Predictive motifs derived from cytosine methyltransferases.

Thirteen bacterial DNA methyltransferases that catalyze the formation of 5-methylcytosine within specific DNA sequences possess related structures. Similar building blocks (motifs), containing invariant positions, can be found in the same order in all thirteen sequences. Five of these blocks are highly conserved while a further five contain weaker similarities. One block, which has the most invariant residues, contains the proline-cysteine dipeptide of the proposed catalytic site. A region in the second half of each sequence is unusually variable both in length and sequence composition. Those methyltransferases that exhibit significant homology in this region share common specificity in DNA recognition. The five highly conserved motifs can be used to discriminate the known 5-methylcytosine forming methyltransferases from all other methyltransferases of known sequence, and from all other identified proteins in the PIR, GenBank and EMBL databases. These five motifs occur in a mammalian methyltransferase responsible for the formation of 5-methylcytosine within CG dinucleotides. By searching the unidentified open reading frames present in the GenBank and EMBL databases, two potential 5-methylcytosine forming methyltransferases have been found.     

Exposition of a family of RNA m(5)C methyltransferases from searching genomic and proteomic sequences.

The Escherichia coli fmu gene product has recently been determined to be the 16S rRNA m(5)C 967 methyltransferase. As such, Fmu represents the first protein identified as an S -adenosyl-L-methionine (AdoMet)- dependent RNA m(5)C methyltransferase whose amino acid sequence is known. Using the amino acid sequence of Fmu as an initial probe in an iterative search of completed DNA sequence databases, 27 homologous ORF products were identified as probable RNA m(5)C methyltransferases. Further analysis of sequences in undeposited genomic sequencing data and EST databases yielded more than 30 additional homologs. These putative RNA m(5)C methyltransferases are grouped into eight subfamilies, some of which are predicted to consist of direct genetic counterparts, or orthologs. The enzymes proposed to be RNA m(5)C methyltransferases have sequence motifs closely related to signature sequences found in the well-studied DNA m(5)C methyltransferases and other AdoMet-dependent methyltransferases. Structure-function correlates in the known AdoMet methyltransferases support the assignment of this family as RNA m(5)C methyltransferases.     

The M.AluI DNA-(cytosine C5)-methyltransferase has an unusually large, partially dispensable, variable region.

The DNA methyltransferase of the AluI restriction-modification system, from Arthrobacter luteus, converts cytosine to 5-methylcytosine in the sequence AGCT. The gene for this methyltransferase, aluIM, was cloned into Escherichia coli and sequenced. A 525-codon open reading frame was found, consistent with deletion evidence, and the deduced amino acid sequence revealed all ten conserved regions common to 5-methylcytosine methyltransferases. The aluIM sequence predicts a protein of M(r) 59.0k, in agreement with the observed M(r), making M.AluI the largest known methyltransferase from a type II restriction-modification system. M.AluI also contains the largest known variable region of any monospecific DNA methyltransferase, larger than that of most multispecific methyltransferases. In other DNA methyltransferases the variable region has been implicated as the sequence-specific target recognition domain. An in-frame deletion that removes a third of this putative target-recognition region leaves the Alu I methyltransferase still fully active.     

Isolation and identification by sequence homology of a putative cytosine methyltransferase from Arabidopsis thaliana.

A plant cytosine methyltransferase cDNA was isolated using degenerate oligonucleotides, based on homology between prokaryote and mouse methyltransferases, and PCR to amplify a short fragment of a methyltransferase gene. A fragment of the predicted size was amplified from genomic DNA from Arabidopsis thaliana. Overlapping cDNA clones, some with homology to the PCR amplified fragment, were identified and sequenced. The assembled nucleic acid sequence is 4720 bp and encodes a protein of 1534 amino acids which has significant homology to prokaryote and mammalian cytosine methyltransferases. Like mammalian methylases, this enzyme has a C terminal methyltransferase domain linked to a second larger domain. The Arabidopsis methylase has eight of the ten conserved sequence motifs found in prokaryote cytosine-5 methyltransferases and shows 50% homology to the murine enzyme in the methyltransferase domain. The amino terminal domain is only 24% homologous to the murine enzyme and lacks the zinc binding region that has been found in methyltransferases from both mouse and man. In contrast to mouse where a single methyltransferase gene has been identified, a small multigene family with homology to the region amplified in PCR has been identified in Arabidopsis thaliana.     

The gene encoding DNA polymerase alpha from Plasmodium falciparum.

The gene encoding DNA polymerase alpha from the human malaria parasite Plasmodium falciparum has been sequenced and characterised. The deduced amino acid sequence possesses the seven sequence motifs which characterise eukaryotic replicative DNA polymerases (I-VII) and four of five motifs (A-E) identified in alpha DNA polymerases. The predicted protein also contains sequences which are reminiscent of Plasmodium proteins but absent from other DNA polymerases. These include four blocks of additional amino acids interspersed with the conserved motifs of the DNA polymerases, four asparagine rich sequences and a novel carboxy-terminal extension. Repetitive sequences similar to those found in other malarial proteins are also present. cDNA-directed PCR was used to establish the presence of these features in the approximately 7kb mRNA. The coding sequence contains a single intron. The gene for DNAPol alpha is located on chromosome 4 and is transcribed in both asexual and sexual erythrocytic stages of the parasite.     

The amino acid sequence of the CCGG recognizing DNA methyltransferase M.BsuFI: implications for the analysis of sequence recognition by cytosine DNA methyltransferases.

The Bacillus subtilis FI DNA methyltransferase (M.BsuFI) modifies the outer cytosine of the DNA sequence CCGG, causing resistance against R.BsuFI and R.MspI restriction. The M.BsuFI gene was cloned and expressed in B.subtilis and Escherichia coli. As derived from the nucleotide sequence, the M.BsuFI protein has 409 amino acids, corresponding to a molecular mass of 46,918 daltons. Including these data we have compared the nucleotide and amino acid sequences of different CCGG recognizing enzymes. These analyses showed that M.BsuFI is highly related to two other CCGG specific methyltransferases, M.MspI and M.HpaII, which were isolated from Gram-negative bacteria. Between M.BsuFI and M.MspI the sequence similarity is particularly significant in a region, which has been postulated to contain the target recognition domains (TRDs) of cytosine-specific DNA methyltransferases. Apparently M.BsuFI and M.MspI, derived from phylogenetic distant organisms, use highly conserved structural elements for the recognition of the CCGG target sequence. In contrast the very same region of M.HpaII is quite different from those of M.BsuFI and M.MspI. We attribute this difference to the different targeting of methylation within the sequence CCGG, where M.HpaII methylates the inner, M.BsuFI/M.MspI the outer cytosine. Also the CCGG recognizing TRD of the multispecific B.subtilis phage SPR Mtase is distinct from that of the host enzyme, possibly indicating different requirements for TRDs operative in mono- and multispecific enzymes.     

A mutational analysis of the two motifs common to adenine methyltransferases.

All methyltransferases that use S-adenosyl methionine as the methyl group donor contain a sequence similar to (D/E/S)XFXGXG which has been postulated to form part of the cofactor binding site. In N6-adenine DNA methyltransferases there is a second motif, (D/N)PP(Y/F), which has been proposed to play a role similar to the catalytically essential PC motif conserved in all C5-cytosine DNA methyltransferases. We have made a series of amino acid changes in these two motifs in the EcoKI N6-adenine DNA methyltransferase. The mutant enzymes have been purified to homogeneity and characterized by physical biochemical methods. The first G is the most conserved residue in motif I. Changing this G to D completely abolished S-adenosyl methionine binding, but left enzyme structure and DNA target recognition unaltered, thus documenting the S-adenosyl methionine binding function of motif I in N6-adenine methyltransferases. Substitution of the N with D, or F with either G or C, in motif II abolished enzyme activity, but left S-adenosyl methionine and DNA binding unaltered. Changes of F to Y or W resulted in partial enzyme activity, implying that an aromatic residue is important for methylation. The substitution of W for F greatly enhanced UV-induced cross-linking between the enzyme and S-adenosyl methionine, suggesting that the aromatic residue is close in space to the methyl-group donor.     

Cloning and sequencing of a cDNA encoding DNA methyltransferase of mouse cells. The carboxyl-terminal domain of the mammalian enzymes is related to bacterial restriction methyltransferases

A cDNA encoding DNA (cytosine-5)-methyltransferase (DNA MeTase) of mouse cells has been cloned and sequenced. The nucleotide sequence contains an open reading frame sufficient to encode a polypeptide of 1573 amino acid residues, which is close to the apparent size of the largest species of DNA MeTase found in mouse cells. The carboxylterminal 570 amino acid residues of the inferred protein sequence shows striking similarities to bacterial type II DNA cytosine methyltransferases and appears to represent a catalytic methyltransferase domain. The amino-terminal portion of the molecule may be involved in regulating the activity of the carboxyl-terminal methyltransferase domain, since antibodies directed against a peptide sequence located within this region inhibits transmethylase activity in vitro. A 5200 base DNA MeTase-specific mRNA was found to be expressed in all mouse cell types tested, and cell lines known to have different genomic methylation patterns were found to contain DNA MeTase proteins of similar or identical sizes and de novo sequence specificities. The implications of these findings for an understanding of the mechanisms involved in the establishment and maintenance of methylation patterns are discussed.     

Sequence motifs specific for cytosine methyltransferases

Using a new alignment method, the sequences of 13 m5C methyltransferases (MTases) have been examined. Five extremely well-conserved blocks of sequence have been detected and have been used as fixed points for the alignment of the 13 sequences. Following this initial alignment, five further blocks of similarity have been identified to give a total of ten recognizable blocks of sequence homology that are all arranged in a common order. The structures of these MTases consist of a variable-length N-terminal arm followed by eight well-conserved blocks each separated by small variable-length regions. A large variable-length segment of 90 to 270 amino acids (aa) then follows. After this are two blocks, and a variable-length C-terminal segment completes the sequence. Within the final alignment, 20 aa in the protein sequences, and 86 nucleotides in the nucleotide sequences are invariant. The strongest conservation is found in proximity to a suspected functional site that contains the dipeptide proline-cysteine. Consensus patterns can be defined for the five best conserved blocks and, when used as search motifs, are able to clearly distinguish between the m5C MTases and all other identified proteins in the PIR database. This suggests they may be of use in identifying putative MTases among protein sequences of unknown function.     

Sequence-specific protection of duplex DNA against restriction and methylation enzymes by pseudocomplementary PNAs

A new generation of PNAs, so-called pseudocomplementary PNAs (pcPNAs), which are able to target the designated sites on duplex DNA with mixed sequence of purines and pyrimidines via double-duplex invasion mode, has recently been introduced. It has been demonstrated that appropriate pairs of decameric pcPNAs block an access of RNA polymerase to the corresponding promoter. Here, we show that this type of PNAs protects selected DNA sites containing all four nucleobases from the action of restriction enzymes and DNA methyltransferases. We have found that pcPNAs as short as octamers form stable and sequence-specific complexes with duplex DNA in a very salt-dependent manner. In accord with a strand-invasion mode of complex formation, the pcPNA binding proceeds much faster with supercoiled than with linear plasmids. The double-duplex invasion complexes selectively shield specific DNA sites from BclI restriction endonuclease and dam methylase. The pcPNA-assisted protection against enzymatic methylation is more efficient when the PNA-binding site embodies the methylase-recognition site rather than overlaps it. We conclude that pcPNAs may provide the robust tools allowing to sequence-specifically manipulate DNA duplexes in a virtually sequence-unrestricted manner.     

Cloning and nucleotide sequence of the gene encoding the Ecal DNA methyltransferase.

The gene coding for the GGTNACC specific Ecal DNA methyltransferase (M.Ecal) has been cloned in E. coli from Enterobacter cloacae and its nucleotide sequence has been determined. The ecalM gene codes for a protein of 452 amino acids (Mr: 51,111). It was determined that M.Ecal is an adenine methyltransferase. M.Ecal shows limited amino acid sequence similarity to other adenine methyltransferases. A clone that expresses Ecal methyltransferase at high level was constructed.     

On the evolutionary origin of eukaryotic DNA methyltransferases and Dnmt2

The Dnmt2 enzymes show strong amino acid sequence similarity with eukaryotic and prokaryotic DNA-(cytosine C5)-methyltransferases. Yet, Dnmt2 enzymes from several species were shown to methylate tRNA-Asp and had been proposed that eukaryotic DNA methyltransferases evolved from a Dnmt2-like tRNA methyltransferase ancestor [Goll et al., 2006, Science, 311, 395-8]. It was the aim of this study to investigate if this hypothesis could be supported by evidence from sequence alignments. We present phylogenetic analyses based on sequence alignments of the methyltransferase catalytic domains of more than 2300 eukaryotic and prokaryotic DNA-(cytosine C5)-methyltransferases and analyzed the distribution of DNA methyltransferases in eukaryotic species. The Dnmt2 homologues were reliably identified by an additional conserved CFT motif next to motif IX. All DNA methyltransferases and Dnmt2 enzymes were clearly separated from other RNA-(cytosine-C5)-methyltransferases. Our sequence alignments and phylogenetic analyses indicate that the last universal eukaryotic ancestor contained at least one member of the Dnmt1, Dnmt2 and Dnmt3 families of enzymes and additional RNA methyltransferases. The similarity of Dnmt2 enzymes with DNA methyltransferases and absence of similarity with RNA methyltransferases combined with their strong RNA methylation activity suggest that the ancestor of Dnmt2 was a DNA methyltransferase and an early Dnmt2 enzyme changed its substrate preference to tRNA. There is no phylogenetic evidence that Dnmt2 was the precursor of eukaryotic Dnmts. Most likely, the eukaryotic Dnmt1 and Dnmt3 families of DNA methyltransferases had an independent origin in the prokaryotic DNA methyltransferase sequence space.     

Structure of RsrI methyltransferase, a member of the N6-adenine beta class of DNA methyltransferases

DNA methylation is important in cellular, developmental and disease processes, as well as in bacterial restriction-modification systems. Methylation of DNA at the amino groups of cytosine and adenine is a common mode of protection against restriction endonucleases afforded by the bacterial methyltransferases. The first structure of an N:6-adenine methyltransferase belonging to the beta class of bacterial methyltransferases is described here. The structure of M. RSR:I from Rhodobacter sphaeroides, which methylates the second adenine of the GAATTC sequence, was determined to 1.75 A resolution using X-ray crystallography. Like other methyltransferases, the enzyme contains the methylase fold and has well-defined substrate binding pockets. The catalytic core most closely resembles the PVU:II methyltransferase, a cytosine amino methyltransferase of the same beta group. The larger nucleotide binding pocket observed in M. RSR:I is expected because it methylates adenine. However, the most striking difference between the RSR:I methyltransferase and the other bacterial enzymes is the structure of the putative DNA target recognition domain, which is formed in part by two helices on an extended arm of the protein on the face of the enzyme opposite the active site. This observation suggests that a dramatic conformational change or oligomerization may take place during DNA binding and methylation.     

Identification of the binding site for the extrahelical target base in N6-adenine DNA methyltransferases by photo-cross-linking with duplex oligodeoxyribonucleotides containing 5-iodouracil at the target position.

DNA methyltransferases flip their target bases out of the DNA double helix for catalysis. Base flipping of C5-cytosine DNA methyltransferases was directly observed in the protein-DNA cocrystal structures of M.HhaI and M.HaeIII. Indirect structural evidence for base flipping of N6-adenine and N4-cytosine DNA methyltransferases was obtained by modeling DNA into the three-dimensional structures of M.TaqI and M.PvuII in complex with the cofactor. In addition, biochemical evidence of base flipping was reported for different N6-adenine DNA methyltransferases. As no protein-DNA cocrystal structure for the related N6-adenine and N4-cytosine DNA methyltransferases is available, we used light-induced photochemical cross-linking to identify the binding site of the extrahelical target bases. The N6-adenine DNA methyltransferases M.TaqI and M.CviBIII, which both methylate adenine within the double-stranded 5'-TCGA-3' DNA sequence, were photo-cross-linked to duplex oligodeoxyribonucleotides containing 5-iodouracil at the target position in 50-60% and almost quantitative yield, respectively. Proteolytic fragmentation of the M. CviBIII-DNA complex followed by Edman degradation and electrospray ionization mass spectrometry indicates photo-cross-linking to tyrosine 122. In addition, the mutant methyltransferases M. TaqI/Y108A and M.TaqI/F196A were photo-cross-linked with 6-fold and 2-fold reduced efficiency, respectively, which suggests that tyrosine 108 is the primary site of modification in M.TaqI. Our results indicate a close proximity between the extrahelical target base and tyrosine 122 in M.CviBIII or tyrosine 108 in M.TaqI. As both residues belong to the conserved motif IV ((N/D/S)(P/I)P(Y/F/W)) found in all N6-adenine and N4-cytosine DNA as well as in N6-adenine RNA methyltransferases, a similar spatial relationship between the target bases and the aromatic amino acid residue within motif IV is expected for all these methyltransferases.     

Cloning and sequence analysis of a zebrafish cDNA encoding DNA (cytosine-5)-methyltransferase-1

The zebrafish has become a well-established animal model for the analysis of development and of several disease phenotypes. Several of the favorable traits that make it a popular model organism would also be beneficial for the study of normal and abnormal vertebrate development in which DNA methylation may play a role. We report the determination of the full-length cDNA sequence corresponding to the zebrafish DNA (cytosine-5-) methyltransferase gene, Dnmt1. It is 4,907 bases long and has an open reading frame predicted to encode a 1,499 amino acid protein that is similar in size and sequence to a number of other methyltransferases identified in other organisms.     

The human Dnmt2 has residual DNA-(cytosine-C5) methyltransferase activity

The human Dnmt2 protein is one member of a protein family conserved from Schizosaccharomyces pombe and Drosophila melanogaster to Mus musculus and Homo sapiens. It contains all of the amino acid motifs characteristic for DNA-(Cytosine-C5) methyltransferases, and its structure is very similar to prokaryotic DNA methyltransferases. Nevertheless, so far all attempts to detect catalytic activity of this protein have failed. We show here by two independent assay systems that the purified Dnmt2 protein has weak DNA methyltransferase activity. Methylation was observed at CG sites in a loose ttnCGga(g/a) consensus sequence, suggesting that Dnmt2 has a more specialized role than other mammalian DNA methyltransferases.     

DNA methylation: evolution of a bacterial immune function into a regulator of gene expression and genome structure in higher eukaryotes

The amino acid sequence of mammalian DNA methyltransferase has been deduced from the nucleotide sequence of a cloned cDNA. It appears that the mammalian enzyme arose during evolution via fusion of a prokaryotic restriction methyltransferase gene and a second gene of unknown function. Mammalian DNA methyltransferase currently comprises an N-terminal domain of about 1000 amino acids that may have a regulatory role and a C-terminal 570 amino acid domain that retains similarities to bacterial restriction methyltransferases. The sequence similarities among mammalian and bacterial DNA cytosine methyltransferases suggest a common evolutionary origin. DNA methylation is uncommon among those eukaryotes having genomes of less than 10(8) base pairs, but nearly universal among large-genome eukaryotes. This and other considerations make it likely that sequence inactivation by DNA methylation has evolved to compensate for the expansion of the genome that has accompanied the development of higher plants and animals. As methylated sequences are usually propagated in the repressed, nuclease-insensitive state, it is likely that DNA methylation compartmentalizes the genome to facilitate gene regulation by reducing the total amount of DNA sequence that must be scanned by DNA-binding regulatory proteins. DNA methylation is involved in immune recognition in bacteria but appears to regulate the structure and expression of the genome in complex higher eukaryotes. I suggest that the DNA-methylating system of mammals was derived from that of bacteria by way of a hypothetical intermediate that carried out selective de novo methylation of exogenous DNA and propagated the methylated DNA in the repressed state within its own genome.(ABSTRACT TRUNCATED AT 250 WORDS)     

The cytosine N4-methyltransferase M.PvuII also modifies adenine residues

Methylation of DNA occurs at the C5 and N4 positions of cytosine and N6 of adenine. The chemistry of methylation is similar among methyltransferases specific for cytosine-N4 and adenine-N6. Moreover these enzymes have similar structures and active sites. Previously it has been demonstrated that the DNA-(adenine-N6)-methyltransferases M.EcoRV, M.EcoRI, E. coli dam and both domains of M.FokI also modify cytosine residues at the N4 position [Jeltsch et al., J. Biol. Chem. 274 (1999), 19538-19544]. Here we show that the cytosine-N4 methyltransferase M.PvuII, which modifies the second cytosine in CAGCTG sequences, also methylates adenine residues in CAGATG/CAGCTG substrates in which the target cytosine is replaced by adenine in one strand of the recognition sequence. Therefore, adenine-N6 and cytosine-N4 methyltransferases have overlapping target base specificities. These results demonstrate that the target base recognition by N-specific DNA methyltransferases is relaxed in many cases. Furthermore, it shows that the catalytic mechanisms of adenine-N6 and cytosine-N4 methyltransferases are very similar.