EP1904650A1

EP1904650A1 - Method for investigating cytosine methylations in dna

Info

Publication number: EP1904650A1
Application number: EP06764209A
Authority: EP
Inventors: Philipp Schatz; Matthias Schuster; Kurt Berlin
Original assignee: Epigenomics AG
Current assignee: Epigenomics AG
Priority date: 2005-07-19
Filing date: 2006-07-19
Publication date: 2008-04-02
Also published as: DE102005034628B4; US20090208941A1; WO2007010004A1; DE102005034628A1

Abstract

A method for sensitive and specific detection of cytosine methylations is described, in which the DNA to be analyzed is first enriched. The enrichment can in particular be methylation-specific, sequence-specific or source-specific. The enriched DNA then undergoes methylation-specific conversion. The converted DNA can be analyzed using different methods, in particular by real-time PCR methods.

Description

Method for the investigation of cytosine methylations in DNA

The present invention relates to a method for detecting 5-methylcytosine in DNA. 5-methylcytosine is the most abundant covalently modified base in the DNA of eukaryotic cells. It plays an important biological role, i.a. in transcriptional regulation, genetic imprinting and tumorigenesis (for review: Miliar et al .: Five not four: History and significance of the fifth base. In: The Epigenome, S. Beck and A. Olek (eds.), Wiley -VCH Verlag Weinheim 2003, pp. 3-20). The identification of 5-methylcytosine as a component of genetic information is therefore of considerable interest. However, detection of methylation is difficult because cytosine and 5-methylcytosine have the same base pairing behavior. Many of the conventional hybridization-based detection methods are therefore unable to distinguish between cytosine and methylcytosine. In addition, the methylation information is completely lost in a PCR amplification.

The conventional methods for methylation analysis operate essentially on two different principles. On the one hand, methylation-specific restriction enzymes are used, on the other hand there is a selective chemical conversion of non-methylated cytosines into uracil (so-called: bisulfite treatment, see for example: DE 101 54 317 A1, DE 100 29 915 A1).

Since the treatment with methylation-specific restriction enzymes is limited by the sequence specificity of the enzymes to certain sequences, a bisulfite treatment is carried out for most applications (for review DE 100 29 915 A1 p.2, lines 35-46). The chemically pretreated DNA is then usually amplified and can be analyzed in different ways (for review: WO 02/072880 p. 1 ff). Of great interest are methods that are able to detect methylation sensitively and quantitatively. This is true because of the important Role of cytosine methylation in carcinogenesis, especially with regard to diagnostic applications. Of particular importance are methods that make it possible to detect aberrant methylation patterns in body fluids, such as serum. Because unlike the unstable RNA, DNA is often found in body fluids. In destructive pathological processes such as cancer, the DNA concentration in the blood is even increased. A cancer diagnosis via a methylation analysis of body fluid tumor DNA is thus possible and has already been described several times (see, for example, Palmisano et al .: Predicting lung cancer by detecting aberrant promoter methylation in sputum.) Cancer Res. 2000 Nov 1; 60 (21) : 5954-8). A particular problem, however, is that in the body fluids in addition to the DNA with the disease-typical methylation pattern is a large amount of DNA of the same sequence but a different methylation pattern. The diagnostic methods must therefore be able to detect low levels of particularly methylated DNA against a strong background of DNA of the same sequence but of a different methylation pattern (hereafter: background DNA).

The conventional methods for methylation analysis solve this problem only limited. Usually, the chemically pretreated DNA is amplified by a PCR method. The use of methylation-specific primers or blockers should then ensure selective amplification of only the methylated (or, in the case of the reverse approach: unmethylated) DNA. The use of methylation-specific primers is known as so-called "methylation-sensitive PCR"("MSP"; Herman et al .: Methylation-specific PCR: a novel PCR assay for methylation status of CpG islands.) Proc Natl Acad 3; 93 (18): 9821-6). A similarly sensitive method is the so-called "heavy methyl" method, in which specific amplification of only the originally methylated (or unmethylated) DNA is achieved by using methylation-specific blocker oligomers (for review: WO 02/072880) Heavy methyl are applicable as quantifiable real-time variants. It is possible to detect the methylation status of fewer positions directly in the course of PCR without the need for subsequent analysis of the products ("MethyLight" - WO00 / 70090; US 6,331,393) One embodiment is the "Taqman" method. This uses probe molecules that carry a fluorescent dye-quencher pair. The probes hybridize sequence-specifically to the amplicons and are degraded by the exonuclease activity of the polymerase during the next cycle of amplification. The separation of quencher and dye produces a detectable fluorescence signal (see, eg, Eads et al .: MethyLight: a high-throughput assay to measure DNA methylation, Nucleic Acids Res. 2000 Apr 15; 28 (8): E32). Another MethyLight embodiment is the so-called Lightcycler method. In this case, two different probes are used, which hybridize in close proximity to each other to the amplificate, and then generate a detectable signal via fluorescence resonance energy transfer (FRET).

However, the applicability of these methods for sensitive and specific detection of methylated DNA against a large background of unmethylated DNA is limited. Thus, there is a risk that false positive results will occur through non-specific amplification of background DNA. However, false positive signals represent one of the most significant problems of using methylation technology for early cancer detection. Increasing the specificity of the methylation detection therefore represents a significant step in the development of appropriate screening assays. A reliable, commercial use of the methylation analysis in the field of tumor early diagnosis is thus facilitated.

To increase the specificity of methylation detection, the known amplification methods use primer or blocker sequences containing multiple methylation specific positions. However, these sequence requirements only allow evidence of segregation. sequences in which a large number of CpG positions occur in a narrow sequence range. These sequence requirements limit the applicability of the methods.

Because of the particular biological and medical significance of cytosine methylation and due to the above-mentioned disadvantages of the prior art, there is a great technical need for the development of efficient methods for sensitive and specific methylation analysis. In the following, a surprisingly simple method is described with which the sensitivity and specificity of the methylation detection can be increased.

According to the invention, an enrichment of the DNA to be amplified is carried out before the amplification. The enrichment preferably takes place before the bisulfite conversion, but can also be carried out afterwards. The enrichment leads to the fact that the disease-specific DNA can be detected more easily. According to the invention, the enrichment preferably takes place according to three different principles. On the one hand, the enrichment can be carried out in a methylation-specific manner, that is, the DNA of a specific methylation status is concentrated. This can be done, for example, via methylcytosine-binding proteins (see, for example, Cross et al., Nat Genet., 1994 Mar; 6 (3): 236-44.). In a second embodiment of the invention, a sequence-specific purification takes place. Only certain sequences are purified, such as those known to associate a change in methylation status with a disease. In a third embodiment of the invention, the enrichment is origin specific. For example, the DNA can be specifically isolated from tumor cells and then further isolated. In preferred embodiments of the method according to the invention, the three principles are combined. After purification, bisulfite conversion and amplification / detection are carried out conventionally. If the enrichment is carried out after the bisulfite conversion, sequence-specific and methylation-specific see purification on the same principle, since the methylation information was converted by the Biuslfit treatment in sequence information. Enrichment of the DNA to be detected reduces the risk of false positive results and thus allows a more specific detection of methylated cytosine positions.

Some of the enrichment methods according to the invention have already been described in connection with a methylation analysis. For example, it is known to purify the DNA prior to methylation analysis with methylcytosine-binding antibody (for example via antibody column: Fisher et al Nucleic Acids Res. 2004 Jan 9; 32 (1): 287-97).

However, this enrichment method has hitherto been used only to identify previously unknown methylation positions. By contrast, a use of this method for the sensitive detection of cytosine positions whose association with a disease is already known is not yet known.

Sensitive detection is understood below to mean a detection which allows the detection of 100 or fewer copies of methylated DNA against a backdrop of 1000 copies of unmethylated or less methylated DNA.

Due to the particular importance of methylation analysis for early tumor diagnosis and due to the disadvantages of the known methods, the opening of this advantageous, new and surprisingly simple technology represents an important technical advance.

The method according to the invention is a method for the sensitive detection of cytosine methylations. These are understood to mean in the following processes which are capable of detecting certain methylation positions in the DNA with high sensitivity. Under Sensitive detection is understood below to mean a detection that allows the detection of 100 or fewer copies of methylated DNA against a background of 1000 copies of unmethylated or less methylated DNA.

In the methods for sensitive detection, the cytosine positions to be analyzed are already known. It is also already known with which biological state, for example with which disease, the methylation status of these positions correlates. It is different in the case of the so-called "discovery methods", which are understood in the following to be methods for identifying or characterizing methylation positions, which are assumed to have a specific biological role Term "method for the sensitive detection of Cytosinmethylierungen" not be included.

The method according to the invention for the sensitive methylation analysis proceeds in the following steps:

1) a biological sample is taken,

2) the DNA to be detected is enriched,

3) the DNA is converted to methylation-specific by a chemical or enzymatic treatment,

4) the converted DNA is amplified,

5) the amplificates are analyzed.

In an alternative embodiment, the enrichment takes place only after the conversion of the DNA. This procedure thus takes place in the following steps:

1) a biological sample is taken,

2) the DNA is converted to methylation-specific by a chemical or enzymatic treatment,

3) the DNA to be detected is enriched,

4) the enriched DNA is amplified,

5) the amplificates are analyzed. In the first step of the method according to the invention, a biological sample is taken, from which the DNA is recovered. Depending on the diagnostic or scientific question, the biological sample can come from different sources. Tissue samples, but also body fluids, in particular serum, serve as starting material for diagnostic questions. It is also possible to use sputum, stool, urine or cerebrospinal fluid. First, DNA isolation is preferably carried out by standard methods, for example using blood from the Qiagen UltraSens DNA extraction kit.

In the second step of the method according to the invention, the DNA to be detected is enriched. The DNA to be detected is understood as meaning the sequence whose methylation status is to be analyzed. Enrichment is understood to mean a process in which the concentration of the DNA to be detected is increased in comparison with the rest of the DNA. The rest of the DNA, depending on the enrichment process, is the background DNA (DNA of the same sequence, but of a different methylation status than the DNA to be detected), the DNA of another sequence, or the DNA from another source.

In a preferred embodiment of the process according to the invention, the enrichment is methylation-specific. In this case, the DNA to be detected is enriched against the background DNA. The methylation-specific enrichment can take place in different ways. Essentially, the DNA is contacted with substances that specifically bind methylated or unmethylated sequences. The binding can be both sequence-specific and sequence-unspecific (only via the methylated cytosines). After binding to the substances, the bound DNA can be separated from the unbound DNA. Depending on whether the DNA to be detected is methylated or unmethylated, the bound or unbound fraction can be further analyzed. As described above, methylation-specific binding of DNA to certain substances and subsequent separation of bound and unbound DNA is essential for methylation-specific enrichment. The term methylation-specific enrichment should not include any methods in which the background DNA is degraded by means of methylation-specific restriction enzymes. Such a method is already described in the patent application DE 10 2005 011 398.2 and is not intended to be content of this application. Although a methylation-specific binding of the DNA to the restriction enzyme also takes place in this case. However, this binding is only a transitory state on the way to the enzymatic section. In the method according to the invention, however, a separation of the bound (uncut) DNA from the unbound DNA.

For the process according to the invention, different substances which bind to the DNA in a methylation-specific manner are suitable.

In a preferred embodiment, the enrichment takes place with the aid of proteins which bind to the DNA in a methylation-specific manner. Several such proteins are known, i.a. MeCP2, MBD1, MBD2, MBD4, and Kaiso (for review: Shiraishi et al., Methyl-CpG binding domain column chromatography to a tool for the analysis of genomic DNA methylation., Anal Biochem., 2004 Jun 1, 329 (1): 1-10.) Incorporated by reference in its entirety; Henrich et Tweedie: The methyl-CpG binding domain and the evolving role of DNA methylation in animals. Trends Genet. 2003 May; 19 (5): 269-77; both incorporated by reference in its entirety).

With the help of proteins that bind methylation-specifically to the DNA, a methylation-specific enrichment can take place in different ways. It is thus possible to use proteins which specifically bind methylated DNA, as well as proteins which bind specifically unmethylated DNA. Furthermore, it is possible to bind the DNA which is to be detected later. For this purpose, first the unbound DNA is separated, and then the bound DNA is released from the protein. It is also possible to bind the background DNA to the proteins and then remove them from the reaction mixture.

The protein binding and the separation of the bound and the unbound DNA can be done in different ways. For example, it is possible to bind the proteins to a solid surface, for example in the form of a column (see: Cross et al 1994, Nature Genetics VoI 6 236-244). The unbound DNA can then be removed by washing. It is also possible to allow the binding to the proteins in solution, and then to separate the DNA-protein complexes from the unbound DNA by conventional methods such as centrifugation or chromatography. Those skilled in the art are familiar with the biochemical methods to be used, for example using biotinylated or histidine-tagged proteins (for example, Gretch et al 1987, Anal Biochem Vol 163 270-7 Janknecht et al., 1991, Proc Natl Acad Sei USA Vol 88 8972- 6)

In a particularly preferred embodiment, the enrichment takes place via the so-called MBD column chromatography, which is described in detail in Shiraishi et al., 2004, supra. Reference is expressly made to this publication.

For example, the methyl CpG-binding domain of the MeCP2 protein which specifically binds methylated but not unmethylated or hemimethylated cytosines can be used. The corresponding, in vitro expressed domain can be bound to a modified agarose surface, for example via additional histidine residues. The domain recognizes sequence-unspecific methylated CpG positions. The binding of the methylated DNA to the column is carried out depending on the degree of methylation and the density of the CpG positions. The bound methylated DNA molecules can then be eluted by increasing the salt concentration and then analyzed (see in detail: Shiraishi et al 2004, supra).

In addition, it is also possible to analyze the unbound, unmethylated fraction.

According to the abovementioned principle, it is also possible to use other proteins which bind methyl-specifically to DNA, in particular proteins which bind sequence-specifically to CpG positions, for example with the help of the Kaiso protein, which recognizes symmetrically methylated CpGpCpG positions ,

In addition to the abovementioned MDB proteins, it is also possible in principle to use further proteins which recognize DNA methylation-specifically. These include, for example, restriction enzymes or methyltransferases. It is conceivable that those parts of these enzymes which are responsible for the methylation-specific binding, without the corresponding active center for enrichment are used.

In a further preferred embodiment, the enrichment takes place via methylation-specific antibodies. Anti-5-methylcytosine antibodies have long been known and are commercially available (www.abcam.com, Abcam Ine, One Kendall Square, Bldg. 200, 3rd Floor, Cambridge, MA02139). These antibodies may also be bound to a column or bound to the DNA in solution via the known methods (see Fisher et al., Supra). ].

It is also conceivable, although not preferred because of the experimental effort, to carry out a chromatin immunoprecipitation (ChIP) for enrichment (details of this method are known to the person skilled in the art and can be found, for example, in Matarazzo et al .: In vivo analysis of DNA methylation pat. CHIP and bisulfite analysis. Biotechniques. Oct; 37 (4): 666-8, 670, 672-3. 2004).

In addition to proteins, according to the invention it is also possible to use further substances which are capable of binding to the DNA in a methylation-specific manner. These include, for example, triplex-forming PNA or DNA oligomers. Corresponding oligomers are described in detail in the patent application PCTVE P04 / 06534 (Applicant: Epigenomics AG). There are also descriptions with further references on how to use triplex-binding molecules for the isolation of methylated DNA (so-called "triple helix affinity chromatography").

In a second particularly preferred embodiment, the enrichment of the DNA to be analyzed is not methylation-specific, but sequence-specific. Thus, specifically those sequences can be enriched whose methylation status is correlated with a disease or another biological issue. The other sequences, on the other hand, are removed from the reaction mixture. The sequence-specific enrichment preferably takes place via hybridization to complementary sequences. These are preferably bound to a surface, such as a solid phase or to particles. Various variants of the enrichment are known to the person skilled in the art, for example using modified PNA or DNA oligomers which are immobilized, biotinylated or provided with magnetic particles (for example: Riccelli et al., Nucleic Acids Res. 2001 Feb 15; 29 (4): 996-1004). The enriched sequences can then be eluted and converted to methylation-specific. However, it is possible to carry out the subsequent conversion, in particular a bisulfite conversion, directly at the surface (see below).

Finally, in a third particularly preferred embodiment, enrichment occurs according to the origin of the DNA. In the following, this refers in particular to the cellular origin of the DNA. In a preferred In this case, the enrichment of the DNA takes place via the isolation of a specific type of cell. It is particularly preferred to isolate cancer cells from body fluids such as blood, urine or stool. In addition, it is also possible to enrich a specific cell type to later analyze the DNA, such as T cells.

For the isolation of cells, various methods are known to the person skilled in the art, for example using fluorescently or magnetically activated or immobilized antibodies, eg. FACS or MACS (for review: FACS Sorting: Herzenberg et al., Clin Chem., 2002 Oct; 48 (10): 1819-27; MACS as Positive Selection: Qin et al., World J Gastroenterol 2004 May 15; 10): 1480-1486; MACS as a negative selection: Lara et al., Exp Hematol., 2004 Oct; 32 (10): 891-904).

Furthermore, it is preferred according to the invention to isolate DNA bound to subcellular fragments, such as nucleosomes. This is based on the consideration that in destructive pathological processes more DNA is released, which is still bound to cellular structures. This can be enriched by the use of organ part specific cleaning method, z. Nuclei PURE Prep from Sigma Life Science Research (see also: Blobel et al 1966 Science VoI 154 1662-5) or by the enrichment of the nucleosomes (Whitlock et al 1976 Nucleic Acids Res VoI 3 2255 -66). It is also possible to specifically purify transcriptional complexes of individual genes (Pindolia et al 2005 J Mol Biol. VoI 349 922-32).

In preferred embodiments of the method according to the invention, the abovementioned enrichment methods are combined with one another. For example, it is possible first to carry out a methylation-specific enrichment (for example with the aid of a methylation-specific antibody) and then (possibly after a fragmentation step) to attach a sequence-specific capture. In the third step of the process according to the invention, the enriched DNA is converted to a methylation-specific manner by a chemical or enzymatic treatment. On the one hand, methylation-specific restriction enzymes can be used for this purpose, for example in such a way that the interface is located within the region which is to be amplified later. An amplicon can only be formed if the DNA has not been cut. Details of this principle are known to the person skilled in the art (cf., for example, DE 1020040297002) However, in a preferred embodiment, the DNA is converted chemically or enzymatically such that unmethylated cytosine is converted into thymine or another base, which differs in the base-pairing behavior of cytosine, while Methyl cytosine remains unchanged. The bisulfite conversion is known to the person skilled in the art in various variations (see for example: Frommer et al .: A genomic sequencing protocol that yields a positive display of 5-methylcytosine residues in individual DNA strands Proc Natl Acad See USA 1992 Mar 1; 89 (5): 1827-31 Olek, A modified and improved method for bisulphite-based cytosine methylation analysis Nucleic Acids Res. 1996 Dec 15; 24 (24): 5064- DE 100 29 915, DE 100 29 915. Particularly preferably, the bisulfite conversion takes place in the presence of denaturing solvents, such as dioxane, and of a free-radical scavenger (cf .: DE 100 29 915.) Further preferred embodiments of the bisulfite conversion are described in German DE 103 47 396.3, DE 10347 397.1, DE 103 47 400.5 and DE 10347 399.8 In some cases, the bisulfite conversion is carried out on a solid phase (compare: PCT / DE02 / 04054, EP 03 019 321.3) kbar, if the enrichment was via a solid phase, the bisulfite conversion directly follow without a previous elution of the DNA.

In another preferred embodiment, the DNA is not converted chemically, but enzymatically. This is due to the use of cytidine Deaminases conceivable, the unmethylated cyidine implement faster than methylated cytidine. A corresponding enzyme has recently been identified (Bransteitter et al .: Activation-induced cytidine deaminase deaminate deoxyncytidine on single-stranded DNA but requires the action of RNase.) Proc Natl Acad Be USA 2003 Apr 1; 100 (7): 4102-7, see: German Patent Application: 103 31 107.6).

In an alternative embodiment of the method according to the invention, the enrichment takes place after the conversion of the DNA. In this case, sequence-specific and methylation-specific purification proceed on the same principle, since the methylation information was converted into sequence information by the bisulfite treatment. For sequential-specific purification, the methods described above, in particular using modified DNA or PNA-OI oligomers, can be used. The above statements are expressly made.

In the fourth step of the method according to the invention, the converted DNA is amplified and subsequently analyzed. Then it is possible to deduce the methylation status of the DNA.

The person skilled in various methods for the amplification of DNA are known, such as ligase chain reactions. In a preferred embodiment, however, the DNA is amplified via a polymerase reaction. Various embodiments are conceivable for this, for example the use of isothermal amplification methods. However, particularly preferred are polymerase chain reactions (PCR). In a most preferred embodiment, the PCR is performed using primers that bind specifically only to positions of the transformed sequence that were previously either methylated (or, in the reverse approach, unmethylated). This method is known for bisulfited DNA under the name methylation-sensitive PCR (MSP). In this case, primers are used which contain at least one 5'-CpG -3 'dinucleotide; preferred are primers which have at least three 5'- Carry CpG 3 'positions, at least one of which is located at the 3' end. Accordingly, 5'-TG-3 ^' or 5 ^' -CA-3 ^' -dinucleotides are required for the amplification of the unmethylated sequences or of the counterstrands (cf. Herman et al .: Methylation-specific PCR: a novel PCR assay for methylation Status of CpG islands Proc Natl Acad See USA 1996 Sep 3; 93 (18): 9821-6).

Another very particularly preferred embodiment is known for bisulfite-pretreated DNA under the name "heavy-methyl" method, whereby a specific amplification of only the originally methylated (or unmethylated) DNA is achieved by using at least one methylation-specific blocker oligomer . the blocker binds to a 5 ^'- ^CG-3' (or 5 ^{^'TG-3'} dinucleotide or 5 ^{^'-CA-3')} dinucleotide, thus preventing the amplification of the background DNA, the embodiment can. the selection of the polymerase or via the modification of the blocker oligomers be designed so that a degradation or an extension of the blocker is minimized (for review: WO 02/072880; Cottrell et al., A real-time PCR assay for DNA methylation using methylation -specific blockers, Nucleic Acids Res. 2004 Jan 13; 32 (1): e10.).

The detection of the amplificates can be carried out by conventional methods, for example via length measurement methods such as gel electrophoresis, capillary gel electrophoresis and chromatography (for example HPLC). Mass spectrometry and sequencing methods such as the Sanger method, the Maxam-Gilbert method and sequencing by hybridization (SBH) can also be used. In a preferred embodiment, the amplificates are detected by primer extension methods (see: Gonzalgo & Jones: Rapid Quantitation of Methylation Differences at Speeifie Sites using methylation-sensitive single nucleotide primer extension (Ms-SNuPE) Nucleic Acids Res 15, 25 (12): 2529-31, DE 100 10 282, DE 100 10 280). In another preferred embodiment, the amplicons are analyzed by hybridization to oligomer arrays (for an overview of ray technology, see the Extra Edition of: Nature Genetics Supplement, Volume 21, January 1999). In such an array, the various oligomers may be disposed on a solid phase in the form of a rectangular or hexagonal lattice. The solid phase surface is preferably composed of silicon, glass, polystyrene, aluminum, steel, iron, copper, nickel, silver or gold. However, nitrocellulose and plastics such as nylon, which may exist in the form of pellets or as resin matrices, are also possible. The approximately fluorescently labeled amplicons are hybridized to the bound oligomers and the unbound fragments are removed. It is advantageous if the oligomers hybridize over a 12-22 base long section to the DNA to be analyzed and they comprise at least one CG, TG or CA dinucleotide. The fluorescence signals can be scanned and processed with software programs (See, for example: Adorjan et al., Tumor class prediction and discovery by microarray-based DNA methylation analysis.) Nucleic Acids Res. 2002 Mar 1; 30 (5): e21) ,

Most preferably, the amplificates are analyzed using PCR real-time variants (see: Heid et al .: Real time quantitative PCR Genome Res. 1996 Oct; 6 (10): 986-94, US Pat. 6,331, 393 "methyl Light") Here, the amplification is carried out in the presence of a fluorescently labeled Reporteroligonukleotid that at a 5 -CG-3 -. dinucleotide (or 5 ^{^'TG-3'} - or 5 ^{^'-CA-3'} The reporter oligonucleotide preferably binds to the DNA to be examined and indicates its amplification by increasing or decreasing the fluorescence, whereby it is particularly advantageous if the fluorescence change is used directly for the analysis and the methylation state is deduced from the fluorenceenzyme signal A particularly preferred variant is the "Taqman ™" method. In another particularly preferred embodiment, an additional fluorescently labeled Oligomer which hybridizes in the immediate vicinity of the first reporter oligonucleotide and which hybridization can be detected by means of fluorescence resonance energy transfer ("Lightcycler ™" method) The person skilled in the art is familiar with further real-time variants, for example by means of lecular Beacons ™ or Scorpion ™ primers (see: DE 103 38 308) The corresponding variants are also part of this invention.

In another particularly preferred embodiment of the invention, a so-called QM assay is carried out. The QM assay uses two methylation-unspecific primers and two different real-time probes, one of which is specific for the methylated and one specific for the unmethylated state. The QM assay allows a very good quantification of methylation states. The QM assay is described in detail in European Patent Application 04 090 213.2, to which reference is expressly made.

Another preferred embodiment of the invention is to amplify multiple fragments simultaneously by multiplex PCR. Care must be taken in their design that not only the primer, but also the other oligonucleotides used are not allowed to be complementary to each other, so that a high degree of multiplexing in this case is more difficult than usual. However, enzymatically pretreated DNA has the advantage that, due to the different G and C contents of the two DNA strands, a forward primer can never function as a reverse primer, which in turn facilitates multiplexing and essentially obviates the disadvantage described above balances. The detection of the amplificates is again possible via different methods. It is conceivable, for example, the use of real-time variants. However, for amplifications of more than four genes, it is recommended to detect the amplificates in another way. Preference is given to an analysis of arrays (see above). In a preferred embodiment of the method according to the invention, the sensitive detection takes place without prior amplification. This is possible, for example, if different purification methods are combined with each other. In this case, the chemical transformation of the DNA may not be required. Thus, first a sequence-specific capturing can take place, for example via a chip or with the aid of a specific transcription factor to which the sequence to be investigated binds, and subsequently detection of methylated sequences via a (eg fluorescence- or radioactively) labeled methylation-specific antibody. As a rule, it will be necessary to amplify the signal. This can be done by branched probes, which have both target-specific sequence sections and sequence parts for signal generation in the form of a tree structure. Then, detection probes which are enzymatically labeled (eg alkaline phosphatase) bind to them. Alternatively, several signal cascades can be coupled together (eg alkaline phosphatase with alcohol dehydrogenase and diaphorase see: Johannsson 1985 Clin Chim Acta VoI 148 119-24)

Alternatively, a methylation-specific antibody can be coupled with an oligonucleotide. The antibody binds to methylated sequences. A second oligonucleotide binds sequentially and can be linked by a ligation reaction to the oligonucleotide attached to the antibody. The newly formed product can be detected by PCR or LCR.

A particularly preferred use of the method of the invention is in the diagnosis of cancers or other diseases associated with a change in methylation status. These include CNS malfunctions, aggression symptoms or behavioral disorders; clinical, psychological and social consequences of brain damage; psychotic disorders and personality disorders; Dementia and / or associated syndromes; cardiovascular disease, malfunctioning on and damage; Dysfunction, damage or disease of the gastrointestinal tract; Dysfunction, damage or disease of the respiratory system; Injury, inflammation, infection, immunity and / or convalescence; Dysfunction, damage or disease of the body as a deviation in the development process; Dysfunction, damage or disease of the skin, muscles, connective tissue or bones; endocrine and metabolic dysfunction, injury or disease; Headache or sexual dysfunction.

The method according to the invention is also suitable for the prediction of undesired drug effects and for the differentiation of cell types or tissues or for the investigation of cell differentiation.

Finally, according to the invention, a kit comprising at least one reagent for enriching the sequence to be analyzed and reagents for a bisulfite conversion, and optionally also a polymerase, primers and probes for amplification and detection is also included.

Suitable reagents for enriching the sequence to be analyzed are, in particular, methylation-specific binding proteins, which are preferably column-bound, biotinylated or provided with histidine tag. Furthermore, or modified PNA or DNA oligomers may be used which are preferably immobilized, biotinylated or modified with magnetic particles.

Claims

claims

1. A method for sensitive methylation analysis, characterized in that the following steps are carried out: a) a biological sample is taken, b) the DNA to be detected is enriched, c) the enriched DNA is methylation-specific by a chemical or enzymatic treatment converted, d) the converted DNA is amplified, e) the amplifcates are analyzed.

2. A method for sensitive methylation analysis, characterized in that the following steps are carried out: a) a biological sample is taken, b) the DNA is converted by a chemical or enzymatic treatment methylation specific, c) the DNA to be detected is enriched, d) the enriched DNA is amplified, e) the amplificates are analyzed.

3. The method according to any one of claims 1-2, characterized in that it is the tissue sample or body fluids in the biological sample.

4. The method according to any one of claims 1 or 3, characterized in that the enrichment takes place methylation-specific.

5. The method according to claim 4, characterized in that the enrichment takes place with the aid of proteins which bind methylation-specific to the DNA.

6. The method according to claim 5, characterized in that the enrichment using MeCP2, MBD1, MBD2, MBD4 or Kaiso takes place.

7. The method according to claim 6, characterized in that the enrichment takes place via MBD column chromatography.

8. The method according to claim 5, characterized in that methylie- rungsspezifische antibody takes place.

9. The method according to any one of claims 1-3, characterized in that the enrichment is sequence-specific.

10. The method according to any one of claims 1 or 3, marked thereby, that the enrichment takes place after the origin of the DNA.

11. The method according to claim 10, characterized in that cancer cells are enriched from body fluids.

12. The method according to claim 11, characterized in that DNA is enriched, which is bound to subcellular fragments.

13. The method according to claim 12, characterized in that the DNA is bound to nucleosomes.

14. The method according to any one of the preceding claims, characterized in that the conversion takes place by means of a bisulfite conversion.

15. The method according to any one of the preceding claims, characterized in that the amplification is carried out by means of one of the following methods: Heavy Methyl ™, MSP; MethyLight ™ or QM.

16. The method according to any one of the preceding claims, characterized in that a plurality of enrichment processes are combined.

17. The method according to claim 16, characterized indicates that an amplification of the enriched DNA is not carried out.

18. Method according to claim 16, characterized in that a chemical conversion of the DNA is not required

19. A method for the sensitive detection of cytosine methylations, characterized in that the following steps are carried out: a) a biological sample is taken, b) the DNA to be detected is a sequence-specific

Enriched capturing, c) the enriched DNA is detected via a methylation-specific antibody

20. Use of the methods according to claims 1-19 for the diagnosis of cancers or other diseases associated with a change in the methylation status.

21. Use of the methods according to claims 1-19 for the prediction of adverse drug reactions, to distinguish

Cell types and tissues or to study cell differentiation.

22. A kit comprising at least one reagent for enrichment of the analyte sequence and reagents for bisulfite conversion, and optionally also a polymerase, primers and probes for amplification and detection.

23. Kit according to claim 22, characterized in that the reagents for enrichment are methylation-specific binding proteins which are column bound, biotinylated or provided with a histidine tag.

24. Kit according to claim 22, characterized in that the reagents for enrichment are modified PNA or DNA oligomers which are immobilized, biotinylated or not provided with magnetic particles.