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.     

Specificity of methylation of cytosine risidues in DNA of Bacillus brevis var. G-B]

On growing the cells of Bacillus brevis S methionine-auxotroph mutant in the presence of (methyl-3H)-methionine practically the total radioactivity included into DNA is found to exist in 5-methylcytosine (MC) and 6N-methyladenine (MA). The analysis of pyrimidine isopliths isolated from DNA shows that radioactivity only exists in mono- and dinucleotides and the content of MC in Pur-MC-Pur and Pur-MC-T-Pur oligonucleotides is equal. The analysis of dinucleotides isolated from DNA by means of pancreatic DNAase hydrolysis allows the nature of purine residues neighbouring with MC to be revealed and shows that MC localizes in G-MC-A and G-MC-T-Pu fragments. Bac. brevis S DNA-methylase modifying cytosine residues recognizes the GCAT GC degenerative nucleotide sequence which is a part of the following complementary structure with rotational symmetry: (5') ... N'--G--MC--T--G--C--N ... (3') (3') ... N--C--G--A--MC--G--N' ... (5') Cytosine modifying DNA-methylase activity is isolated from Bac. brevis cells; it is capable of methylating in vitro homologous and heterologous DNA. Hence, DNA in bacterial cells can be partially undermethylated. This enzyme methylates cytosine residues in native and deneaturated DNA in the same nucleotide sequences. As compared to the native DNA, the denaturated DNA is indicative of a decrease in the level of methylation of adenine, rather than cytosine residues. Specificity of methylation of cytosine residues in vitro and in vivo does not depend on the nature of substrate DNA (calf thymus, Pseudomonas aeruginosa etc.). DNA-methylases of different variants of Bac. brevis (R, S, P+, P-) methylate cytosine residues in the same nucleotide sequences. It means that specificity of methylation of DNA cytosine residues in the cells of different variants of Bac. brevis is the same.     

DNA methylation. Inhibition of de novo and maintenance methylation in vitro by RNA and synthetic polynucleotides

A partially purified HeLa cell DNA methylase will methylate a totally unmethylated DNA (de novo methylation) at about 3-4% the rate it will methylate a hemimethylated DNA template (maintenance methylation). Our evidence suggests that many, if not most, dCpdG sequences in a natural or synthetic DNA can be methylated by the enzyme. There is a powerful inhibitor of DNA methylase activity in crude extracts which has been identified as RNA. The inhibition of DNA methylase by RNA may indicate that this enzyme is regulated in vivo by the presence of RNA at specific chromosomal sites. The pattern of binding of RNA to DNA in the nucleosome structure and the DNA replication complex may determine specific sites of DNA methylation. An even more potent inhibition of DNA methylase activity is observed with poly(G), but not poly(C), poly(A), or poly(U). The only other synthetic polynucleotides studied which inhibit DNA methylation as well as poly(G) are the homopolymers poly(dC).poly(dG) and poly (dA).poly(dT). These results point out the unique importance of the guanine residue itself in the binding of the DNA methylase to dCpdG, the site of cytosine methylation. The surprising inhibition of the methylation reaction by poly(dA).poly(dT), which is itself not methylated by the enzyme, suggests the possible involvement of adjacent A and T residues in influencing the choice of sites of methylation by the enzyme.     

Procaryotic and eucaryotic traits of DNA methylation in spiroplasmas (mycoplasmas).

Differences in the type of base methylated (cytosine or adenine) and in the extent of methylation were detected by high-pressure liquid chromatography in the DNAs of five spiroplasmas. Nearest neighbor analysis and digestion by restriction enzyme isoschizomers also revealed differences in methylation sequence specificity. Whereas in Spiroplasma floricola and Spiroplasma sp. strain PPS-1 5-methylcytosine was found on the 5' side of each of the four major bases, the cytosine in Spiroplasma apis DNA was methylated only when its 3' neighboring base was adenine or thymine. In Spiroplasma sp. strain MQ-1 over 95% of the methylated cytosine was in C-G sequences. Essentially all of the C-G sequences in the MQ-1 DNA were methylated. Partially purified extracts of S. apis and Spiroplasma sp. strain MQ-1 were used to study substrate and sequence specificity of the methylase activity. Methylation by the MQ-1 enzyme was exclusively at C-G sequences, resembling in this respect eucaryotic DNA methylases. However, the MQ-1 methylase differed from eucaryotic methylases by showing high activity on nonmethylated DNA duplexes, low activity with hemimethylated DNA duplexes, and no activity on single-stranded DNA.     

DNA-methylase from regenerating rat liver: purification and characterisation.

DNA methylase has been purified 660-fold from nuclei from regenerating rat liver. The enzyme is able to methylate single stranded (ss) and double stranded (ds) DNA, the only reaction product being 5-methylcytosine. Previously unmethylated double stranded DNA from prokaryotes (M.luteus) as well as from eukaryotes (Ascaris suis) can serve as substrates. The synthetic copolymers (dG-dC)n . (dC-dG)n and (dG,dC)n are also methylated. While SV40 DNA is almost not methylated, PM2 DNA is a good substrate even in the supercoiled form. The enzyme methylates 1 in 17 bases in heterologous M.luteus DNA, but only 1 in 590 in homologous rat liver DNA. The high methylation level of M.luteus DNA, an analysis of the methylated pyrimidine isostichs and a preliminary dinucleotide analysis suggest that all the CpGs in a DNA can be methylated.     

DNA methylation: sequences flanking C-G pairs modulate the specificity of the human DNA methylase.

Synthetic single-stranded oligodeoxynucleotides of known sequence have been used as in vitro substrates for a partially purified HeLa cell DNA methylase. Although most oligonucleotides tested cannot be used by the HeLa DNA methylase in vitro, we have found a unique 27mer, containing 2 C-G pairs, that is an excellent substrate for the enzyme. Analysis of the methylation of the 27mer, its derivatives and other oligomer substrates reveal that the HeLa DNA methylase does not significantly methylate an oligomer which contains just one C-G pair. In addition, only one of the two C-G pairs in the 27mer is methylated and this methylation is abolished if the other C-G pair is converted to a C-A pair. Furthermore, the HeLa enzyme apparently cannot methylate C-G pairs located in compounds containing a high A + T content. The most efficient methylation occurs with multiple separated C-G pairs in a compound with a high G + C content (greater than 65%). The results suggest that clustering of C-G pairs in regions of the DNA high in G + C content may be the preferred site for DNA methylation in vivo.     

Enzymes from Micrococcus luteus involved in the initial steps of excision repair of spontaneous DNA lesions: uracil-DNA-glycosidase and apurinic-endonucleases.

Uracil-DNA-glycosidase that releases free uracil from single-stranded or double-stranded deaminated DNA and poly d(A-U) has been partially purified from Micrococcus luteus. The enzyme has a molecular weight of about 16,000 and can be separated from uracil-endonuclease and endonucleases (AP-endonucleases) specific for apurinic and apyrimidinic sites. Uracil-DNA-glycosidase does not act on guanine residues opposite uracil in double-stranded DNA and on xanthine in deaminated DNA. The glycosidase generates apyrimidinic sites which can serve as substrate sites for different AP-endonucleases from M. luteus.     

Methylation of specific cytosine residues enhances simian virus 40 T-antigen binding to origin region DNA.

Specific binding of simian virus 40 large T antigen to origin region DNA requires the interaction of T antigen with multiples of a consensus recognition pentanucleotide sequence (5'-G[T]-A[G]-G-G-C-3'). To assess the interaction of T antigen with cytosine residues in the recognition sequences, bacterial methylases were used to methylate simian virus 40 form I DNA in vitro at specific cytosine residues. Methylation of a subset of the cytosine residues in the pentanucleotide sequences resulted in enhanced binding of T antigen to origin region DNA. Enhanced binding to the methylated pentanucleotides indicates that the methyl groups introduced on this subset of pentanucleotide cytosine residues could not have sterically interfered with the interaction of T antigen with the recognition sequences. This lack of steric interference suggests that T antigen does not make close contact in the major groove with these particular cytosine residues during normal binding.     

Enzymic removal of 5-methylcytosine from poly(dG-5-methyl-dC) by HeLa cell nuclear extracts is not by a DNA glycosylase.

A recent report in this journal [Vairapandi, M. and Duker, N.J. (1993) Nucleic Acids Res. 21, 5323-5327) presented evidence of an activity in HeLa cell nuclear extracts that released radiolabeled material from a poly(dG.dC) polymer that had been methylated and simultaneously labeled on cytosine residues by incubation with a CpG-specific DNA methylase and [methyl-3H]S-adenosylmethionine. Based on chromatographic evidence that the released products were thymine and 5-methylcytosine and on f1p4olabeling data suggesting a concomitant increase in abasic sites, the authors concluded that the releasing activity was a 5-methylcytosine-specific glycosylase and that the solubilized 5-methylcytosine was converted to thymine by a nuclear deaminase. We have confirmed that HeLa nuclear extracts promote release of ethanol-soluble radioactivity from a methyl-labeled poly(dG-5-methyl-dC)polymer, but the products released were neither 5-methylcytosine nor thymine. Furthermore, free 5-methylcytosine was not deaminated by incubation with the nuclear extract. The labeled compound released initially from the polymer appeared to be 5-methyl-deoxycytidine monophosphate, which was converted to 5-methyl-deoxycytidine, thymidine monophosphate, and/or thymidine by further incubation with the nuclear extract. The activity responsible for the release, therefore, was a nuclease. Release of 32P-labeled nucleotides from a 32P-labeled poly(dG-dC) polymer suggested, furthermore, that the activity was not specific for methylated DNA.     

The use of permanganate as a sequencing reagent for identification of 5-methylcytosine residues in DNA.

The use of permanganate as a reagent for DNA sequencing by chemical degradation has been studied with respect to its specificity for 5-methylcytosine residues. At weakly acidic pH and room temperature, 0.2 mM potassium permanganate reacts preferentially with thymine, 5-methylcytosine, and to a lesser extent with purine residues, while cytosine remains essentially intact. Permanganate oxidation is, therefore, a suitable DNA sequencing reaction for positive discrimination between 5-methylcytosine and unmethylated cytosine.     

DNA helicase IV from HeLa cells.

Human DNA helicase IV, a novel enzyme, was purified to homogeneity from HeLa cells and characterized. The activity was measured by assaying the unwinding of 32P labeled 17-mer annealed to M13 ss DNA. From 440g of HeLa cells we obtained 0.31 mg of pure protein. Helicase IV was free of DNA topoisomerases, DNA ligase and nuclease activities. The apparent molecular weight is 100 kDa. It requires a divalent cation for activity (Mg2+ = Mn2+ = Zn2+) and the hydrolysis of only ATP or dATP. The activity is destroyed by trypsin and is inhibited by 200 mM KCl or NaCl, 100 mM potassium phosphate, 45 mM ammonium sulfate, 5 mM EDTA, 20 microM ss M13 DNA or 20 microM poly [G] (as phosphate). The enzyme unwinds DNA by moving in the 5' to 3' direction along the bound strand, a polarity opposite to that of the previously described human DNA helicase I (Tuteja et al Nucleic Acids Res. 18, 6785-6792, 1990). It requires more than 84 bases of single-stranded DNA in order to exert its unwinding activity and does not require a replication fork-like structure. Like human DNA helicase I the enzyme can also unwind RNA-DNA hybrid.     

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.     

Sequence specificity of DNA adenine methylase in the protozoan Tetrahymena thermophila.

The sequence specificity of the Tetrahymena DNA-adenine methylase was determined by nearest-neighbor analyses of in vivo and in vitro methylated DNA. In vivo all four common bases were found to the 5' side of N6-methyladenine, but only thymidine was 3'. Homologous DNA already methylated in vivo and heterologous Micrococcus luteus DNA were methylated in vitro by a partially purified DNA-adenine methylase activity isolated from Tetrahymena macronuclei. The in vitro-methylated sequence differed from the in vivo sequence in that both thymidine and cytosine were 3' nearest neighbors of N6-methyladenine.     

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.     

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.     

M.FokI methylates adenine in both strands of its asymmetric recognition sequence

M.FokI, a type-IIS modification enzyme from Flavobacterium okeanokoites, was purified, and its activity was characterized in vitro. The enzyme was found to be a DNA-adenine methyltransferase and to methylate both strands of the asymmetric FokI recognition sequence: (formula; see text) M.FokI does not methylate single-stranded DNA, nor does it methylate double-stranded DNA at sequences other than FokI sites.     

Mutants of the N-3 R-Factor Conditionally Defective in hspII Modification and Deoxyribonucleic Acid-Cytosine Methylase Activity

The N-3 drug resistance (R) factor specifies a deoxyribonucleic acid (DNA)-cytosine methylase and a DNA restriction-modification (hspII) system. We have isolated three independent mutants that are conditionally defective in their ability to modify bacteriophage lambda and to methylate DNA-cytosine residues. The ratio of 5-methylcytosine to N(6)-methyladenine in bacterial DNA and in the DNA of phages lambda and fd was determined after labeling with [methyl-(3)H]methionine at various growth temperatures. Although the ability of the wild-type N-3 factor to modify phage lambda and to methylate DNA-cytosine residues was unaffected with increasing temperature, two of the mutants exhibited a parallel loss in modification and cytosine methylation ability. The ability of the third mutant to carry out these functions was dependent on the presence or absence of an amber suppressor mutation in the host genome. These results offer further support for the notion that hspII modification is mediated by a DNA-cytosine methylase. Evidence is also presented that the modification methylase is responsible for the in vivo methylation of phage fd DNA (which is not subject to hspII restriction in vivo).     

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 substrate specificity of DNA methyltransferases. adenine-N6 DNA methyltransferases also modify cytosine residues at position N4

Methylation of DNA is important in many organisms and essential in mammals. Nucleobases can be methylated at the adenine-N6, cytosine-N4, or cytosine-C5 atoms by specific DNA methyltransferases. We show here that the M.EcoRV, M.EcoRI, and Escherichia coli dam methyltransferases as well as the N- and C-terminal domains of the M. FokI enzyme, which were formerly all classified as adenine-N6 DNA methyltransferases, also methylate cytosine residues at position N4. Kinetic analyses demonstrate that the rate of methylation of cytosine residues by M.EcoRV and the M.FokI enzymes is reduced by only 1-2 orders of magnitude in relation to methylation of adenines. This result shows that although these enzymes methylate DNA in a sequence specific manner, they have a low substrate specificity with respect to the target base. This unexpected finding has implications on the mechanism of adenine-N6 DNA methyltransferases. Sequence comparisons suggest that adenine-N6 and cytosine-N4 methyltransferases have changed their reaction specificity at least twice during evolution, a model that becomes much more likely given the partial functional overlap of both enzyme types. In contrast, methylation of adenine residues by the cytosine-N4 methyltransferase M.BamHI was not detectable. On the basis of our results, we suggest that adenine-N6 and cytosine-N4 methyltransferases should be grouped into one enzyme family.     

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.