Study of the methylation process and DNA methylase specificity in Shigella]

The nature and content of minor bases in DNA of 3 Shigella strains are investigated. DNAs from Shigella stutzeri 2, Sh. sonnei 1188 and Sh. sonnei 311 are found to contain 0.43, 0.56 and 0.45 mol.% of N6-methyladenine respectively. 5-methylcytosine (0.16 mol.%) is discovered in Sh. sonnei 311. Substrate specificity of adenine methylase from Sh. sonnei 1188 with respect to phage DNAs of different host modification is investigated. Recognition sites for guanine methylase of DDVI phage and for adenine methylase of Sh. sonnei 1188 turned to be different. DNA of DDII phage grown in Sh. stutzeri 2 cells does not accept methyl groups under the treatment with Sh. sonnei 1188 extracts, but it is methylated by Escherichia coli extract. Adenine methylases of Sh. sonnei 1188 and Sh. stutzeri 2 are suggested to be either the same enzyme, or enzymes, which recognition sites are partially overlapped.     

Some peculiarities of phage DDVI-specific methylases]

The types of methylases are found in the cellular extract of Escherichia coli B, infected with phage DDVI. One of them is a cellular enzyme, which methylates adenine to form 6-methylaminopurine (6-MAP) and is repressed in the infected cell in vivo. The second type, which is not found in the non-infected cells, is specific for phage DDVI and induces the formation of 7-methylguanine (7-MG). Both enzymes recognize various sites, which accounts for the ratio 6-MAP/7-MG to vary in heterological DNAs between 2.07 in phage Sd DNA and 0.40 in phage DDII DNA. During in vitro incubation with homologous methylases phage DDVI DNA and especially phage T2 DNA are subjected to further methylation, which is probably indicative of their "undermethylation" in vivo. The DDVI-specific enzyme, similar to B-specific type, methylates DNA with a normal set of nitrogenous bases (phages Sd and DDII), as well as DNAs containing 5-oxymethylcytosine and glucose (phages T2 and DDVI). Both methylases under study use only native double-helical DNA as substrate and are strongly inhibited by S-adenosylhomocysteine. Phage DDVI Methylase is characterized by low stability.     

Fractionation and purification of DNA methylases and specific endonucleases from cells of Escherichia coli SK]

Fractionation and purification of DNA methylases and specific endonucleases from E. coli SK responsible for DNA specificity to host prokaryotic cells were studied. The most efficient purification was achieved by precipitation of proteins by 0.6 saturated ammonium sulfate with subsequent chromatography on KM-cellulose and concentration of fractions by dialysis against glycerol. Under these conditions the methylase activity produced 4 discrete fractions. Due to purification the specific activity of methylases increased 11--20-fold in various fractions. Methylase from the first (A) and fourth (BII) peaks catalyzed the methylation of cytosine to produce 5-methylcytosine; methylase from the third peak (BI) methylated adenine to produce 6-methylaminopurine. The chemical specificity of the second peak (B) methylase could not be established due to very high lability of the enzyme in this fraction. Specific endonuclease was found in the gradient zones eluted by 0.1--0.2 M and 0.65--0.75 M NaCl. It is assumed that those enzymes providing for DNA hydrolysis up to the formation of high--molecular discrete fragments, are restricting endonucleases of the SK system. The results obtained strongly suggest the existence of several types of methylases and restricting endonucleases in E. coli SK cells.     

Recognition sequence of the dam methylase of Escherichia coli K12 and mode of cleavage of Dpn I endonuclease.

The recognition sequence for the dam methylase of Escherichia coli K12 has been determined directly by use of in vivo methylated ColE1 DNA or DNA methylated in vitro with purified enzyme. The methylase recognizes the symmetric tetranucleotide d(pG-A-T-C) and introduces two methyl groups per site in duplex DNA with the product of methylation being 6-methylaminopurine. This work has also demonstrated that Dpn I restriction endonuclease cleaves on the 3' side of the modified adenine within the methylated sequence to yield DNA fragments possessing fully base-paired termini. All sequences in ColE1 DNA methylated by the dam enzyme are subject to double strand cleavage by Dpn I endonuclease. Therefore, this restriction enzyme can be employed for mapping the location of sequences possessing the dam modification.     

The host specificity system inEscherichia coli SK

E. coli SK has its own enzyme system providing DNA host specificity which differs from the known types of specificity inE. coli K12 andE. coli B. Modification and restriction are observed when the PBVI or PBV3 phages are transferred fromE. coli SK toE. coli B or K12 (and back).A methylase has been isolated fromE. coli SK cells and partly purified. This methylase catalyzesin vitro transfer of the labelled methyl groups from S-adenosylmethionine (SAM) to DNA of both phage and tissue origin which gives rise to 5-methylcytosine (5MC) and 6-methylaminopurine (6MAP). The methylase preparations isolated from the cells at the stationary growth have proved to be 1.5–1.7 times as active as the enzyme from the cells at the logarithmic growth stage. The extract ofE. coli SK cells infected with the phage S_D cannot methylate DNAin vitro. This fact is due tode novo synthesis of the enzyme which disintegrates SAM down to 5-methylthioadenosine (5MTA) and homoserine (HS). This enzyme is not found in the cells infected with the S_D phage in the presence of chloroamphenicole. The activity of the enzyme which disintegrates SAM is the highest between the 4th and the 5th minutes of infection. Thus it may be assumed that this enzyme, most probably, is an early virus specific protein and preventsin vivo methylation of the phage DNA.     

Methylated Bases of Bacillus megaterium KM Nucleic Acids: Comparison with Escherichia coli

Parallel studies were performed with methionineless derivatives of Escherichia coli 15 T(-) and Bacillus megaterium KM: T(-). Methylated bases are present in the total cell ribonucleic acid (RNA) of B. megaterium. The level of RNA methylation in E. coli is about 60% greater than that in B. megaterium. Although E. coli deoxyribonucleic acid (DNA) was found to contain 0.12% 5-methylcytosine (5-MC) and 0.24% 6-methylaminopurine (6-MA), methylated bases were not detected in the DNA of B. megaterium. Assuming a molecular weight of 7 x 10(9) daltons for B. megaterium DNA, it was calculated that this organism could not contain more than one molecule of 5-MC or 6-MA per genome, and that possibly no methylated bases were present. Methylated bases were also not detected in the DNA of thymine-starved B. megaterium. Crude extracts of this organism possess RNA methylase activity but no detectable DNA methylase activity.     

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.     

In vivo methylation by Escherichia coli K-12 mec+ deoxyribonucleic acid-cytosine methylase protects against in vitro cleavage by the RII restriction endonuclease (R. Eco RII).

We have analyzed the susceptibility of the deoxyribonucleic acid (DNA) of phage fd replicative form (RF) and of Escherichia coli to in vitro cleavage by purified RII restriction endonuclease (R. Eco RII). The results are summarized as follows: (i) fd, mec- RFI, isolated from infected E. coli K-12 mec- bacteria (a mutant strain lacking DNA-cytosine methylase activity), is cleaved into at least two fragments, whereas fd. mec+ RFI, isolated from the parental mec+ strain, is not cleaved. (ii) E. coli mec- DNA is extensively degraded, whereas mec+ DNA-cytosine methylase acts as an RII modification enzyme.     

Cloning the BamHI restriction modification system.

BamHI, a Type II restriction modification system from Bacillus amyloliquefaciensH recognizes the sequence GGATCC. The methylase and endonuclease genes have been cloned into E. coli in separate steps; the clone is able to restrict unmodified phage. Although within the clone the methylase and endonuclease genes are present on the same pACYC184 vector, the system can be maintained in E. coli only with an additional copy of the methylase gene present on a separate vector. The initial selection for BamHI methylase activity also yielded a second BamHI methylase gene which is not homologous in DNA sequence and hybridizes to different genomic restriction fragments than does the endonuclease-linked methylase gene. Finally, the interaction of the BamHI system with the E. coli Dam and the Mcr A and B functions, have been studied and are reported here.     

Bacteriolytic enzymes of Vi phage III lysate.

Vi phage III infected Salmonella typhi cells were shown to contain two activities which lyse the chloroform-killed E. coli B cells. These enzymes have been separated by chromatography on CM-cellulose column and identified as the D-alanyl-meso-DAP endopeptidase and the N-acetylmuramyl-L-ala-nine amidase. The substrate specificity of these enzymes was investigated using low molecular weight muropeptides C3 and C6. It has been shown that muropeptide C3, the cross-linking unit in E coli B murein is completely resistant to the amidase action. This property of Vi phage III amidase suggested that this enzyme does not possess the ability to cause lysis, at the end of the production cycle, of host-bacteria infected with this phage.     

Molecular cloning and expression in Escherichia coli of two modification methylase genes of Bacillus subtilis

Two modification methylase genes of Bacillus subtilis R were cloned in Escherichia coli by using a selection procedure which is based on the expression of these genes. Both genes code for DNA-methyltransferases which render the DNA of the cloning host E. coli HB101 insensitive to the BspRI (5'-GGCC) endonuclease of Bacillus sphaericus R. One of the cloned genes is part of the restriction-modification (RM) system BsuRI of B. subtilis R with specificity for 5'-GGCC. The other one is associated with the lysogenizing phage SP beta B and produces the methylase M.BsuP beta BI with specificity for 5'-GGCC. The fragment carrying the SP beta B-derived gene also directs the synthesis in E. coli of a third methylase activity (M.BsuP beta BII), which protects the host DNA against HpaII and MspI cleavage within the sequence 5'-CCGG. Indirect evidence suggests that the two SP beta B modification activities are encoded by the same gene. No cross-hybridization was detected either between the M.BsuRI and M.BsuP beta B genes or between these and the modification methylase gene of B. sphaericus R, which codes for the enzyme M.BspRI with 5'-GGCC specificity.     

The irreversible binding of azacytosine-containing DNA fragments to bacterial DNA(cytosine-5)methyltransferases

DNA containing 5-azacytosine is an irreversible inhibitor of DNA(cytosine-5)methyltransferase. This paper describes the binding of DNA methyltransferase to 32P-labeled fragments of DNA containing 5-azacytosine. The complexes were identified by gel electrophoresis. The EcoRII methyltransferase specified by the R15 plasmid was purified from Escherichia coli B(R15). This enzyme methylates the second C in the sequence CCAGG and has a molecular mass of 60,000 Da. Specific binding of enzyme to DNA fragments could be detected if either excess unlabeled DNA or 0.8% sodium dodecyl sulfate was added to the reaction mixture prior to electrophoresis. Binding was dependent upon the presence of both the CCAGG sequence and azacytosine in the DNA fragment. S-Adenosylmethionine stimulated the formation of the complex. The complex was stable to 6 M urea but could be digested with pronase. These DNA fragments could be used to detect the presence of several different methyltransferases in crude extracts of E. coli. No DNA protein complexes could be detected in E. coli B extracts, a strain that contains no DNA(cytosine-5)methyltransferases. The chromosomally determined methylase with the same specificity as the purified EcoRII methylase could be detected in crude extracts of E. coli K12 strains. The MspI methylase cloned in E. coli HB101 could also be detected in crude extracts. These enzymes are the only proteins that bind azacytosine-containing DNA in crude extracts of E. coli.     

DNA methylases of Hemophilus influenzae Rd. I. Purification and properties

Hemophilus influenzae strain Rd DNA contains small amounts of 5-methylcytosine (0.012%) and significantly greater amounts of N-6-methyladenine (0.34%). Four DNA adenine methylases have been identified and purified from crude extracts of H. influenzae Rd by means of phosphocellulose chromatography. Each of the four enzymes requires (S-adenosyl-l-methionine as a methyl group donor and each differs in its ability to methylate various DNAs in vitro. DNA methylase I is related to the genetically described modification-restriction system in H. influenzae Rd, and is presumably the modification enzyme for that system. DNA methylase II introduces approximately 130 methyl groups into a phage T7 DNA molecule and protects T7 DNA from the H. influenzae Rd restriction enzyme, endonuclease R, described by Smith and Wilcox (1970). These findings indicate that DNA methylase II is the modification enzyme corresponding to endonuclease R. A third modification-restriction system, which does not affect T7 DNA, has been detected in H. influenzae Rd. DNA methylase III is apparently the modification enzyme for this system. The biological function of DNA methylase IV remains unknown.     

Excision of Thymine Dimers In Vitro by Extracts of Bacteriophage-Infected Escherichia coli

Extracts of DNA polymerase I defective Escherichia coli infected with phage T4 contain an exonuclease activity that removes thymine dimers from UV-irradiated DNA previously nicked with T4 UV endonuclease. This activity is not expressed if cells are infected in the presence of chloramphenicol. The enzyme has a requirement for divalent cation and is not affected by caffeine, but excision is inhibited in the presence of proflavine. The enzyme is present in all phage T4 mutants thus far examined, including 25 UV-sensitive mutants isolated during the course of the experiments, all of which are defective in the v gene. A similar activity can be detected in cells infected with phages T2, T3, and T6, but not in cells infected with phage T7.     

Temperate Myxococcus xanthus phage Mx8 encodes a DNA adenine methylase, Mox.

Temperate bacteriophage Mx8 of Myxococcus xanthus encapsidates terminally repetitious DNA, packaged as circular permutations of its 49-kbp genome. During both lytic and lysogenic development, Mx8 expresses a nonessential DNA methylase, Mox, which modifies adenine residues in occurrences of XhoI and PstI recognition sites, CTCGAG and CTGCAG, respectively, on both phage DNA and the host chromosome. The mox gene is necessary for methylase activity in vivo, because an amber mutation in the mox gene abolishes activity. The mox gene is the only phage gene required for methylase activity in vivo, because ectopic expression of mox as part of the M. xanthus mglBA operon results in partial methylation of the host chromosome. The predicted amino acid sequence of Mox is related most closely to that of the methylase involved in the cell cycle control of Caulobacter crescentus. We speculate that Mox acts to protect Mx8 phage DNA against restriction upon infection of a subset of natural M. xanthus hosts. One natural isolate of M. xanthus, the lysogenic source of related phage Mx81, produces a restriction endonuclease with the cleavage specificity of endonuclease BstBI.     

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.     

Role of Gene 52 in Bacteriophage T4 DNA Synthesis

In an attempt to elucidate the mechanism of delayed DNA synthesis in phage T4, Escherichia coli B cells were infected with H17 (an amber mutant defective in gene 52 possessing a "DNA-delay" phenotype). The fate of (14)C-labeled H17 parental DNA after infection was followed: we could show that this DNA sediments more slowly in neutral sucrose than wild-type DNA 3 min postinfection. In pulse-chase experiments progeny DNA was found to undergo detachment from the membrane at 12 min postinfection. Reattachment to the membrane was found to be related to an increase in rate of DNA synthesis. A nucleolytic activity that is absent from cells infected by wild-type phage and from uninfected cells could be detected in extracts prepared from mutant-infected cells. In contrast, degradation of host DNA was found to be less extensive in am H17 compared with wild-type infected cells. Addition of chloramphenicol to mutant-infected cells 10 min postinfection inhibited the appearance of a nuclease activity on one hand and suppressed the "DNA-delay" phenotype on the other hand. We conclude that the gene 52 product controls the activity of a nuclease in infected cells whose main function may be specific strand nicking in association with DNA replication. This gene product might directly attack both E. coli and phage T4 DNA, or indirectly determine their sensitivity to degradation by another nuclease.     

Substrate recognition and selectivity in the type IC DNA modification methylase M.EcoR124I.

The type I DNA modification methylase M.EcoR124I binds sequence specifically to DNA and protects a 25bp fragment containing its cognate recognition sequence from digestion by exonuclease III. Using modified synthetic oligonucleotide duplexes we have investigated the catalytic properties of the methylase, and have established that a specific adenine on each strand of DNA is the site of methylation. We show that the rate of methylation of each adenine is increased at least 100 fold by prior methylation at the other site. However, this is accompanied by a significant decrease in the affinity of the methylase for these substrates according to competitive gel retardation assays. In contrast, methylation of an adenine in the recognition site which is not a target for the enzyme results in only a small decrease in both DNA binding affinity and rate of methylation by the enzyme.     

Host-controlled Restriction of T-even Bacteriophages: Relation of Four Bacterial Deoxyribonucleases to Restriction

Escherichia coli strains B and K-12, which restrict growth of nonglucosylated T- even phage (T(*) phage), and nonrestricting strains (Shigella sonnei and mutants of E. coli B) were tested for levels of endonuclease I and exonucleases I, II, and III, by means of in vitro assyas. Cell-free extracts freed from deoxyribonucleic acid (DNA) were examined with three substrates: E. coli DNA, T(*)2 DNA, and T2 DNA. Both restricting and nonrestricting strains had comparable levels of the four nuclease activities and had similar patterns of preference for the three substrates. In addition, mutants of E. coli B and K-12 that lack endonuclease I were as effective as their respective wild types in restricting T(*) phage.     

In vivo methylation of bacteriophage phi X174 DNA.

A mutant (designated mec(-)) has been isolated from Escherichia coli C which has lost DNA-cytosine methylase activity and the ability to protect phage lambda against in vivo restriction by the RII endonuclease. This situation is analogous to that observed with an E. coli K-12 mec(-) mutant; thus, the E. coli C methylase appears to have overlapping sequence specificity with the K-12 and RII enzymes; (the latter methylases have been shown previously to recognize the same sequence). Covalently closed, supertwisted double-standed DNA (RFI) was isolated from C mec(+) and C mec(-) cells infected with bacteriophage phiX174. phiX. mec(-) RFI is sensitive to in vitro cleavage by R.EcoRII and is cut twice to produce two fragments of almost equal size. In contrast, phiX.mec(+) RFI is relatively resistant to in vitro cleavage by R.EcoRII. R.BstI, which cleaves mec(+)/RII sites independent of the presence or absence of 5-methylcytosine, cleaves both forms of the RFI and produces two fragments similar in size to those observed with R. EcoRII. These results demonstrate that phiX.mec(+) RFI is methylated in vivo by the host mec(+) enzyme and that this methylation protects the DNA against cleavage by R.EcoRII. This is consistent with the known location of two mec(+)/ RII sequences (viz., [Formula: see text]) on the phiX174 map. Mature singlestranded virion DNA was isolated from phiX174 propagated in C mec(+) or C mec(-) in the presence of l-[methyl-(3)H]methionine. Paper chromatographic analyses of acid hydrolysates revealed that phiX.mec(+) DNA had a 10-fold-higher ratio of [(3)H]5-methylcytosine to [(3)H]cytosine compared to phiX.mec(-). Since phiX.mec(+) contains, on the average, approximately 1 5-methylcytosine residue per viral DNA, we conclude that methylation of phiX174 is mediated by the host mec(+) enzyme only. These results are not consistent with the conclusions of previous reports that phiX174 methylation is mediated by a phage-induced enzyme and that methylation is essential for normal phage development.