On the nature of the cytosine-methylated sequence in DNA of Bacillus brevis var. G.-B.

On growing the cells of Bacillus brevis S methionine-auxotroph mutant in the presence of [Me-3H]methionine, practically all the radioactivity incorporated into DNA is found to exist in 5-methylcytosine and N6-methyladenine. The analysis of pyrimidine isopliths isolated from DNA shows that radioactivity only exists in mono- and dinucleotides and the content of 5-methylcytosine in R-m5 C-R and R-m5 C-T-R oligonucleotides is equal. The analysis of dinucleotides isolated from DNA by means of pancreatic DNAase hydrolysis allows the nature of purine residues neighbouring 5-methylcytosine to be identified and shows that 5-methylcytosine localizes in G-m5 C-A and G-m5 C-Tr fragments. B. brevis S DNA methylase modifying cytosine residues recognizes the GCA/TGC degenerate nucleotide sequence which is a part of the following complementary structure with a two-fold rotational axis of symmetry: (5')...N'-G-C-T-G-C-N... (3') (3')...N-C-G-A-C-G-N'... (5') (Methylated cytosine residues are askerisked). Cytosine-modifying DNA methylase activity is isolated from B. brevis cells; it is capable of methylating in vitro homologous and heterologous DNA. Hence DNA in bacterial cells can be undermethylated. This enzyme methylates cytosine residues in native and denatured DNA in the same nucleotide sequences. Specificity of methylation of cytosine residues in vitro and in vivo does not depend on the nature of substrate DNA. DNA methylases of different variants of B. brevis (R, S, P+, P-)) methylate cytosine residues in the same nucleotide sequences. It means that specificity or methylation of DNA cytosine residues in the cells of different variants of B. brevis is the same.     

Heat- and alkali-induced deamination of 5-methylcytosine and cytosine residues in DNA

5-Methylcytosine residues in DNA underwent deamination at high temperatures. Furthemore, their rate of deamination at neutral or alkaline pH was greater than that of cytosine residues in DNA. As sources of [¹⁴C]5-methylcytosine-containing DNA, we used bacteriophage XP-12 DNA, in which 5-methylcytosine residues completely replace C residues, and calf thymus DNA experimentally substituted with [¹⁴C]5-methylcytosine residues. Upon incubation at 95°C in a physiological buffer or at 60°C in 1 M NaOH, the respective rates of deamination of 5-methylcytosine residues were about 3- and 1.5-times those of cytosine residues. Under the same conditions, the free 5-methyldeoxycytidine was converted to thymidine more rapidly than deoxycytidine was converted to deoxyuridine. The reactions at physiological pH and elevated temperature suggest that deamination of 5-methylcytosine residues may yield a significant portion of spontaneous mutations in vivo, especially in view of the lack of thymine-specific mismatch repair systems with specificity and efficiency comparable to that of uracil excision repair systems.     

Methylation of parental and progeny DNA strands in Physarum polycephalum

Although 5-methylcytosine comprises 4 to 8% of the cytosine residues in the major nuclear DNA of Physarum polycephalum (Evans &; Evans, 1970), only 1 % of the cytosine residues of progeny DNA become methylated during replication. Further methylation occurs during the same and subsequent mitotic cycles, so that 6 to 7 cycles after its synthesis, 5-methylcytosine comprises 5 to 7% of the DNA-cytosine residues of a single generation of DNA. The extent of methylation occurring during the S period has been measured by the determination of the specific activity of the precursor (S-adenosylmethionine) and the product (DNA-5-methylcytosine) and by comparison of the radioactivity in DNA-cytosine and DNA-5-methylcytosine after incorporation of [¹⁴C]deoxycytidine. Continuing methylation of parental DNA has been shown, by density shift experiments and by the conversion of prelabeled DNA-cytosine to DNA-5-methylcytosine. The DNA-5-methylcytosine once formed was found to be stable.     

5-Methylcytosine is not detectable in Saccharomyces cerevisiae DNA.

We examined the DNA of Saccharomyces cerevisiae by both HpaII-MspI restriction enzyme digestion and high-performance liquid chromatography analysis for the possible presence of 5-methylcytosine. Both of these methods failed to detect cytosine methylation within this yeast DNA; i.e., there is less than 1 5-methylcytosine per 3,100 to 6,000 cytosine residues.     

On the impossibility of the incorporation of 5-methylcytosine and its nucleosides into higher plant DNA

No radioactivity was detected in 5-methylcytosine isolated from wheat DNA after incubation of wheat seedlings with 3H-labelled 5-methylcytosine, 5-methylcytidine and 5-methyldeoxycytidine. No label from 3H-5-methylcytosine was found in DNA of seedlings. After incubation of seedlings with 3H-labelled nucleosides of 5-methylcytosine, radioactivity was discovered only in thymine of DNA. Thus 5-methylcytosine and its nucleosides can not be used in plants as direct precursors of 5-methyl cytosine residues in DNA, but nucleosides of 5-methylcytosine may be deaminated to thymidine (or deoxythymidine) and subsequently incorporated into DNA.     

High sensitivity mapping of methylated cytosines.

An understanding of DNA methylation and its potential role in gene control during development, aging and cancer has been hampered by a lack of sensitive methods which can resolve exact methylation patterns from only small quantities of DNA. We have now developed a genomic sequencing technique which is capable of detecting every methylated cytosine on both strands of any target sequence, using DNA isolated from fewer than 100 cells. In this method, sodium bisulphite is used to convert cytosine residues to uracil residues in single-stranded DNA, under conditions whereby 5-methylcytosine remains non-reactive. The converted DNA is amplified with specific primers and sequenced. All the cytosine residues remaining in the sequence represent previously methylated cytosines in the genome. The work described has defined procedures that maximise the efficiency of denaturation, bisulphite conversion and amplification, to permit methylation mapping of single genes from small amounts of genomic DNA, readily available from germ cells and early developmental stages.     

Determination of trace amounts of 5-methylcytosine in DNA by reverse-phase high-performance liquid chromatography

A high-performance liquid chromatographic method to separate five major bases (cytosine, thymine, guanine, adenine, and uracil) and three minor methylated bases (5-methylcytosine, N6-methyladenine, and 7-methylguanine) has been developed using a volatile mobile phase under isocratic conditions. It is extended to quantitate 5-methylcytosine in trace amounts (1 in 20,000 cytosine residues). The suitability of the method has been verified by estimating 5-methylcytosine in DNAs of phi X174 and pBR322. The method has been applied to quantitate the extent of cytosine methylation in DNA of larval silk glands of Bombyx mori. Our results confirm that the pupal DNA of Drosophila melanogaster does not contain detectable amounts of 5-methylcytosine.     

The bisulfite genomic sequencing used in the analysis of epigenetic states, a technique in the emerging environmental genotoxicology research

Methylation at position 5 of cytosine in DNA is an important event in epigenetic changes of cells, the methylation being linked to the control of gene functions. The DNA methylation can be analyzed by bisulfite genomic sequencing, and a large body of data have now been accumulated, based on which causation of diseases, for example cancer, and many other manifestations of cellular activities have been discussed intensively. This article gives an extensive account of the chemical aspects of bisulfite modification of cytosine and 5-methylcytosine in DNA. Various factors that affect the action of bisulfite are discussed, and a recent progress from our laboratory is explained. Conventional procedures for the bisulfite treatment consist incubation of single-stranded DNA with sodium bisulfite under acidic conditions. This treatment converts cytosine into uracil, but 5-methylcytosine remains unchanged. Amplification by polymerase chain reaction (PCR) of the bisulfite-treated DNA followed by sequencing can result in revealing the positions of 5-methylcytosine in the gene. We have discovered that the whole procedure can be significantly speeded up by the use of a highly concentrated bisulfite solution, 10 M ammonium bisulfite. Another recent finding is that urea, which has been often added to the reaction mixture with the purpose of facilitating the bisulfite-mediated deamination of cytosine in DNA, may not work as anticipated: we have observed that urea does not show such promoting actions in our treatments of DNA. A laboratory protocol for quantifying bisulfite, suitably simple for routine practice to ensure valid experiments, is described.     

Pyrimidine-specific chemical reactions useful for DNA sequencing.

Potassium permanganate reacts selectively with thymidine residues in DNA (1) while hydroxylamine hydrochloride at pH 6 specifically attacks cytosine (2). We have adopted these reactions for use with the chemical sequencing method developed by Maxam and Gilbert (3).     

High-Speed Conversion of Cytosine to Uracil in Bisulfite Genomic Sequencing Analysis of DNA Methylation

Bisulfite genomic sequencing is a widely used technique foranalyzing cytosine-methylation of DNA. By treating DNA withbisulfite, cytosine residues are deaminated to uracil, whileleaving 5-methylcytosine largely intact. Subsequent PCR andnucleotide sequence analysis permit unequivocal determinationof the methylation status at cytosine residues. A major caveatassociated with the currently practiced procedure is that ittakes 16–20 hr for completion of the conversion of cytosineto uracil. Here we report that a complete deamination of cytosineto uracil can be achieved in shorter periods by using a highlyconcentrated bisulfite solution at an elevated temperature.Time course experiments demonstrated that treating DNA with9 M bisulfite for 20 min at 90°C or 40 min at 70°C allcytosine residues in the DNA were converted to uracil. Underthese conditions, the majority of 5-methylcytosines remainedintact. When a high molecular weight DNA derived from a cellline (containing a number of genes whose methylation statuswas known) was treated with bisulfite under the above conditionsand amplified and sequenced, the results obtained were consistentwith those reported in the literature. Although some degradationof DNA occurred during this process, the amount of treated DNArequired for the amplification was nearly equal to that requiredfor the conventional bisulfite genomic sequencing procedure.The increased speed of DNA methylation analysis with this novelprocedure is expected to advance various aspects of DNA sciences.     

Analysis of 5-methylcytosine in DNA: II. Gas chromatography

A method for analyzing 5-methylcytosine in DNA by gas chromatography is described. The method is based on degradation of the DNA to its free bases by treatment with trifluoroacetic acid and gas chromatography of the trimethylsilyl derivatives of the free bases. Chromatography of microgram amounts of derivatized material is conducted at isothermal conditions using a 3% SE-30 or 2% OV-225 column. The peak areas corresponding to cytosine and 5-methylcytosine are used to calculate the 5-methylcytosine/cytosine molar ratio in DNA. The lower limit for detection of 5-methylcytosine in DNA by this method is a 5-methylcytosine/cytosine molar ratio of 0.001.     

DNA of Drosophila melanogaster contains 5-methylcytosine

It is commonly accepted that the DNA of Drosophila melanogaster does not contain 5-methylcytosine, which is essential in the development of most eukaryotes. We have developed a new, highly specific and sensitive assay to detect the presence of 5-methylcytosine in genomic DNA. The DNA is degraded to nucleosides, 5-methylcytosine purified by HPLC and, for detection by 1D- and 2D-TLC, radiolabeled using deoxynucleoside kinase and [gamma-(32)P]ATP. Using this assay, we show here that 5-methylcytosine occurs in the DNA of D. melanogaster at a level of approximately 1 in 1000-2000 cytosine residues in adult flies. DNA methylation is detectable in all stages of D.melanogaster development.     

Organization of 5-methylcytosine in chromosomal DNA

The 5-methylcytosine residues of L-cells have been labeled with [methyl-3H]-L-methionine and their chromatin localization studied using deoxyribonucleases. The kinetics of micrococcal nuclease digestion showed that the methylated cytosine residues are concentrated within regions resistant to nuclease digestion and preferentially missing from those regions between nucleosomes which are nuclease sensitive. Using DNA hybridization kinetic analysis, it is shown that 5-methylcytosine is abundant in highly repeated sequences but is also present in middle repetitive and unique sequence DNA.     

Quantitative determination of 5-methylcytosine in DNA by reverse-phase high-performance liquid chromatography

A method to separate the four major bases (cytosine, guanine, thymine and adenine) and the two minor modified bases (5-methylcytosine and 6N-methyladenine) in DNA has been developed. For optimal separation, several different buffer systems are available for isocratic elution. The 12 5-methylcytosine (5-mC) residues in the plasmid pBR322 can be determined with a deviation of less than 3% of the expected value and have been used for internal standardization. Formic acid hydrolysis of bases and probably of DNA does not lead to the deamination of cytosine or 5-mC and thus can be used routinely for DNA hydrolysis. Adenovirus or baculovirus DNA does not contain detectable amounts of 5-mC. The distribution of 5-mC in hamster cell DNA appears to be nonrandom in that different 5'-CpG-3'-containing restriction sites are methylated to different extents.     

Detection of 5-methylcytosine in DNA sequences.

Col E1 DNA has methylated cytosine in the sequence 5'-CC*(A/T)GG-3' and methylated adenine in the sequence 5'-GA*TC-3' at the positions indicated by asterisks(*). When the Maxam-Gilbert DNA sequencing method is applied to this DNA, the methylated cytosine (5-methylcytosine) is found to be less reactive to hydrazine than are cytosine and thymine, so that a band corresponding to that base does not appear in the pyrimidine cleavage patterns. The existence of the methylated cytosine can be confirmed by analyzing the complementary strand or unmethylated DNA. In contrast, the methylated adenine (probably N6-methyladenine) cannot be distinguished from adenine with standard conditions for cleavage at adenine.     

Identification and resolution of artifacts in bisulfite sequencing

Bisulfite sequencing has become the most widely used application to detect 5-methylcytosine (5-MeC) in DNA, and provides a reliable way of detecting any methylated cytosine at single-molecule resolution in any sequence context. The process of bisulfite treatment exploits the different sensitivity of cytosine and 5-MeC to deamination by bisulfite under acidic conditions, in which cytosine undergoes conversion to uracil while 5-MeC remains unreactive. In this article, we address the more commonly encountered experimental artifacts associated with bisulfite sequencing, and provide methods for the detection and elimination of these artifacts. In particular, we focus on conditions that inhibit complete bisulfite-mediated conversion of cytosines in a target sequence, and demonstrate the necessity of complete protein removal from DNA samples prior to bisulfite treatment. We also include a brief summary of the experimental protocol for bisulfite treatment and tips for designing polymerase chain reaction (PCR) primers to amplify from bisulfite-treated DNA.     

Novel procedure for the detection of 5-methylcytosine.

Bisulfite converts non-methylated cytosine in DNA to uracil leaving 5-methylcytosine unaltered. In this communication, we present a new approach omitting the conventional PCR amplification step. Bisulfite-converted methylated DNA is directly sequenced. The effectiveness of the new protocol is demonstrated by using it for the detection of 5-methylation of cytosine residues introduced by three different DNA methyltransferases (M.HaeIII, M.HpaII and M.HhaI). A simple experimental system useful to determine the sequence specificity of DNA methyltransferases is also presented.     

Developmentally regulated DNA methylation in Dictyostelium discoideum

Methylation of cytosine residues in DNA plays a critical role in the silencing of gene expression, organization of chromatin structure, and cellular differentiation of eukaryotes. Previous studies failed to detect 5-methylcytosine in Dictyostelium genomic DNA, but the recent sequencing of the Dictyostelium genome revealed a candidate DNA methyltransferase gene (dnmA). The genome sequence also uncovered an unusual distribution of potential methylation sites, CpG islands, throughout the genome. DnmA belongs to the Dnmt2 subfamily and contains all the catalytic motifs necessary for cytosine methyltransferases. Dnmt2 activity is typically weak in Drosophila melanogaster, mouse, and human cells and the gene function in these systems is unknown. We have investigated the methylation status of Dictyostelium genomic DNA with antibodies raised against 5-methylcytosine and detected low levels of the modified nucleotide. We also found that DNA methylation increased during development. We searched the genome for potential methylation sites and found them in retrotransposable elements and in several other genes. Using Southern blot analysis with methylation-sensitive and -insensitive restriction endonucleases, we found that the DIRS retrotransposon and the guaB gene were indeed methylated. We then mutated the dnmA gene and found that DNA methylation was reduced to about 50% of the wild-type level. The mutant cells exhibited morphological defects in late development, indicating that DNA methylation has a regulatory role in Dictyostelium development. Our findings establish a role for a Dnmt2 methyltransferase in eukaryotic development.     

Unusual properties of the DNA from Xanthomonas phage XP-12 in which 5-methylcytosine completely replaces cytosine.

Xanthomonas phage XP-12 contains 5-methylcytosine completely replacing cytosine. This substitution confers several unusual properties upon XP-12 DNA. The buoyant density of XP-12 DNA in CsCl gradients is 1.710 g/cm-3, 0.16 g/cm-3 lower than that expected for a normal DNA with the same percentage of adenine plus thymine. The melting temperature for XP-12 DNA in 0.012 M Na+ is the highest reported for any naturally occurring DNA, 83.2 degrees C, 6.1 degrees C higher than that of normal DNAs with the same percentage of adenine plus thymine. Unlike the minor amounts of 5-methylcytosine found in most plant and animal DNAs, the 5-methylcytosine residues of XP-12 derive their methyl group from the 3-carbon of serine instead of from the thiomethyl carbon of methionine. .     

Oxidative damage to 5-methylcytosine in DNA.

Exposure of pyrimidines of DNA to ionizing radiation under aerobic conditions or oxidizing agents results in attack on the 5,6 double bond of the pyrimidine ring or on the exocyclic 5-methyl group. The primary product of oxidation of the 5,6 double bond of thymine is thymine glycol, while oxidation of the 5-methyl group yields 5-hydroxymethyluracil. Oxidation of the 5,6 double bond of cytosine yields cytosine glycol, which decomposes to 5-hydroxycytosine, 5-hydroxyuracil and uracil glycol, all of which are repaired in DNA by Escherichia coli endonuclease III. We now describe the products of oxidation of 5-methylcytosine in DNA. Poly(dG-[3H]dmC) was gamma-irradiated or oxidized with hydrogen peroxide in the presence of Fe3+ and ascorbic acid. The oxidized co-polymer was incubated with endonuclease III or 5-hydroxymethyluracil-DNA glycosylase, to determine whether repairable products were formed, or digested to 2'-deoxyribonucleosides, to determine the total complement of oxidative products. Oxidative attack on 5-methylcytosine resulted primarily in formation of thymine glycol. The radiogenic yield of thymine glycol in poly(dG-dmC) was the same as that in poly(dA-dT), demonstrating that 5-methylcytosine residues in DNA were equally susceptible to radiation-induced oxidation as were thymine residues.