Bacterial genes mutL, mutS, and dcm participate in repair of mismatches at 5-methylcytosine sites.

Certain amber mutations in the cI gene of bacteriophage lambda appear to recombine very frequently with nearby mutations. The aberrant mutations included C-to-T transitions at the second cytosine in 5'CC(A/T)GG sequences (which are subject to methylation by bacterial cytosine methylase) and in 5'CCAG and 5'CAGG sequences. Excess cI+ recombinants arising in crosses that utilize these mutations are attributable to the correction of mismatches by a bacterial very-short-patch (VSP) mismatch repair system. In the present study I found that two genes required for methyladenine-directed (long-patch) mismatch repair, mutL and mutS, also functioned in VSP mismatch repair; mutH and mutU (uvrD) were dispensable. VSP mismatch repair was greatly reduced in a dcm Escherichia coli mutant, in which 5-methylcytosine was not methylated. However, mismatches in heteroduplexes prepared from lambda DNA lacking 5-methylcytosine were repaired in dcm+ bacteria. These results indicate that the product of gene dcm has a repair function in addition to its methylase activity.     

Spontaneous Mutation at a 5-Methylcytosine Hotspot Is Prevented by Very Short Patch (Vsp) Mismatch Repair

In many strains of Escherichia coli, the product of gene dcm methylates the internal cytosines in the sequence 5'CC(A or T)GG. Spontaneous deamination of 5-methylcytosine produces thymine which, if not corrected, can result in a transition mutation. 5-Methylcytosines in the lacI gene are hotspots for spontaneous C to T mutations. dcm is linked to vsr, a gene required for very short patch (VSP) repair. VSP repair corrects T.G mispairs in the following contexts:CTAAGGGGTCC, CTTGGGGACC, TAGGGTCC and CTAGGGTC. I have investigated the relationships between cytosine methylation, mutation, and VSP repair. Spontaneous mutations in the repressor (cI) gene of lambda prophage were isolated in wild-type and mutant lysogens. A hotspot for spontaneous mutation that corresponds with a 5-methylcytosine was observed in wild-type lysogens but was not present in bacteria lacking both methylase and VSP repair activity. Introduction of a plasmid containing dcm+ and vsr+ restored the mutation hotspot. If the added plasmid carried only dcm+, the frequency of spontaneous mutations at the 5-methylcytosine was over 10-fold higher than in Dcm+Vsr+ lysogens. The addition of vsr on a plasmid to a wild-type lysogen resulted in a 4-fold reduction in mutation at the hotspot. These findings support the previously untested hypothesis that VSP repair prevents mutations resulting from deamination of 5-methylcytosine.     

Restriction analysis and quantitative estimation of methylated bases of filamentous and unicellular cyanobacterial DNAs.

The DNAs of strains of three cyanobacterial genera (Anabaena, Plectonema, and Synechococcus) were found to be partially or fully resistant to many restriction endonucleases. This could be due to the absence of specific sequences or to modifications, rendering given sequences resistant to cleavage. The latter explanation is substantiated by the content of N6-methyladenine and 5-methylcytosine in these genomes, which is high in comparison with that in other bacterial genomes. dcm- and dam-like methylases are present in the three strains (based on the restriction patterns obtained with the appropriate isoschizomeric enzymes). Their contribution to the overall content of methyladenine and methylcytosine in the genomes was calculated. Partial methylation of GATC sequences was observed in Anabaena DNA. In addition, the GATC methylation patterns might not have been random in the three cyanobacterial DNA preparations, as revealed by the appearance of discrete fragments (possibly of plasmid origin) withstanding cleavage by DpnI (which requires the presence of methyladenine in the GATC sequence).     

Absence in Bacillus subtilis and Staphylococcus aureus of the sequence-specific deoxyribonucleic acid methylation that is conferred in Escherichia coli K-12 by the dam and dcm enzymes

Restriction analysis of plasmid pHV14 deoxyribonucleic acid isolated from Escherichia coli K-12, Bacillus subtilis, and staphylococcus aureus with restriction endonucleases MboI, Sau3AI, and EcoRII was used to study the methylation of those nucleotide sequences which in E. coli contain the major portions of N6-methyladenine and 5-methylcytosine. The results showed that neither B. subtilis nor S. aureus methylates deoxyribonucleic acid at the same sites and nucleotides which are recognized and methylated by dam and dcm enzymes in E. coli K-12.     

Sequence and substrate specificity of isolated DNA methylases from Escherichia coli C

Two DNA methylase activities of Escherichia coli C, the mec (designates DNA-cytosine-methylase gene, which is also designated dcm) and dam gene products, were physically separated by DEAE-cellulose column chromatography. The sequence and substrate specificity of the two enzymes were studied in vitro. The experiments revealed that both enzymes show their expected sequence specificity under in vitro conditions, methylating symmetrically on both DNA strands. The mec enzyme methylates exclusively the internal cytosine residue of CCATGG sequences, and the dam enzyme methylates adenine residues at GATC sites. Substrate specificity experiments revealed that both enzymes methylate in vitro unmethylated duplex DNA as efficiently as hemimethylated DNA. The results of these experiments suggest that the methylation at a specific site takes place by two independent events. A methyl group in a site on one strand of the DNA does not facilitate the methylation of the same site on the opposite strand. With the dam methylase it was found that the enzyme is incapable of methylating GATC sites located at the ends of DNA molecules.     

DNA methylation in mycobacteria: Absence of methylation at GATC (Dam) and CCA/TGG (Dcm) sequences

Abstract The presence of 6-methyladenine and 5-methylcytosine at Dam (GATC) and Dcm (CCA/TGG) sites in DNA of mycobacterial species was investigated using isoschizomer restriction enzymes. In all species examined, Dam and Dcm recognition sequences were not methylated indicating the absence of these methyltransferases. On the other hand, high performance liquid chromatographic analysis of genomic DNA from Mycobacterium smegmatis and Mycobacterium tuberculosis showed significant levels of 6-methyladenine and 5-methylcytosine suggesting the presence of DNA methyltransferases other than Dam and Dcm. Occurrence of methylation was also established by a sensitive genetic assay.     

Presence of N6-methyladenine in GATC sequences of Bacillus popilliae and Bacillus lentimorbus KLN2.

Nine strains of Bacillus popilliae and Bacillus lentimorbus KLN2 contain N6-methyladenine in GATC sequences, as determined by using the restriction enzymes MboI and DpnI. Among eight other Bacillus species examined, all, except one strain of Bacillus brevis (ATCC 9999), lacked adenine methylation in GATC. A methylase with Escherichia coli dcm site specificity was not present in any of the Bacillus species studied.     

Expression of the Escherichia coli dam methylase in Saccharomyces cerevisiae: effect of in vivo adenine methylation on genetic recombination and mutation.

The Escherichia coli DNA adenine methylase (dam) gene has been introduced into Saccharomyces cerevisiae on a yeast-E. coli shuttle vector. Sau3AI, MboI, and DpnI restriction enzyme digests and Southern hybridization analysis indicated that the dam gene is expressed in yeast cells and methylates GATC sequences. Analysis of digests of total genomic DNA indicated that some GATC sites are not sensitive to methylation. The failure to methylate may reflect an inaccessibility to the methylase due to chromosome structure. The effects of this in vivo methylation on the processes of recombination and mutation in mitotic cells were determined. A small but definite general increase was found in the frequency of mitotic recombination. A similar increase was observed for reversion of some auxotrophic markers; other markers demonstrated a small decrease in mutation frequency. The effects on mutation appear to be locus (or allele) specific. Recombination in meiotic cells was measured and was not detectably altered by the presence of 6-methyladenine in GATC sequences.     

Methylation of ribosomal RNA genes in the macronucleus of Tetrahymena thermophila.

We have investigated the occurrence of methylated adenine residues in the macronuclear ribosomal RNA genes of Tetrahymena thermophila. It has been shown previously that macronuclear DNA, including the palindromic ribosomal RNA genes (rDNA), of Tetrahymena thermophila contains the modified base N-6-methyladenine, but no 5-methylcytosine. Purified rDNA was digested with restriction enzymes Sau 3AI, MboI and DpnI to map the positions and levels of N-6-methyladenine in the sequence 5' GATC 3'. A specific pattern of doubly methylated GATC sequences was found; hemimethylated sites were not detected. The patterns and levels of methylation of these sites did not change significantly in different physiological states. A molecular form of the rDNA found in the newly developing macronucleus and for several generations following the sexual process, conjugation, contained no detectably methylated GATC sites. However, both the bulk macronuclear DNA and palindromic rDNA from the same macronuclei were methylated. Possible roles for N-6-methyladenine in macronuclear DNA are discussed in light of these findings.     

Selection againstdam methylation sites in the genomes of DNA of enterobacteriophages

Summary Postreplicative methylation of adenine inEscherichia coli DNA to produce G^6m ATC (where^6mA is 6-methyladenine) has been associated with preferential daughter-strand repair and possibly regulation of replication. An analysis was undertaken to determine if these, or other, as yet unknown roles of GATC, have had an effect on the frequency of GATC inE. coli or bacteriophage DNA. It was first ascertained that the most accurate predictions of GATC frequency were based on the observed frequencies of GAT and ATC, which would be expected since these predictors take into account preferences in codon usage. The predicted frequencies were compared with observed GATC frequencies in all available bacterial and phage nucleotide sequences. The frequency of GATC was close to the predicted frequency in most genes ofE. coli and its RNA bacteriophages and in the genes of nonenteric bacteria and their bacteriophages. However, for DNA enterobacteriophages the observed frequency of DNA enterobacteriophages the observed frequency of GATC was generally significantly lower than predicted when assessed by the chi square test. No elevation in the rate of mutation of^6mA in GATC relative to other bases was found when pairs of DNA sequences from closely related phages or pairs of homologous genes from enterobacteria were compared, nor was any preferred pathway for mutation of^6mA evident in theE. coli DNA bacteriophages. This situation contrasts with that of 5-methylcytosine, which is hypermutable, with a preferred pathway to thymine. Thus, the low level of GATC in enterobacteriophages is probably due not to^6mA hypermutability, but to selection against GATC in order to bypass a GATC-mediated host function.     

Very short patch repair: reducing the cost of cytosine methylation

In Escherichia coli and related bacteria, the product of gene dcm methylates the second cytosine of 5'-CCWGG sequences (where W is A or T). Deamination of 5-methylcytosine (5meC) results in C to T mutations. The mutagenic potential of 5meC is reduced by a system called very short patch (VSP) repair, which replaces T with C. T:G and U:G mispairs in the methylatable sequence and in related sequences are recognized by the product of vsr , a gene adjacent to dcm . Vsr creates a nick just 5' of the mispaired pyrimidine to initiate the repair. Additional products known to be required for VSP repair are DNA polymerase I and DNA ligase. MutS and MutL have a stimulatory role but are not required. The ability of Vsr to recognize T:G mispairs in sequences related to CCWGG is probably responsible for over- and under-representation of certain tetranucleotides in the E. coli genome. Although VSP repair reduces spontaneous mutations at 5meCs in replicating bacteria, mutation hot-spots persist at these sites. Under conditions that more accurately mimic the natural environment of E. coli , VSP repair appears to be effective in preventing mutation at 5meC.     

Partially deficient methylation of cytosine in DNA at CCATGG sites stimulates genetic recombination of bacteriophage lambda

Lambda bacteriophages grown on arl mutants of Escherichia coli ("Arl-" phages) display intermediate levels of cytosine methylation: less 5-methylcytosine (m5C) than phages grown on wild-type bacteria ("Arl+" phages) but more than phages grown on dcm mutants, and thus lacking the methylated sequences (Cm5CATGG) characteristic of E. coli K-12 bacteria ("Dcm-" phages). "Arl-" phages are one twelfth as resistant to Eco RII restriction (recognition site CCATGG) as "Arl+" phages, but 40-fold more resistant than "Dcm-" phages. Chromatographic analyses show the 5-methylcytosine content of "Arl-" DNA to be one third that of "Arl+" DNA. Altered cytosine methylation frequency correlates with two previously described properties of "Arl-" phages, increased genetic recombination and unusual sensitivity of phage DNA to endonuclease S1, which are absent in phages grown on dcm or dcm arl bacteria. Methylated/unmethylated heteroduplex DNA prepared in vitro (one strand from Eco RII-modified phages/one from "Dcm-" phages) is highly recombinogenic but not S1-sensitive. We hypothesize that hemimethylated CCATGG sites in "Arl-" DNA are necessary and sufficient for enhanced recombination, and necessary but not sufficient for S1 sensitivity.     

Plasmid-controlled variation in the content of methylated bases in single-stranded DNA bacteriophages M13 and fd

The N⁶-methyladenine and 5-methylcytosine contents in the DNA of bacteriophages M13 and fd have been analyzed. The results are summarized as follows. (1) After growth in bacteria harboring the N-3ft^? drug resistance-factor, fd and M13 are observed to contain approximately 1 to 2 more 5-methylcytosine residues per DNA molecule than after growth in the parental drug-sensitive host; no effect on the N⁶-methyladenine content is produced by the plasmid. (2) After growth in bacteria harboring P1 prophage, fd and M13 are observed to contain approximately 2 to 3 more N⁶-methyladenine residues per DNA molecule than after growth in the parental P1-sensitive host; no apparent effect on the 5-methylcytosine content was produced by the P1 plasmid. (3) In agreement with others, fd carrying B-host specificity (fd·B) is observed to contain 2 more N⁶-methyladenine residues/DNA molecule than fd·K.     

Expression of Escherichia coli dam gene in Bacillus subtilis provokes DNA damage response: N6-methyladenine is removed by two repair pathways.

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.     

The effect of differential methylation by Escherichia coli of plasmid DNA and phage T7 and lambda DNA on the cleavage by restriction endonuclease MboI from Moraxella bovis.

The nucleotide sequence recognized and cleaved by the restriction endonuclease MboI is 5' GATC and is identical to the central tetranucleotide of the restriction sites of BamHI and BglII. Experiments on the restriction of DNA from Escherichia coli dam and dam+ confirm the notion that GATC sequences are adenosyl-methylated by the dam function of E. coli and thereby are made refractory to cleavage by MboI. On the basis of this observation the degree of dam methylation of various DNAs was examined by cleavage with MboI and other restriction endonucleases. In plasmid DNA essentially all of the GATC sequences are methylated by the dam function. The DNA of phage lambda is only partially methylated, extended methylation is observed in the DNA of a substitution mutant of lambda, lambda gal8bio256, and in the lambda derived plasmid, lambdadv93, which is completely methylated. In contrast, phage T7 DNA is not methylated by dam. A suppression of dam methylation of T7 DNA appears to act only in cis dam. A suppression of dam methylation of T7 DNA appears to act only in cis since plasmid DNA replicated in a T7-infected cell is completely methylated. The results are discussed with respect to the participation of the dam methylase in different replication systems.     

Methylation of spore DNA in Bacillus coagulans strain 26

The modification status of DNA throughout the life cycle of Bacillus coagulans strain 26 was analysed by restriction analysis with methylation-sensitive enzymes. A significant fraction of the GATC sequences (dam target) in spore DNA contain N6-methyladenine, a modification that is lacking during the vegetative phase. From the modulation of the modification pattern of GATC sites, the existence of a de novo methylase may be inferred. Spore DNA was more sensitive than vegetative cell DNA to BamHI, HpaI, SalI and XhoI, indicating that the sites for these enzymes are modified during the vegetative growth phase.     

Characterization of a unique methyl-specific restriction system in Streptomyces avermitilis.

Streptomyces avermitilis contains a unique restriction system that restricts plasmid DNA containing N6-methyladenine or 5-methylcytosine. Shuttle vectors isolated from Escherichia coli RR1 or plasmids isolated from modification-proficient Streptomyces spp. cannot be directly introduced into S. avermitilis. This restriction barrier can be overcome by first transferring plasmids into Streptomyces lividans or a modification-deficient E. coli strain and then into S. avermitilis. The transformation frequency was reduced greater than 1,000-fold when plasmid DNA was modified by dam or TaqI methylases to contain N6-methyladenine or by AluI, HhaI, HphI methylases to contain 5-methylcytosine. Methyl-specific restriction appears to be common in Streptomyces spp., since either N6-methyladenine-specific or 5-methylcytosine-specific restriction was observed in seven of nine strains tested.     

The Neisseria gonorrhoeae S.NgoVIII restriction/modification system: a type IIs system homologous to the Haemophilus parahaemolyticus HphI restriction/modification system.

Strains of Neisseria gonorrhoeae possess numerous restriction-modification (R-M) systems. One of these systems, which has been found in all strains tested, encodes the S. NgoVIII specificity (5'TCACC 3') R-M system. We cloned two adjacent methyltransferase genes (dcmH and damH), each encoding proteins whose actions protect DNA from digestion by R.HphI or R.Ngo BI (5'TCACC 3'). The damH gene product is a N 6-methyladenine methyltransferase that recognizes this sequence. We constructed a plasmid containing multiple copies of the S.NgoVIII sequence, grew it in the presence of damH and used the HPLC to demonstrate the presence of N 6-methyladenine in the DNA. A second plasmid, containing overlapping damH and Escherichia coli dam recognition sequences in combination with various restriction digests, was used to identify which adenine in the recognition sequence was modified by damH. The predicted dcmH gene product is homologous to 5-methylcytosine methyltransferases. The products of both the dcmH and damH genes, as well as an open reading frame downstream of the damH gene are highly similar to the Haemophilus parahaemolyticus hphIMC , hphIMA and hphIR gene products, encoding the Hph I Type IIs R-M system. The S.NgoVIII R-M genes are flanked by a 97 bp direct repeat that may be involved in the mobility of this R-M system.     

N4-methylcytosine as a minor base in bacterial DNA.

The DNA base composition, including the minor base content, of 26 strains of bacteria was determined. The studied bacteria are sources of widely used restriction endonucleases. Approximately 35% of the bacterial DNAs contained N4-methylcytosine, about 60% contained 5-methylcytosine, and about 90% had N6-methyladenine.     

The effect of methylation on DNA replication in Salmonella enterica serovar typhimurium

The DNA adenine methylase of Salmonella typhimurium methylates adenine at GATC sequences. Strains deficient in this methylase are not well transformed by methylated plasmids, but unmethylated plasmids transform them at high frequencies. Hemimethylated daughter molecules accumulate after the transformation of dam(-) strains with fully methylated plasmids, suggesting that hemimethylation prevents DNA replication. It will also be shown that plasmids isolated from dam(-) bacteria are hemimethylated by restriction enzyme digestion. These results may explain why newly formed daughter molecules are not substrates for immediate reinitiation of DNA replication in dam(-) bacteria.