2-Pyrimidinone as a probe for studying the EcoRII DNA methyltransferase-substrate interaction.

EcoRII DNA methyltransferase (M.EcoRII) recognizes the 5' em leader CC*T/AGG em leader 3' DNA sequence and catalyzes the transfer of the methyl group from S-adenosyl-l-methionine to the C5 position of the inner cytosine residue (C*). Here, we study the mechanism of inhibition of M.EcoRII by DNA containing 2-pyrimidinone, a cytosine analogue lacking an NH(2) group at the C4 position of the pyrimidine ring. Also, DNA containing 2-pyrimidinone was used for probing contacts of M.EcoRII with functional groups of pyrimidine bases of the recognition sequence. 2-Pyrimidinone was incorporated into the 5' em leader CCT/AGG em leader 3' sequence replacing the target and nontarget cytosine and central thymine residues. Study of the DNA stability using thermal denaturation of 2-pyrimidinone containing duplexes pointed to the influence of the bases adjacent to 2-pyrimidinone and to a greater destabilizing influence of 2-pyrimidinone substitution for thymine than that for cytosine. Binding of M.EcoRII to 2-pyrimidinone containing DNA and methylation of these DNA demonstrate that the amino group of the outer cytosine in the EcoRII recognition sequence is not involved in the DNA-M.EcoRII interaction. It is probable that there are contacts between the functional groups of the central thymine exposed in the major groove and M.EcoRII. 2-Pyrimidinone replacing the target cytosine in the EcoRII recognition sequence forms covalent adducts with M.EcoRII. In the absence of the cofactor S-adenosyl-l-methionine, proton transfer to the C5 position of 2-pyrimidinone occurs and in the presence of S-adenosyl-l-methionine, methyl transfer to the C5 position of 2-pyrimidinone occurs.     

Measurement of DNA methylase activity by tritium release from DNA cytosine

The advantages of assaying of DNA methylase by measuring the transfer to water of tritium from the 5 position of DNA cytosine, rather than the transfer to DNA of labeled methyl groups are discussed.     

Hemimethylated duplex DNAs prepared from 5-azacytidine-treated cells.

Duplex heavy-light (HL) DNAs synthesized in the presence of brdUrd and methylation inhibitors were separated from bulk cellular DNA by CsCl density gradient centrifugation and analysed for 5-methylcytosine (5mC) contents by HPLC. DNAs synthesized in the presence of 5 mM ethionine or 2 mg/ml cycloleucine were not detectably hypomethylated, was undermethylated with respect to control DNA. The heavy, or H-strand, in which up to 5% of the cytosine residues were replaced by intact 5-azacytosine, was undermethylated and the HL duplex DNA was therefore strand asymmetrically methylated. This duplex DNA served as an efficient substrate for a crude DNA methyltransferase preparation which transferred the methyl group from S-adenosylmethionine specifically into cytosine residues within the hypomethylated H strand. Increasing levels of incorporated 5-azacytosine inhibited the action of the methyltransferase suggesting that incorporation of 5-azacytosine into DNA may be responsible for the inhibitory effect of 5-azacytidine on DNA methylation.     

A novel method to assess the full genome methylation profile using monoclonal antibody combined with the high throughput based microarray approach

In this work we demonstrate a novel method of methylation detection that utilises immunoaffinity to detect the presence of methylated DNA hybridised to a cDNA microarray. We use a monoclonal antibody specific to 5 methyl cytidine to detect the presence of 5 methyl cytosine in genomic DNA from human fibroblasts bearing the karyotype 45 XO. We report that over 2900 genes show the presence of methylation in this condition. We also report that 165 genes are consistently methylated in all replicates of these experiments. The methylated genes show a uniform distribution over all the chromosomes. The gene ontology of these also indicates no functional correlation between the genes that are methylated. We detect the presence of methylation in IGF2, an imprinted gene and thus known to harbour DNA methylation. The method is extremely specific and offers a quick and efficient way to analyse the methylation landscape on a high throughput scale. This method uses existing technology to assess methylation and thus can integrate very efficiently into any platform used.     

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.     

The kinetics of DNA methylation in cultures of a mouse adrenal cell line

Direct measurements of the methylation of newly-synthesized DNA were made in cultures of a clonal mouse adrenal cortex cell line, Y129OS3, by (1) following the incorporation of radioactivity from methionine-(methyl)-C¹⁴ into a segment of DNA which had been density-labeled with bromouracil and (2) labeling DNA cytosine with C¹⁴-deoxycytidine and then following the appearance of radioactivity in DNA 5-methylcytosine. The results establish that during exponential growth the DNA of this cell line is methylated entirely within a few minutes of its synthesis. Using the second technique described above accurate, sensitive measurements of DNA methylation levels can be made by comparing radioactivity in 5-methylcytosine to radioactivity in cytosine plus 5-methylcytosine. In this cell line 5-methylcytosine accounts for 4.3 ± 0.2% of the DNA cytosine. Some apparent contradictions between these results and those of other workers are discussed.     

Sensitive detection of 5-methylcytosine and quantitation of the 5-methylcytosine/cytosine ratio in DNA by gas chromatography--mass spectrometry using multiple specific ion monitoring.

A method combining gas chromatography and mass spectrometry (GC-MS) with multiple specific ion monitoring has been developed for the detection of 5-methylcytosine and the quantitation of the ratio of methyleytosine to cytosine in DNA. The trimethylsilyl derivatives of cytosine and 5-methylcytosine obtained from DNA hydrolysates are separated by isothermal elution on an OV-225 column and detected by specific ion monitoring in a DuPont 321 mass spectrometer. As little as 1.6 pmol of 5-methylcytosine in Φ_χ174 DNA can be detected, corresponding to a tenfold improvement in sensitivity over that obtained by conventional techniques. The ratio of 5-methylcytosine to cytosine of DNA from φ_χ174, calf thymus, salmon sperm, and several mouse tissues has also been determined. The results agree well with those obtained by other methods.     

DNA甲基化及其对植物发育的调控

DNA甲基化属于一种表观遗传修饰,主要发生在CpG双核苷酸序列中的胞嘧啶上,是在DNA甲基转移酶催化下,以S-腺苷甲硫氨酸为甲基供体,将甲基转移到胞嘧啶上,生成5-甲基胞嘧啶的一种反应。DNA甲基化在植物生长过程中具有极其重要的作用。综述了植物DNA甲基化的特征、调控机制,及其对植物基因表达影响的研究进展。     

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 duplexes containing photoactive derivatives of 2'-deoxyuridine as photocrosslinking probes for EcoRII DNA methyltransferase-substrate interaction

EcoRII DNA methyltransferase (M.EcoRII) recognizes the DNA sequence 5'.CC*T/AGG.3' and catalyzes the transfer of the methyl group from S-adenosyl-L-methionine to the C5 position of the inner cytosine residue (C*). We obtained several DNA duplexes containing photoactive 5-iodo-2'-deoxyuridine (i(5)dU) or 5-[4-(3-(trifluoromethyl)-3H-diazirin-3-yl)phenyl]-2'-deoxyuridine (Tfmdp-dU) to characterize regions of M.EcoRII involved in DNA binding and to investigate the DNA double helix conformational changes that take place during methylation. The efficiencies of methylation, DNA binding affinities and M.EcoRII-DNA photocrosslinking yields strongly depend on the type of modification and its location within the EcoRII recognition site. The data obtained agree with the flipping of the target cytosine out of the DNA double helix for catalysis. To probe regions of M.EcoRII involved in DNA binding, covalent conjugates M.EcoRII-DNA were cleaved by cyanogen bromide followed by analysis of the oligonucleotide-peptides obtained. DNA duplexes containing i(5)dU or Tfmdp-dU at the central position of the recognition site, or instead of the target cytosine were crosslinked to the Gly(268)-Met(391) region of the EcoRII methylase. Amino acid residues from this region may take part both in substrate recognition and stabilization of the extrahelical target cytosine residue.     

Substitutions of a cysteine conserved among DNA cytosine methylases result in a variety of phenotypes.

The proposed mechanism for DNA (cytosine-5)-methyltransferases envisions a key role for a cysteine residue. It is expected to form a covalent link with carbon 6 of the target cytosine, activating the normally inactive carbon 5 for methyl transfer. There is a single conserved cysteine among all DNA (cytosine-5)-methyltransferases making it the candidate nucleophile. We have changed this cysteine to other amino acids for the EcoRII methylase; which methylates the second cytosine in the sequence 5'-CCWGG-3'. Mutants were tested for their methyl transferring ability and for their ability to form covalent complexes with DNA. The latter property was tested indirectly with the use of a genetic assay involving sensitivity of cells to 5-azacytidine. Replacement of the conserved cysteine with glycine, valine, tryptophan or serine led to an apparent loss of methyl transferring ability. Interestingly, cells carrying the mutant with serine did show sensitivity to 5-azacytidine, suggesting the ability to link to DNA. Unexpectedly, substitution of the cysteine with glycine results in the inhibition of cell growth and the mutant allele can be maintained in the cells only when it is poorly expressed. These results suggest that the conserved cysteine in the EcoRII methylase is essential for methylase action and it may play more than one role in it.     

Sequence-specific and mechanism-based crosslinking of Dcm DNA cytosine-C5 methyltransferase of E. coli K-12 to synthetic oligonucleotides containing 5-fluoro-2'-deoxycytidine.

The product of the dcm gene is the only DNA cytosine-C5 methyltransferase of Escherichia coli K-12; it catalyses transfer of a methyl group from S-adenosyl methionine (SAM) to the C-5 position of the inner cytosine residue of the cognate sequence CCA/TGG. Sequence-specific, covalent crosslinking of the enzyme to synthetic oligonucleotides containing 5-fluoro-2'-deoxycytidine is demonstrated. This reaction is abolished if serine replaces the cysteine at residue #177 of the enzyme. These results lend strong support to a catalytic mechanism in which an enzyme sulfhydryl group undergoes Michael addition to the C5-C6 double bond, thus activating position C-5 of the substrate DNA cytosine residue for electrophilic attack by the methyl donor SAM. The enzyme is capable of self-methylation in a DNA-independent reaction requiring SAM and the presence of cysteine at position #177.     

The bZIP mutant CEBPB (V285A) has sequence specific DNA binding propensities similar to CREB1

The bZIP homodimers CEBPB and CREB1 bind DNA containing methylated cytosines differently. CREB1 binds stronger to the C/EBP half-site GCAA when the cytosine is methylated. For CEBPB, methylation of the same cytosine does not affect DNA binding. The X-ray structure of CREB1 binding the half site GTCA identifies an alanine in the DNA binding region interacting with the methyl group of T, structurally analogous to the methyl group of methylated C. This alanine is replaced with a valine in CEBPB. To explore the contribution of this amino acid to binding with methylated cytosine of the GCAA half-site, we made the reciprocal mutants CEBPB(V285A) and CREB1(A297V) and used protein binding microarrays (PBM) to examine binding to four types of double-stranded DNA (dsDNA): 1) DNA with cytosine in both strands (DNA(C|C)), 2) DNA with 5-methylcytosine (M) in one strand and cytosine in the second strand (DNA(M|C)), 3) DNA with 5-hydroxymethylcytosine (H) in one strand and cytosine in the second strand (DNA(H|C)), and 4) DNA with both cytosines in all CG dinucleotides containing 5-methylcytosine (DNA(5mCG)). When binding to DNA(C|C), CEBPB (V285A) preferentially binds the CRE consensus motif (TGACGTCA), similar to CREB1. The reciprocal mutant, CREB1(A297V) binds DNA with some similarity to CEBPB, with strongest binding to the methylated PAR site 8-mer TTACGTAA. These data demonstrate that V285 residue inhibits CEBPB binding to methylated cytosine of the GCAA half-site.     

M.HhaI binds tightly to substrates containing mismatches at the target base.

The (cytosine-5) DNA methyltransferase M.HhaI causes its target cytosine base to be flipped completely out of the DNA helix upon binding. We have investigated the effects of replacing the target cytosine by other, mismatched bases, including adenine, guanine, thymine and uracil. We find that M.HhaI binds more tightly to such mismatched substrates and can even transfer a methyl group to uracil if a G:U mismatch is present. Other mismatched substrates in which the orphan guanine is changed exhibit similar behavior. Overall, the affinity of DNA binding correlates inversely with the stability of the target base pair, while the nature of the target base appears irrelevant for complex formation. The presence of a cofactor analog. S-adenosyl-L-homocysteine, greatly enhances the selectivity of the methyltransferase for cytosine at the target site. We propose that the DNA methyltransferases have evolved from mismatch binding proteins and that base flipping was, and still is, a key element in many DNA-enzyme interactions.     

MBD结构域和SRA结构域识别甲基化DNA的结构机理

DNA胞嘧啶5-甲基化修饰是表观遗传重要的修饰之一,其对基因表达的调控依赖下游的识别蛋白识别和传递甲基化信号.本文围绕两种主要的甲基化DNA识别结构域——MBD结构域和SRA结构域,综述了它们识别不同修饰形式DNA的结构基础以及发挥功能的分子机理.     

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.     

Investigation of restriction-modification enzymes from M. varians RFL19 with a new type of specificity toward modification of substrate.

The characterization of MvaI restriction-modification enzymes, isolated from Micrococcus varians RFL19, is reported. Both enzymes recognize the 5'CC decreases (A/T)GG nucleotide sequence. The endonuclease cleaves the sequence at the position indicated by the arrow, whereas the methylase modifies the internal cytosine, yielding N4-methylcytosine. This type of modification protects the substrate from R.MvaI cleavage. 5-Methylcytosine in the same position of the recognition sequence does not protect the substrate from R.MvaI cleavage. R.MvaI proved to be the first example of a restriction endonuclease differentiating the position of the methyl group in the heterocyclic ring of cytosine, located in the same site of the recognition sequence. M.MvaI modifies DNA dcm+ in vitro yielding N4,5-dimethylcytosine. N4-methylcytosine cannot be differentiated from cytosine using the Maxam-Gilbert DNA sequencing procedure.     

Mouse DNA-cytosine-5-methyltransferase: sequence specificity of the methylation reaction and electron microscopy of enzyme-DNA complexes.

Monoclonal antibodies prepared against DNA methyltransferase from human placenta undergo immune complex formation also with DNA methyltransferase from P815 mouse mastocytoma cells. One of these monoclonal antibodies, M2B10, was used for the immunoaffinity purification of this enzyme. Complexes of the immunoaffinity-purified mouse DNA methyltransferase with DNA were visualized by electron microscopy. DNA methyltransferase was found to be distributed along linearized plasmid DNA with a higher incidence of enzyme molecules at the terminal segments. This binding to strand ends was significantly increased after dG- or dGdC-tailing of the DNA, which is compatible with a preferred binding of the enzyme to single-stranded DNA. Sequence specificity analysis using methyl-sensitive restriction enzymes showed that the mouse DNA methyltransferase transferred methyl groups to the internal cytosines in 5'CCGG and 5'GCGC sequences, however, the external cytosine in 5'CCGG sequences was also methylated.