Identification, purification, and characterization of Escherichia coli virus T1 DNA methyltransferase

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.     

The DNA-methylation state regulates virulence and stress response of Salmonella

The DNA methylation is a post-replicative event that provides secondary information to that formed by DNA. Addition of this information involves DAM methyltransferase, which methylates DNA on specific sites (5'-GATC-3'). This modification of DNA may play a role in regulating various processes in eukaryote or prokaryote cells. It was well understood that deoxyadenosine methyltransferase (DAM) methylates the adenine of the GATC sequence. Following DNA replication, however, DNA is transiently hemimethylated, and the new strand is then methylated by DAM. In Escherichia coli, removing the dam gene produces several phenotypes indicating multiple functions of methylation: (i) modulation of gene expression, (ii) DNA repair, (iii) initiation of replication, and (iv) stabilising the chromosome.     

Natrialba magadii virus phiCh1: first complete nucleotide sequence and functional organization of a virus infecting a haloalkaliphilic archaeon

The double-stranded (ds)DNA virus phiCh1 infects the haloalkaliphilic archaeon Natrialba magadii. The complete DNA sequence of 58 498 bp of the temperate virus was established, and the probable functions of 21 of 98 phiCh1-encoded open reading frames (ORFs) have been assigned. This knowledge has been used to propose functional modules each required for specific functions during virus development. The phiCh1 DNA is terminally redundant and circularly permuted and therefore appears to be packaged by the so-called headful mechanism. The presence of ORFs encoding homologues of proteins involved in plasmid replication as well as experimental evidence indicate a plasmid-mediated replication strategy of the virus. Results from nanosequencing of virion components suggest covalent cross-linking of monomers of at least one of the structural proteins during virus maturation. A comparison of the phiCh1 genome with the partly sequenced genome of Halobacterium salinarum virus phiH revealed a close relationship between the two viruses, although their host organisms live in distinct environments with respect to the different pH values required for growth.     

Identification and sequence analysis of a methylase gene in Porphyromonas gingivalis.

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'.     

Characterization of Natronobacterium magadii phage ΦCh1, a unique archaeal phage containing DNA and RNA

A novel archaeal bacteriophage, ΦCh1, was isolated from a haloalkalophilic archaeon Natronobacterium magadii upon spontaneous lysis. The phage-cured strain N. magadii (L13) was used to demonstrate infectivity of phage ΦCh1. The turbid-plaque morphology and the fact that N. magadii cells isolated from plaques were able to produce phage indicated that ΦCh1 is a temperate phage. The phage morphology resembles other members of Myoviridae -infecting Halobacterium species. In solution below 2 M NaCl, the phage lost its morphological stability and infectivity. One- and two-dimensional SDS–PAGE of phage particles revealed at least four major and five minor proteins with molecular masses ranging from 15 to 80 kDa and acidic isoelectric points. Southern blot analysis of chromosomal DNA of a lysogenic N. magadii strain showed that ΦCh1 exists as a chromosomally integrated prophage. The phage particles contain both double-stranded, linear DNA (approx. 55 kbp) as well as several RNA species (80–700 nucleotides). Hybridization of labelled RNA fragments to total DNA from N. magadii and ΦCh1 showed that the virion-associated RNA is host encoded. Part of the phage DNA population is modified and restriction analysis revealed evidence for adenine methylation. Phage ΦCh1 is the first virus described for the genus Natronobacterium , and the first phage containing DNA and RNA in mature phage particles.     

A DNA adenine methyltransferase of Escherichia coli that is cell cycle regulated and essential for viability

DNA sequence analysis revealed that the putative yhdJ DNA methyltransferase gene of Escherichia coli is 55% identical to the Nostoc sp. strain PCC7120 gene encoding DNA methyltransferase AvaIII, which methylates adenine in the recognition sequence, ATGCAT. The yhdJ gene was cloned, and the enzyme was overexpressed and purified. Methylation and restriction analysis showed that the DNA methyltransferase methylates the first adenine in the sequence ATGCAT. This DNA methylation was found to be regulated during the cell cycle, and the DNA adenine methyltransferase was designated M.EcoKCcrM (for "cell cycle-regulated methyltransferase"). The CcrM DNA adenine methyltransferase is required for viability in E. coli, as a strain lacking a functional genomic copy of ccrM can be isolated only in the presence of an additional copy of ccrM supplied in trans. The cells of such a knockout strain stopped growing when expression of the inducible plasmid ccrM gene was shut off. Overexpression of M.EcoKCcrM slowed bacterial growth, and the ATGCAT sites became fully methylated throughout the cell cycle; a high proportion of cells with an anomalous size distribution and DNA content was found in this population. Thus, the temporal control of this methyltransferase may contribute to accurate cell cycle control of cell division and cellular morphology. Homologs of M.EcoKCcrM are present in other bacteria belonging to the gamma subdivision of the class Proteobacteria, suggesting that methylation at ATGCAT sites may have similar functions in other members of this group.     

Conservation of Dcm-mediated cytosine DNA methylation in Escherichia coli

In Escherichia coli, cytosine DNA methylation is catalyzed by the DNA cytosine methyltransferase (Dcm) protein and occurs at the second cytosine in the sequence 5'CCWGG3'. Although the presence of cytosine DNA methylation was reported over 35?years ago, the biological role of 5-methylcytosine in E.?coli remains unclear. To gain insight into the role of cytosine DNA methylation in E.?coli, we (1) screened the 72 strains of the ECOR collection and 90 recently isolated environmental samples for the presence of the full-length dcm gene using the polymerase chain reaction; (2) examined the same strains for the presence of 5-methylcytosine at 5'CCWGG3' sites using a restriction enzyme isoschizomer digestion assay; and (3) quantified the levels of 5-methyl-2'-deoxycytidine in selected strains using liquid chromatography tandem mass spectrometry. Dcm-mediated cytosine DNA methylation is conserved in all 162 strains examined, and the level of 5-methylcytosine ranges from 0.86% to 1.30% of the cytosines. We also demonstrate that Dcm reduces the expression of ribosomal protein genes during stationary phase, and this may explain the highly conserved nature of this DNA modification pathway.     

Analysis of genomic DNA from Chlamydia trachomatis for Dam and Dcm methylation

Chlamydia trachomatis is a Gram-negative eubacterium with a dimorphic developmental cycle and obligate intracellular growth in the eucaryotic host. The Dam transmethylase of Escherichia coli methylates at the N6 position of adenine in the sequence 5'-GATC-3' and the Dcm transmethylase adds methyl groups to the C5 position of the internal cytosines in the sequences 5'-CCWGG-3'. In contrast to E. coli, C. trachomatis DNA appears to have unmethylated Dam sites and only low level Dcm methylation.     

Cloning of the Dam methyltransferase gene from Haemophilus influenzae bacteriophage HP1

The putative product of orf13 from the genome of Haemophilus influenzae HP1 bacteriophage shows homology only to bacteriophage T1 Dam methyltransferase, and a weak similarity to the conserved amino acids sequence motifs characteristic of m6A-methyltransferases. Especially interesting is lack of characteristic motif I responsible for binding of S-adenosylmethionine. Despite this fact, a DNA sequence of HP1 bacteriophage of Haemophilus influenzae encoding methyltransferase activity was cloned and expressed in Escherichia coli using pMPMT4 omega expression vector. The cloned methyltransferase recognizes the sequence 5'-GATC-3' and methylates an adenine residue. The enzyme methylates both double- and single-stranded DNA substrates.     

The Helicobacter pylori genome is modified at CATG by the product of hpyIM.

To understand mechanisms of DNA methylation in Helicobacter pylori, a human pathogen associated with peptic ulcer disease and gastric adenocarcinoma, we cloned a putative DNA methyltransferase gene, hpyIM. This gene contains a 990-bp open reading frame encoding a 329-amino-acid protein, M.HpyI. Sequence analysis revealed that M.HpyI was closely related to CATG-recognizing adenine DNA methyltransferases, including M.NlaIII in N. lactamica. hpyIM was present in all H. pylori strains tested. DNA from wild-type H. pylori strains was resistant to digestion by SphI and NlaIII, which recognize DNA at sites containing CATG, whereas their isogenic hpyIM mutants were susceptible, indicating lack of modification. Overexpression of hpyIM in Escherichia coli rendered DNA from these cells resistant to NlaIII digestion, confirming the role of hpyIM in modifying CATG sites. We conclude that hpyIM encodes a DNA methyltransferase, M.HpyI, that is well conserved among diverse H. pylori strains and that modifies H. pylori genomes at CATG sites.     

Novel non-specific DNA adenine methyltransferases

The mom gene of bacteriophage Mu encodes an enzyme that converts adenine to N(6)-(1-acetamido)-adenine in the phage DNA and thereby protects the viral genome from cleavage by a wide variety of restriction endonucleases. Mu-like prophage sequences present in Haemophilus influenzae Rd (FluMu), Neisseria meningitidis type A strain Z2491 (Pnme1) and H. influenzae biotype aegyptius ATCC 11116 do not possess a Mom-encoding gene. Instead, at the position occupied by mom in Mu they carry an unrelated gene that encodes a protein with homology to DNA adenine N(6)-methyltransferases (hin1523, nma1821, hia5, respectively). Products of the hin1523, hia5 and nma1821 genes modify adenine residues to N(6)-methyladenine, both in vitro and in vivo. All of these enzymes catalyzed extensive DNA methylation; most notably the Hia5 protein caused the methylation of 61% of the adenines in λ DNA. Kinetic analysis of oligonucleotide methylation suggests that all adenine residues in DNA, with the possible exception of poly(A)-tracts, constitute substrates for the Hia5 and Hin1523 enzymes. Their potential 'sequence specificity' could be summarized as AB or BA (where B = C, G or T). Plasmid DNA isolated from Escherichia coli cells overexpressing these novel DNA methyltransferases was resistant to cleavage by many restriction enzymes sensitive to adenine methylation.     

Modulation of Escherichia coli DNA methyltransferase activity by biologically derived GATC-flanking sequences

Escherichia coli DNA adenine methyltransferase (EcoDam) methylates the N-6 position of the adenine in the sequence 5'-GATC-3' and plays vital roles in gene regulation, mismatch repair, and DNA replication. It remains unclear how the small number of critical GATC sites involved in the regulation of replication and gene expression are differentially methylated, whereas the approximately 20,000 GATCs important for mismatch repair and dispersed throughout the genome are extensively methylated. Our prior work, limited to the pap regulon, showed that methylation efficiency is controlled by sequences immediately flanking the GATC sites. We extend these studies to include GATC sites involved in diverse gene regulatory and DNA replication pathways as well as sites previously shown to undergo differential in vivo methylation but whose function remains to be assigned. EcoDam shows no change in affinity with variations in flanking sequences derived from these sources, but methylation kinetics varied 12-fold. A-tracts immediately adjacent to the GATC site contribute significantly to these differences in methylation kinetics. Interestingly, only when the poly(A) is located 5' of the GATC are the changes in methylation kinetics revealed. Preferential methylation is obscured when two GATC sites are positioned on the same DNA molecule, unless both sites are surrounded by large amounts of nonspecific DNA. Thus, facilitated diffusion and sequences immediately flanking target sites contribute to higher order specificity for EcoDam; we suggest that the diverse biological roles of the enzyme are in part regulated by these two factors, which may be important for other enzymes that sequence-specifically modify DNA.     

Lack of evidence for methylation of parental and newly synthesized adenovirus type 2 DNA in productive infections.

Methylations of highly specific sites in the promoter and 5' regions of eucaryotic genes have been shown to shut off gene activity and thus play a role in the long-term regulation of gene expression. It was therefore of interest to investigate whether site-specific DNA methylations could also play a role in adenovirus DNA in productive infections. It has been reported earlier that adenovirion DNA is not detectably methylated (U. Günthert, M. Schweiger, M. Stupp, and W. Doerfler, Proc. Natl. Acad. Sci. USA 73:3923-3927, 1976). In the present study, evidence for the methylation of cytidine residues in 5'-CCGG-3' and 5'-GCGC-3' sequences or the methylation of adenine residues in 5'-GATC-3' and 5'-TCGA-3' sequences in intranuclear adenovirus type 2(Ad2) DNA isolated and analyzed early (5 h) or late (24 h) after infection could not be obtained. In Ad2 DNA, 22.5% of all 5'-CG-3' dinucleotides reside in 5'-CCGG-3' and 5'-GCGC-3' sequences. Intranuclear viral DNA was examined by restriction endonuclease cleavage by using HpaII, MspI, HhaI, DpnI, or TaqI and Southern blot hybridizations. The HindIII fragments of Ad2 DNA served as hybridization probes. The data rendered it very unlikely that free intracellular adenovirus DNA in productively infected cells was extensively methylated. Thus, DNA methylation was not a likely element in the regulation of free adenovirus DNA expression in productively infected cells.     

Sequence-dependent interactions of two forms of UvrC with DNA helix-stabilizing CC-1065-N3-adenine adducts

The uvrA, uvrB, and uvrC genes of Escherichia coli control the initial steps of nucleotide excision repair. The uvrC gene product is involved in at least one of the dual incisions produced by the UvrABC complex. Using single-stranded (ss) DNA affinity chromatography, we have separated two forms of UvrC from both wild-type E. coli cells and overproducing cells. UvrCI elutes at 0.4 M KCl, and UvrCII elutes at 0.6 M KCl. In general, both forms, in the presence of UvrA and UvrB, actively incise UV-irradiated and CC-1065-modified DNA in the same fashion; i.e., they incise six to eight nucleotides 5' to and three to five nucleotides 3' to a photoproduct or a CC-1065-N3-adenine adduct. They produce different incisions, however, at a CC-1065-N3-adenine adduct in the sequence 5'-GATTACG- present in the MspI-BstNI 117 bp fragment of M13mp1. UvrABCI incises at both the 5' and 3' sides of the adduct (UvrABCI cut), while UvrABCII incises only at the 5' side (UvrABCII cut). Mixing UvrCI and UvrCII results in both UvrABCI and UvrABCII cuts, and the levels of these two types of cutting are proportional to the amount of UvrCI and UvrCII. DNase I footprints of the MspI-BstNI 117 bp DNA fragment containing a site-directed CC-1065-adenine adduct at the 5'-GATTACG- site show that UvrCII, but not UvrCI, binds to the adduct site. Furthermore, the pattern of DNase I footprints induced by UvrCII binding differs from the pattern of the footprints induced by UvrA, UvrAB, and UvrABCI binding. Interestingly, while the presence of unirradiated DNA enhances the efficiency of UvrABCII in incising UV-irradiated DNA, it does not enhance UvrABCII incision of the CC-1065-N3-adenine adduct formed at 5'-GATTACG-. These results show that two different forms of UvrC differ in DNA binding properties as well as incision modes at some kinds of DNA damage.     

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.