EC:2.1.1.37 - FACTA Search

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Query: EC:2.1.1.37 (DNA methyltransferase)
4,983 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Escherichia coli dam mutants, lacking the GATC DNA methylase, do not produce anucleate cells at high frequencies, suggesting that hemimethylation of the chromosome origin of replication, oriC, is not essential for correct chromosome partitioning.
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PMID:Chromosome partitioning in Escherichia coli in the absence of dam-directed methylation. 155 54

Genes located near telomeres in Saccharomyces cerevisiae undergo position-effect variegation; their transcription is subject to reversible but mitotically heritable repression. This position effect and the finding that telomeric DNA is late replicating suggest that yeast telomeres exist in a heterochromatin-like state. Mutations in genes that suppress the telomeric position effect suggest that a special chromatin structure exists near chromosomal termini. Thus transcriptional repression may be explained by the inability of DNA binding proteins to access the DNA near telomeres. To test this hypothesis, the Escherichia coli Dam DNA methyltransferase, which modifies the sequence GATC, was introduced into S. cerevisiae cells. DNA sequences near the telomere were highly refractive to Dam methylation but were modified when located at positions more internal on the chromosome. Telomeric sequences were accessible to methyltransferase activity in strains that contained a mutation that suppressed the telomeric position effect. These data support the model that sequence-specific DNA binding proteins are excluded from telomere-proximal sequences in vivo and show that expression of DNA methyltransferase activity may serve as a useful tool for mapping chromosomal structural domains in vivo.
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PMID:Telomere-proximal DNA in Saccharomyces cerevisiae is refractory to methyltransferase activity in vivo. 157 Mar 34

The dam gene of Escherichia coli encodes a DNA methyltransferase that methylates the N6 position of adenine in the sequence GATC. It was stably expressed from a shuttle vector in a repair- and recombination-proficient strain of Bacillus subtilis. In this strain the majority of plasmid DNA molecules was modified at dam sites whereas most chromosomal DNA remained unmethylated during exponential growth. During stationary phase the amount of unmethylated DNA increased, suggesting that methylated bases were being removed. An ultraviolet damage repair-deficient mutant (uvrB) contained highly methylated chromosomal and plasmid DNA. High levels of Dam methylation were detrimental to growth and viability of this mutant strain and some features of the SOS response were also induced. A mutant defective in the synthesis of adaptive DNA alkyltransferases and induction of the adaptive response (ada) also showed high methylation and properties similar to that of the dam gene expressing uvrB strain. When protein extracts from B. subtilis expressing the Dam methyltransferase or treated with N-methyl-N'-nitro-N-nitroso-guanidine were incubated with [3H]-labelled Dam methylated DNA, the methyl label was bound to two proteins of 14 and 9 kD. Some free N6-methyladenine was also detected in the supernatant of the incubation mixture. We propose that N6-methyladenine residues are excised by proteins involved in both excision (uvrB) and the adaptive response (ada) DNA repair pathways in B. subtilis.
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PMID:Expression of Escherichia coli dam gene in Bacillus subtilis provokes DNA damage response: N6-methyladenine is removed by two repair pathways. 164 27

A gene from the periodontal organism Porphyromonas gingivalis has been identified as encoding a DNA methylase. The gene, referred to as pgiIM, has been sequenced and found to contain a reading frame of 864 basepairs. The putative amino acid sequence of the encoded methylase was 288 amino acids, and shared 47% and 31% homology with the Streptococcus pneumoniae DpnII and E. coli Dam methylases, respectively. The activity and specificity of the pgi methylase (M.PgiI) was confirmed by cloning the gene into a dam- strain of E. coli (JM110) and performing a restriction analysis on the isolated DNA with enzymes whose activities depended upon the methylation state of the DNA. The data indicated that M.PgiI, like DpnII and Dam, methylated the adenine residue within the sequence 5'-GATC-3'.
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PMID:Identification and sequence analysis of a methylase gene in Porphyromonas gingivalis. 187 Sep 72

The gene encoding the Neisseria lactamica III DNA methyltransferase (M.NlaIII) which recognizes the sequence CATG has been cloned and expressed in Escherichia coli. DNA sequencing of a 3.125 kb EcoRI-PstI fragment localizes the M. NlaIII gene to a 334 codon open reading frame (ORF) and identifies, 468 bp downstream, a second ORF of 313 amino acids, which is referred to as M.NlaX. Both proteins are detectable in the E. coli coupled in vitro transcription-translation system; they are apparently expressed from separate N. lactamica promoters. The N-terminal half of the previously characterized M.FokI, which methylates adenine in one of the DNA strands with its asymmetric recognition sequence (GGATG), is found to have 41% sequence identity and a further 11.7% sequence similarity with M.NlaIII. Among the conserved amino acids is the wellknown DPPY sequence motif. With one exception, analysis of the nucleotides coding for the DP dipeptide in all known DPPY sequences shows the presence of an inherent DNA adenine methylation (dam) recognition site of GATC. A low level of expression of M.NlaX in E. coli prevents the elucidation of its sequence recognition specificity. Sequence analysis of M.NlaX shows that it is closely related to the group of monospecific 5-methylcytosine DNA methyltransferases (M.EcoRII, Dcm, M.HpaII and M.HhaI) which all have a modified cytosine at the second position of the recognition sequences. Both M.EcoRII and Dcm amino acid sequences are about 50% identical with M.NlaX; a considerable degree of sequence identity is found in the so-called variable region which is believed to be responsible for sequence recognition specificity. M.NlaX is probably the counterpart to the E. coli Dcm in N. lactamica.
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PMID:Cloning and characterization of two tandemly arranged DNA methyltransferase genes of Neisseria lactamica: an adenine-specific M.NlaIII and a cytosine-type methylase. 227 28

Proteins encoded by three genes in the DpnII restriction enzyme cassette of Streptococcus pneumoniae were purified and characterized. Large amounts of the proteins were produced by subcloning the cassette in an Escherichia coli expression system. All three proteins appear to be dimers composed of identical polypeptide subunits. One is the DpnII endonuclease, and the other two are DNA adenine methylase active at 5' GATC 3' sites. Inactivation of enzyme activity by insertions into the genes and comparison of the DNA sequence with the amino-terminal sequence of amino acid residues in the proteins demonstrated the following correspondence between genes and enzymes. The promoter-proximal gene in the operon, dpnM, encodes a 33 X 10(3) Mr polypeptide that gives rise to a potent DNA methylase. The next gene, dpnA, encodes the 31 x 10(3) Mr polypeptide of a weaker and less-specific methylase. The third gene, dpnB, encodes the 34 x 10(3) Mr polypeptide of the endonuclease. Although the endonuclease polypeptide is initiated from an ordinary ribosome-binding site, each of the methylase polypeptide begins at an atypical site with a consensus sequence entirely different from that of Shine & Dalgarno. This presumptive novel ribosome-binding site is well recognized in both S. pneumoniae and E. coli.
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PMID:Proteins encoded by the DpnII restriction gene cassette. Two methylases and an endonuclease. 282 82

Mycoplasma bacteriophage L51 single-stranded DNA and L2 double-stranded DNA are host cell modified and restricted when they transfect Acholeplasma laidlawii JA1 and K2 cells. The L51 genome has a single restriction endonuclease MboI site (recognition sequence GATC), which contains 5-methylcytosine when the DNA is isolated from L51 phage grown in K2 cells but is unmethylated when the DNA is from phage grown in JA1 cells. This GATC sequence is nonessential, since an L51 mutant in which the MboI site was deleted was still viable. DNA from this deletion mutant phage was not restricted during transfection of either strain K2 or JA1. Therefore, strain K2 restricts DNA containing the sequence GATC, and strain JA1 restricts DNA containing the sequence GAT 5-methylcytosine. We conclude that K2 cells have a restriction system specific for DNA containing the sequence GATC and protect their DNA by methylating cytosine in this sequence. In contrast, JA1 cells (which contain no methylated DNA bases) have a newly discovered type of restriction-modification system. From results of studies of the restriction of specifically methylated DNAs, we conclude that JA1 cells restrict DNA containing 5-methylcytosine, regardless of the nucleotide sequence containing 5-methylcytosine. This is the first report of a DNA restriction activity specific for a single (methylated) base. Modification in this system is the absence of cytosine methylating activity. A restriction-deficient variant of strain JA1, which retains the JA1 modification phenotype, was isolated, indicating that JA1 cells have a gene product with restriction specificity for DNA containing 5-methylcytosine.
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PMID:Mycoplasma restriction: identification of a new type of restriction specificity for DNA containing 5-methylcytosine. 300 Oct 23

An Escherichia coli virus T1-induced DNA methyltransferase was identified by activity gel analysis in homogenates of infected E. coli DNA-adenine-methylation-deficient strains. Although the Mr of this protein (31,000) is in the same range as that of the E. coli DNA adenine methyltransferase, the two proteins are not closely related; the E. coli dam gene does not hybridize with T1 DNA. Selective conditions for measurement of the T1 activity were developed, and the enzyme was purified to functional homogeneity, as shown by activity analysis in polyacrylamide gels. Requirements for optimal activity of the viral enzyme were determined to be pH 6.9, ionic strengths below 0.1 M KCl, and a temperature between 40 and 43 degrees C. The Km for S-adenosyl-L-methionine is 4.9 microM. The purified T1 DNA methyltransferase is capable of methylating adenine in 5'-GATC-3' sites in vitro.
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PMID:Identification, purification, and characterization of Escherichia coli virus T1 DNA methyltransferase. 331 2

The T4 dam+ gene has been cloned (S. L. Schlagman and S. Hattman, Gene 22:139-156, 1983) and transferred into an Escherichia coli dam-host. In this host, the T4 Dam DNA methyltransferase methylates mainly, if not exclusively, the sequence 5'-GATC-3'; this sequence specificity is the same as that of the E. coli Dam enzyme. Expression of the cloned T4 dam+ gene suppresses almost all the phenotypic traits associated with E. coli dam mutants, with the exception of hypermutability. In wild-type hosts, 20- to 500-fold overproduction of the E. coli Dam methylase by plasmids containing the cloned E. coli dam+ gene results in a hypermutability phenotype (G.E. Herman and P. Modrich, J. Bacteriol. 145:644-646, 1981; M.G. Marinus, A. Poteete, and J.A. Arraj, Gene 28:123-125, 1984). In contrast, the same high level of T4 Dam methylase activity, produced by plasmids containing the cloned T4 dam+ gene, does not result in hypermutability. To account for these results we propose that the E. coli Dam methylase may be directly involved in the process of methylation-instructed mismatch repair and that the T4 Dam methylase is unable to substitute for the E. coli enzyme.
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PMID:Direct role of the Escherichia coli Dam DNA methyltransferase in methylation-directed mismatch repair. 351 29

A DNA methyltransferase was isolated from a eucaryotic, Chlorella-like green alga infected with the virus PBCV-1. The enzyme recognized the sequence GATC and methylated deoxyadenosine solely in GATC sequences. Host DNA, which contains GATC sequences, but not PBCV-1 DNA, which contains GmATC sequences, was a good substrate for the enzyme in vitro. The DNA methyltransferase activity was first detected about 1 h after viral infection; PBCV-1 DNA synthesis and host DNA degradation also began at about this time. The appearance of the DNA methyltransferase activity required de novo protein synthesis, and the enzyme was probably virus encoded. Methylation of DNAs with the PBCV-1-induced methyltransferase conferred resistance of the DNAs to a PBCV-1-induced restriction endonuclease enzyme described previously (Y. Xia, D. E. Burbank, L. Uher, D. Rabussay, and J. L. Van Etten, Mol. Cell. Biol. 6:1430-1439). We propose that the PBCV-1-induced methyltransferase protects viral DNA from the PBCV-1-induced restriction endonuclease and is part of a virus-induced restriction and modification system in PBCV-1-infected Chlorella cells.
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PMID:DNA methyltransferase induced by PBCV-1 virus infection of a Chlorella-like green alga. 353 3

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