Fractionation and specificity of DNA methylases from the Escherichia coli SK cells

Summary Specificity of DNA methylation enzymes from the E. coli SK cells and conditions for their separation have been investigated. Column chromatography on carboxymethylcellulose permits fractionation of methylase activity into six discrete peaks whose specificity to the methylated base has been determined in vitro with H³-SAM as precursor. All methylases specific for adenine produced 6-methylaminopurine, all methylases specific for cytosine yielded 5-methylcytosine.The first enzymatic activity peak containing cytosine methylase free of traces of adenine-methyiating activity (E₁), and the second peak containing both the enzymes (E₂) were not adsorbed on the ion exchanger and went off the column with the effluent (column buffer). Adenine specific methylase E₂ is retarded to a small extent during the passage through the column. The second adenine methylases (W) was characterized by weak bonds with the ion exchanger and was removed when washing the column with column buffer. The elution with NaCl gradient produced successively three enzymatic activity peaks: adenine methylase (G_I), cytosine methylase (G_II), and one more adenine methylase (G_III) removed from the column by 0.16 m, 0.24 m and 0.43 m NaCl respectively.Using a new modification of the complementary methylation test, the specificity with regard to recognition site was examined for all enzymes, except for W and G_III, which were extremely unstable. The adenine methylases E₂ and G_I and the cytosine methylases E₁ and G_II were shown to recognize different sites and to be different enzymes. In view of the drastic differences in their chromatographic behaviour and physical stability, the adenine methylases W and G_III are probably also different enzymes.     

Sequence specificity of DNA methylases from Bacillus amyloliquefaciens and Bacillus brevis

DNA methylation in Bacillus amyloliquefaciens strain H (Bam)² and Bacillus brevis (Bbv) has been examined by a variety of techniques. In vivo labelling studies revealed that Bam DNA contains no N⁶-methyladenine (MeAde), but contains 5-methylcytosine (MeCyt); approximately 0·7% of the cytosine residues are methylated.DNA methylase activity was partially purified from both Bam and Bbv; the Bam enzyme preparation transferred methyl groups from S-adenosyl-l-[methyl-³H]methionine ([³H]AdoMet) to specific DNA cytosine residues only; in agreement with Vanyushin & Dobritsa (1975), the Bbv enzyme preparation methylated both DNA adenine and cytosine residues. The (partial) sequence specificity of the methylases was determined by analyzing [³H]methyl-labelled dinucleotides obtained from enzymatic digests of DNA methylated in vitro. Bam and Bbv each contain a DNA-cytosine methylase with overlapping sequence specificity; e.g. both enzymes produce G-C1, C1-A and C1-T. This is consistent with a single, twofold symmetrical methylation sequence of 5′ … G-C1-(A or T)-G-C … 3′; this was observed by Vanyushin & Dobritsa (1975) for a different Bbv strain. Bam contains a second DNA-cytosine methylase (not present in Bbv), which produces T-C1 and C1-T. We propose that this methylase is the BamI modification enzyme, and that the modified sequence is 5′ … G-G-A-T-C1-C … 3′.Bbv appears to contain two DNA-adenine methylases which produce the (partial) methylated sequences, 5′ … G-A1-T … 3′ and 5′ … A-A1-G … 3′, respectively; in the former case, all the G-A-T-C sites on Bbv DNA appear to be methylated.     

Sequence specificity of isolated DNA-cytosine methylases from Shigella sonnei 47 cells

Five individual DNA-cytosine methylases differing in pI (isoelectric point) values are present in Shigella sonnei 47-cells. The sequence specificity of each of those was determined 'in vitro' by a highly efficient combined approach that included pyrimidine tract (isostic) analysis, identification of the immediate neighbourhood of the methylated base within the recognition sequence and the calculation method. The enzyme with pI 5.3 (MSso5.3) is the counterpart of the RSso 47 II in the Sso 47 II restriction-modification system and methylates the internal cytosine residue of the 'palindromic' 5'-C-C-N-G-G-3' sequence. The enzymes with pI 6.2 (MSso6.2) and 7.4 (MSso7.4) exhibit identical specificity upon methylation of the 'palindromic' 5'-Py-C-N-G-Pu-3' sequence, but differ in the pI values of the proteins. The enzyme with pI 4.2 (MSso4.2) recognizes the unique tetranucleotide 5'-C-C-C-C-3' sequence and methylates the second cytosine residue at the 5'-end of the sequence. The enzyme with pI 8.4 (MSso8.4) methylates the central cytosine residue within the degenerative trinucleotide 5'-(PuC)-C-C-3' sequence. MSso5.3, MSso6.2, and MSso7.4 are presumed to belong to the 'family' of sequence-specific (Eco RII-like) enzymes. These DNA-cytosine methylases are likely to be evolutionary related to Eco RII and to have undergone a sufficient genetic drift so as to recognize similar (but more degenerative) nucleotide sequences.     

On heterogeneity of DNA methylases from Escherichia coli SK cells

Summary The presence ofE. coli SK cells of five different DNA-methylases differing in specificity to the methylated sequence is documented has been proven. Two enzymes methylate cytosine with the formation of 5′-methylcytosine and three enzymes methylate adenine with formation of 6′-methylaminopurine. A method for simultaneous isolation of the five individual enzymes including gel filtration on Biogel A-0.5 M is proposed. The direct evidence has been presented showing that the additional methylation test in our method modification actually can discriminate between enzymes differing in sensitive sites.     

Sequence specificity of isolated DNA-adenine methylases from Mycobacterium smegmatis (butyricum) and Shigella sonnei 47 cells

A set of four individual DNA-adenine methylases differing in pI (isoelectric point) values (MMbu4.2, MMbu6.4, MMbu7.3, and MMbu8.7), and a sole methylating enzyme with the same base specificity (MSso9.5) are present in M. smegmatis (butyricum) and Sh. sonnei 47 cells, respectively. The sequence specificity of each of those was studied 'in vitro' by a combined approach that comprised isostich (purine tract) analysis and identification of the immediate neighbourhood of the methylated base within the sequence methylated. The MSso9.5 recognition site has been established as the hexanucleotide 'palindromic' 5'-G-A-A-T-T-C-3' sequence which is structurally similar to the analogous MEco RI recognition site. However, in contrast to MEco RI, MSso9.5 methylates the 5'-end adenine residue in the sequence and thus it appears to be an isometimer of MEco RI. By means of the same approach, the partial nucleotide sequences methylated by each of the four individual M. butyricum enzymes were determined. MMbu7.3 and MMbu8.7 exhibit the identical sequence specificity upon methylation of the degenerative trinucleotide 5'-Py-A-Py-3' sequence and thus these enzymes are assumed to represent the different molecular forms of the methylase. MMbu4.2 methylates the 5'-G-G-A-3' sequence and thus it is of a great value as the tool for negating effects of the RBam HI and RAva II-type restriction. MMbu6.4 is of a particular interest on account of its unique DNA methylation pattern which is distinguished in the pronounced clustering of purine bases in the 5'-Pu-Pu-Pu-Pu-Pu-3' sequence methylated.     

Studies on the substrate specificity of the DNA methylase activity from Escherichia coli K-12.

A partially purified extract of DNA methylases from E. coli K-12 containing DNA-adenine as well as DNA-cytosine methylase activities has been examined with respect to different DNA species as substrates. The results show that the natural content of 6-MAP) in the applied DNA represses the DNA-adenine methylase activity. On the other hand, 5-MC, already present in the substrate does not influence the activity of the DNA-cytosine methylase. DNA from Micrococcus radiodurans, which is completely free of methylated bases served as comparison. Since netropsin preferentially binds to AT-rich regions of DNA, the influence of this oligopeptide antibiotic on the methylation of DNA was investigated. As expected the antibiotic predominantly inhibits adenine methylation of DNA. The degree of inhibition depends on the molar ratio of netropsin to DNA phosphate.     

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.     

Sequence and functional-group specificity for cleavage of DNA junctions by RuvC of Escherichia coli.

RuvC is the DNA junction-resolving enzyme of Escherichia coli. While the enzyme binds to DNA junctions independently of base sequence, it exhibits considerable sequence selectivity for the phosphodiester cleavage reaction. We have analyzed the sequence specificity using a panel of DNA junctions, measuring the rate of cleavage of each under single-turnover conditions. We have found that the optimal sequence for cleavage can be described by (A approximately T)TT downward arrow(C>G approximately A), where downward arrow denotes the position of backbone scission. Cleavage is fastest when the cleaved phosphodiester linkage is located at the point of strand exchange. However, cleavage is possible one nucleotide 3' of this position when directed by the sequence, with a rate that is 1 order of magnitude slower than the optimal. The maximum sequence discrimination occurs at the central TT in the tetranucleotide site, where any alteration of sequence results in a rate reduction of at least 100-fold and cleavage is undetectable for some changes. However, certain sequences in the outer nucleotides are strongly inhibitory to cleavage. Introduction of base analogues around the cleavage site reveals a number of important functional groups and suggests that major-groove contacts in the center of the tetranucleotide are important for the cleavage process. Since RuvC binds to all the variant junctions with very similar affinity, any contacts affecting the rate of cleavage must be primarily important in the transition state. Introduction of the optimal cleavage sequence into a three-way DNA junction led to relatively efficient cleavage by RuvC, at a rate only 3-fold slower than the optimal four-way junction. This is consistent with a protein-induced alteration in the conformation of the DNA.     

L-aspartase from Escherichia coli: substrate specificity and role of divalent metal ions

The enzyme L-aspartase from Escherichia coli has an absolute specificity for its amino acid substrate. An examination of a wide range of structural analogues of L-aspartic acid did not uncover any alternate substrates for this enzyme. A large number of competitive inhibitors of the enzyme have been characterized, with inhibition constants ranging over 2 orders of magnitude. A divalent metal ion is required for enzyme activity above pH 7, and this requirement is met by many transition and alkali earth metals. The binding stoichiometry has been established to be one metal ion bound per subunit. Paramagnetic relaxation studies have shown that the divalent metal ion binds at the recently discovered activator site on L-aspartase and not at the enzyme active site. Enzyme activators are bound within 5 A of the enzyme-bound divalent metal ion. The activator site is remote from the active site of the enzyme, since the relaxation of inhibitors that bind at the active site is not affected by paramagnetic metal ions bound at the activator site.     

Twelve species of the nucleoid-associated protein from Escherichia coli. Sequence recognition specificity and DNA binding affinity.

The genome of Escherichia coli is composed of a single molecule of circular DNA with the length of about 47,000 kilobase pairs, which is associated with about 10 major DNA-binding proteins, altogether forming the nucleoid. We expressed and purified 12 species of the DNA-binding protein, i.e. CbpA (curved DNA-binding protein A), CbpB or Rob (curved DNA-binding protein B or right arm of the replication origin binding protein), DnaA (DNA-binding protein A), Dps (DNA-binding protein from starved cells), Fis (factor for inversion stimulation), Hfq (host factor for phage Q(beta)), H-NS (histone-like nucleoid structuring protein), HU (heat-unstable nucleoid protein), IciA (inhibitor of chromosome initiation A), IHF (integration host factor), Lrp (leucine-responsive regulatory protein), and StpA (suppressor of td(-) phenotype A). The sequence specificity of DNA binding was determined for all the purified nucleoid proteins using gel-mobility shift assays. Five proteins (CbpB, DnaA, Fis, IHF, and Lrp) were found to bind to specific DNA sequences, while the remaining seven proteins (CbpA, Dps, Hfq, H-NS, HU, IciA, and StpA) showed apparently sequence-nonspecific DNA binding activities. Four proteins, CbpA, Hfq, H-NS, and IciA, showed the binding preference for the curved DNA. From the apparent dissociation constant (K(d)) determined using the sequence-specific or nonspecific DNA probes, the order of DNA binding affinity were determined to be: HU > IHF > Lrp > CbpB(Rob) > Fis > H-NS > StpA > CbpA > IciA > Hfq/Dps, ranging from 25 nM (HU binding to the non-curved DNA) to 250 nM (Hfq binding to the non-curved DNA), under the assay conditions employed.     

Examination of polypeptide substrate specificity for Escherichia coli ClpB

Escherichia coli ClpB is a molecular chaperone that belongs to the Clp/Hsp100 family of AAA+ proteins. ClpB is able to form a hexameric ring structure to catalyze protein disaggregation with the assistance of the DnaK chaperone system. Our knowledge of the mechanism of how ClpB recognizes its substrates is still limited. In this study, we have quantitatively investigated ClpB binding to a number of unstructured polypeptides using steady‐state anisotropy titrations. To precisely determine the binding affinity for the interaction between ClpB hexamers and polypeptide substrates the titration data were subjected to global non‐linear least squares analysis incorporating the dynamic equilibrium of ClpB assembly. Our results show that ClpB hexamers bind tightly to unstructured polypeptides with binding affinities in the range of ～3–16 nM. ClpB exhibits a modest preference of binding to Peptide B1 with a binding affinity of (1.7 ± 0.2) nM. Interestingly, we found that ClpB binds to an unstructured polypeptide substrate of 40 and 50 amino acids containing the SsrA sequence at the C‐terminus with an affinity of (12 ± 3) nM and (4 ± 2) nM, respectively. Whereas, ClpB binds the 11‐amino acid SsrA sequence with an affinity of (140 ± 20) nM, which is significantly weaker than other polypeptide substrates that we tested here. We hypothesize that ClpB, like ClpA, requires substrates with a minimum length for optimal binding. Finally, we present evidence showing that multiple ClpB hexamers are involved in binding to polypeptides ≥152 amino acids. Proteins 2015; 83:117–134. © 2014 Wiley Periodicals, Inc.     

Site-specific methylases induce the SOS DNA repair response in Escherichia coli.

Expression of the site-specific adenine methylase HhaII (GmeANTC, where me is methyl) or PstI (CTGCmeAG) induced the SOS DNA repair response in Escherichia coli. In contrast, expression of methylases indigenous to E. coli either did not induce SOS (EcoRI [GAmeATTC] or induced SOS to a lesser extent (dam [GmeATC]). Recognition of adenine-methylated DNA required the product of a previously undescribed gene, which we named mrr (methylated adenine recognition and restriction). We suggest that mrr encodes an endonuclease that cleaves DNA containing N6-methyladenine and that DNA double-strand breaks induce the SOS response. Cytosine methylases foreign to E. coli (MspI [meCCGG], HaeIII [GGmeCC], BamHI [GGATmeCC], HhaI [GmeCGC], BsuRI [GGmeCC], and M.Spr) also induced SOS, whereas one indigenous to E. coli (EcoRII [CmeCA/TGG]) did not. SOS induction by cytosine methylation required the rglB locus, which encodes an endonuclease that cleaves DNA containing 5-hydroxymethyl- or 5-methylcytosine (E. A. Raleigh and G. Wilson, Proc. Natl. Acad. Sci. USA 83:9070-9074, 1986).     

Characteristics of chromosomal DNA isolated from Escherichia coli spheroplasts

The chromosomal DNA of Escherichia coli spheroplasts induced by penicillin G was studied biochemically and electron microscopically. Although the spheroplasts were unable to divide, they continued to synthesize chromosomal DNA for several hours even in the presence of penicillin G. Some differences were observed between the chromosomal DNA of the parent cells and that of the spheroplasts in sucrose gradient centrifugation and electron microscopy; two types of chromosomal DNA, a slower sedimenting form and a faster sedimenting form, were released from the gently lysed parent cells. The former was membrane-free folded chromosome and the latter was membrane-associated chromosome. In contrast, the chromosome from the spheroplast showed a single intermediate value of sedimentation coefficient between those of the chromosomal DNA from the parent cell. Cytochrome spreading for electron microscopy showed that the spheroplast chromosomal DNA formed an aggregated mass consisting of several chromosome-molecules of the parent cell.