCCCTTCC-3 '

Taq-man probe: 5'-F AM-ATGGATGAAGAAAGAAAGGATGAGT-BHQ- 1 -3 'Real-time PCR approach:

Forward primer (50 pmol / m²) 0.1 m²

Reverse primer (50 pmol / mΐ) 0.1 mΐ

Taq-man probe (25 pmol / mΐ) 0.1 mΐ

InnuMIX qPCR MasterMix Probe (Analytik Jena) 7.5 mΐ

Bisulfite-modified or genomic DNA 1.5 mΐ

PCR grade H ₂ 0 5.7 mΐ

The real-time PCR was carried out in the CFX96 real-time system by the company Biorad:

Amplification conditions:

Step 1: Denaturation 95 ° C / 120 "

Step 2: amplification 40 cycles (95 ° C / 4 "; 52 ° C / 40")

FIG. 8 shows a real-time PCR from the CFF-1 assay. (magenta curves: No Template Control; gray curves: genomic DNA; red and green curves sample DNA after bisulfite modification reaction). A CFP 415 bp assay (cytosine-ffee primer binding site) with bisulfite-modified DNA was carried out as a further analysis. Since this assay is used to amplify long DNA sequences, this assay provides information about the degraded DNA during the bisulfite modification and during the purification of bisulfite-modified DNA. The sequences from the primers are as follows:

Forward primers: 5 ATGGGT AAGGAT ATG AAGTT AAT-3 '

Reverse Primer: 5'-TATCACTTAATCACCTCCTAAACTA-3 '

Real-time PCR approach:

Forward primer (50 pmol / m²): 0.1 m²

Reverse primer (50 pmol / mΐ): 0.1 mΐ

innuMix qPCR DSgreen Standard (Analytik Jena): 7.5 mΐ

Bisulfite-modified or genomic DNA 1.5 mΐ

PCR grade H ₂ 0: 5.8 mΐ

The real-time PCR was carried out in the CFX96 real-time system from Biorad:

Amplification conditions:

Step 1: Denaturation 95 ° C / 120 "

Step 2: Amplification 40 cycles (95 ° C / 4 "; 58 ° C / 40")

FIG. 9 shows a real-time PCR of the CFP 415 bp assay. (magenta curves: No Template Control, red and green curves: samples DNA after

Bisulfite modification reaction).

The results show less degraded DNA after the bisulfite modification by means of the method according to the invention compared to the commercial product.

Claims

Claims

1. A method for converting a cytosine base in a nucleic acid by bisulfite treatment into a uracil base, characterized in that the nucleic acid is bound to a non-mineral solid phase which has a rough surface after the bisulfite treatment and an incubation.

2. V experience according to claim 1, characterized in that the rough surface consists of metal, plastic or rubber, preferably of plastic granules.

3. The method according to claim 2, characterized in that the plastic granulate with a rough surface is paramagnetic.

4. The method according to claim 1 or 2, characterized in that the rough surface was generated by 3-D printing.

5. The method according to any one of claims 1 to 4, characterized in that the solid phase with a rough surface is located within a pipette tip.

6. The method according to any one of claims 1 or 4, characterized in that the fixed

Phase with a rough surface represents the lower part of a plastic comb.

7. The method according to any one of claims 1 to 6, characterized by the following steps: a) mixing the nucleic acid with a bisulfite solution and subsequent incubation of the reaction mixture

b) Addition of a binding buffer and attachment to the solid phase with a rough surface c) Incubation and removal of the supernatant from the solid phase

d) Washing by means of a washing buffer and subsequent removal of the washing buffer e) Addition of a desulfonation buffer and incubation, subsequent removal of the supernatant from the solid phase

f) washing, drying and detaching the modified nucleic acid from the solid phase.

8. Automated method according to the “walk-away principle” according to one of claims 5 to 7, characterized in that steps 7a) to 7f) are carried out within a pipette tip or on the lower part of a plastic comb.

9. Test kit for performing the method according to one of claims 1 to 8, comprising:

• a solid phase with a rough surface

• a bisulfite solution

• a binding buffer

• a desulfonation buffer

• at least one wash buffer

• a release buffer

• a vessel to carry through

10. Use of a non-mineral solid phase with a rough surface for converting a cytosine base in a nucleic acid by bisulfite treatment into a uracil base.