Cytosine DNA-methylase of a SsoII-type from Shigella sonnei 47 cells

Shigella sonnei 47 cells were found to contain DNA-methylase SsoII which is a modifying component of the system of host specificity of SsoII. The recognition sequence (RS) of methylase SsoII is represented by a five-member palyndromic structure--5'...CCNGG...3'--with a degenerated central nucleotide. Modification of SsoII affords protection of acceptor DNA not only from SsoII type restriction, but also from other restrictases, e. g., Eco RII having an analogous RS but with a less degenerated central nucleotide pair. A simple and rapid procedure for isolation and purification of DNA-methylase ScoII, which employs hydrophobic chromatography on phenyl-Sepharose, has been developed. The enzyme preparation does not contain trace amounts of specific and nonspecific endonucleases and keeps stable on storage in 30% glycerol over a period of one year.     

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.     

DNA duplexes containing photoactive derivatives of 2'-deoxyuridine as photocrosslinking probes for EcoRII DNA methyltransferase-substrate interaction

EcoRII DNA methyltransferase (M.EcoRII) recognizes the DNA sequence 5'.CC*T/AGG.3' and catalyzes the transfer of the methyl group from S-adenosyl-L-methionine to the C5 position of the inner cytosine residue (C*). We obtained several DNA duplexes containing photoactive 5-iodo-2'-deoxyuridine (i(5)dU) or 5-[4-(3-(trifluoromethyl)-3H-diazirin-3-yl)phenyl]-2'-deoxyuridine (Tfmdp-dU) to characterize regions of M.EcoRII involved in DNA binding and to investigate the DNA double helix conformational changes that take place during methylation. The efficiencies of methylation, DNA binding affinities and M.EcoRII-DNA photocrosslinking yields strongly depend on the type of modification and its location within the EcoRII recognition site. The data obtained agree with the flipping of the target cytosine out of the DNA double helix for catalysis. To probe regions of M.EcoRII involved in DNA binding, covalent conjugates M.EcoRII-DNA were cleaved by cyanogen bromide followed by analysis of the oligonucleotide-peptides obtained. DNA duplexes containing i(5)dU or Tfmdp-dU at the central position of the recognition site, or instead of the target cytosine were crosslinked to the Gly(268)-Met(391) region of the EcoRII methylase. Amino acid residues from this region may take part both in substrate recognition and stabilization of the extrahelical target cytosine residue.     

Isolation and Characterization of Site-Specific DNA-methyltransferases from Bacillus coagulans K

Two site-specific DNA methyltransferases, M.BcoKIA and M.BcoKIB, were isolated from the thermophilic strain Bacillus coagulans K. Each of the methylases protects the recognition site 5'-CTCTTC-3'/5'-GAAGAG-3' from cleavage with the cognate restriction endonuclease BcoKI. It is shown that M.BcoKIB is an N6-adenine specific methylase and M.BcoKIA is an N4-cytosine specific methylase. According to bisulfite mapping, M.BcoKIA methylates the first cytosine in the sequence 5'-CTCTTC-3'.     

On the nature of the cytosine-methylated sequence in DNA of Bacillus brevis var. G.-B.

On growing the cells of Bacillus brevis S methionine-auxotroph mutant in the presence of [Me-3H]methionine, practically all the radioactivity incorporated into DNA is found to exist in 5-methylcytosine and N6-methyladenine. The analysis of pyrimidine isopliths isolated from DNA shows that radioactivity only exists in mono- and dinucleotides and the content of 5-methylcytosine in R-m5 C-R and R-m5 C-T-R oligonucleotides is equal. The analysis of dinucleotides isolated from DNA by means of pancreatic DNAase hydrolysis allows the nature of purine residues neighbouring 5-methylcytosine to be identified and shows that 5-methylcytosine localizes in G-m5 C-A and G-m5 C-Tr fragments. B. brevis S DNA methylase modifying cytosine residues recognizes the GCA/TGC degenerate nucleotide sequence which is a part of the following complementary structure with a two-fold rotational axis of symmetry: (5')...N'-G-C-T-G-C-N... (3') (3')...N-C-G-A-C-G-N'... (5') (Methylated cytosine residues are askerisked). Cytosine-modifying DNA methylase activity is isolated from B. brevis cells; it is capable of methylating in vitro homologous and heterologous DNA. Hence DNA in bacterial cells can be undermethylated. This enzyme methylates cytosine residues in native and denatured DNA in the same nucleotide sequences. Specificity of methylation of cytosine residues in vitro and in vivo does not depend on the nature of substrate DNA. DNA methylases of different variants of B. brevis (R, S, P+, P-)) methylate cytosine residues in the same nucleotide sequences. It means that specificity or methylation of DNA cytosine residues in the cells of different variants of B. brevis is the same.     

How M.MspI and M.HpaII decide which base to methylate.

The HpaII methylase (M.HpaII) recognizes the sequence CCGG and methylates the inner cytosine residue. The MspI methylase (MspI) recognizes the same sequence but methylates the outer cytosine residue. Both methylases have the usual architecture of 10 well-conserved motifs surrounding a variable region, responsible for sequence specific recognition, that is quite different in the two methylases. We have constructed hybrids between these two methylases and studied their methylation properties. A hybrid containing the variable region and C-terminal sequences from M.MspI methylates the outer cytosine residue. A second hybrid identical to the first except that the variable region derives from the M.HpaII methylates the inner cytosine residue. Thus the choice of base to be methylated within the recognition sequence is determined by the variable region.     

Site-specificity of DNA methylases from Shigella sonnei 47 cells

A complex approach involving isoplith analysis, enzymatic treatment of methylated isopliths and a computer analysis of experimental data has been used for determining site specificity of six methylases from Shigella sonnei 47 cells termed according to their specificity for a nitrous base and pI as MC4.2, MC5.3, MC6.2, MC7.4, MC8.4 and MA9.5. It has been found that the recognition site of MA9.5 is a palyndrome six-member structure of the 5'...GAATTC...3' type and that this enzyme is an isometimer with respect to MEcoRI. It has been demonstrated for the first time for methylases that the recognition site of MC4.2 is represented by a non-symmetrical four-member sequence, 5'...NCCCCN...3' characterized by unique blocking of cytosines. MC8.4 possesses a broad specificity of substrate recognition and methylates the cytosine residue within the composition of the non-symmetrical unique sequence 5'...N (C/Pu) CCN...3', whose 5'-terminal base is depleted in three nucleotides. MC5.3 methylates the 3'-terminal cytosine residue within the composition of the pentanucleotide palindrome recognition site, 5'...CCNGG...3'. MC6.2 and MC7.4 possess identical pentanucleotide recognition sites of 5'...(Py)CNG(Pu)...3', but are distinguished in pI. The latter finding has been shown for the first time for different methylases within one strain.     

Characterization of restriction-modification enzymes Cfr13 I from Citrobacter freundii RFL13

This communicatiopn describes some properties of RCfr13 I and MCfr13 I, isolated from Citrobacter freundii RFL13. RCFfr13 I restriction enzyme recognizes the 5'-G GNCC sequence and cleaves, as indicated by the arrow. MCfr13 I methylase modifies the internal cytosine producing m5C (5'-GGNm5CC). RCfr13 I is sensitive not only to this type of substrate modification but also to hemimethylation in overlapping sites by MCfr10 I (internal cytosine of RCfr13 I recognition is methylated) and MHpa II (external cytosine is methylated). From these results the sensitivity of RCfr13 I to methylation by dcm methylase of E.coli in overlapping sites is deduced.     

Determination of the adenine-specific methylase recognition site of Shigella sonnei 47, using hydrazinolysis with subsequent separation of purine oligonucleotides by thin layer chromatography on DEAE- cellulose

A procedure for separation of oligopurine blocks of different length and composition by two-dimensional thin layer chromatography on DEAE-cellulose plates has been developed. This method allows a comparative analysis of the purine isostich content in the DNAs of various origin. In case of methylated DNA, the method permits to compare the substrate specificity of different enzymes responsible for the adenine residue methylation in the DNA. In combination with enzymatic treatment of labeled methylated isostichs, the method described can be used for the deciphering of the methylated sequences as well as for constructing, in a number of cases, the recognition site of adenine-specific methylases. Thus, it was demonstrated that methylase SsoI recognizes the 5...G-A-A-T-T-C ... 3' sequence and methylates its adenine residue nearest to the 5'-end.     

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.     

Macroevolution by transposition: drastic modification of DNA recognition by a type I restriction enzyme following Tn5 transposition.

We have characterized a novel mutant of EcoDXXI, a type IC DNA restriction and modification (R-M) system, in which the specificity has been altered due to a Tn5 insertion into the middle of hsdS, the gene which encodes the polypeptide that confers DNA sequence specificity to both the restriction and the modification reactions. Like other type I enzymes, the wild type EcoDXXI recognizes a sequence composed of two asymmetrical half sites separated by a spacer region: TCA(N7)RTTC. Purification of the EcoDXXI mutant methylase and subsequent in vitro DNA methylation assays identified the mutant recognition sequence as an interrupted palindrome, TCA(N8)TGA, in which the 5' half site of the wild type site is repeated in inverse orientation. The additional base pair in the non-specific spacer of the mutant recognition sequence maintains the proper spacing between the two methylatable adenine groups. Sequencing of both the wild type and mutant EcoDXXI hsdS genes showed that the Tn5 insertion occurred at nucleotide 673 of the 1221 bp gene. This effectively deletes the entire carboxyl-terminal DNA binding domain which recognizes the 3' half of the EcoDXXI binding site. The truncated hsdS gene still encodes both the amino-terminal DNA binding domain and the conserved repeated sequence that defines the length of the recognition site spacer region. We propose that the EcoDXXI mutant methylase utilizes two truncated hsdS subunits to recognize its binding site. The implications of this finding in terms of subunit interactions and the malleability of the type I R-M systems will be discussed.     

Cloning and characterization of the genes encoding the MspI restriction modification system.

The genes encoding the MspI restriction modification system, which recognizes the sequence 5' CCGG, have been cloned into pUC9. Selection was based on expression of the cloned methylase gene which renders plasmid DNA insensitive to MspI cleavage in vitro. Initially, an insert of 15 kb was obtained which, upon subcloning, yielded a 3 kb EcoRI to HindIII insert, carrying the genes for both the methylase and the restriction enzyme. This insert has been sequenced. Based upon the sequence, together with appropriate subclones, it is shown that the two genes are transcribed divergently with the methylase gene encoding a polypeptide of 418 amino acids, while the restriction enzyme is composed of 262 amino acids. Comparison of the sequence of the MspI methylase with other cytosine methylases shows a striking degree of similarity. Especially noteworthy is the high degree of similarity with the HhaI and EcoRII methylases.     

Cloning and characterization of the dcm locus of Escherichia coli K-12.

The dcm locus of Escherichia coli K-12 has been shown to code for a methylase that methylates the second cytosine within the sequence 5'-CC(A/T)GG-3'. This sequence is also recognized by the EcoRII restriction-modification system coded by the E. coli plasmid N3. The methylase within the EcoRII system methylates the same cytosine as the dcm protein. We have isolated, from a library of E. coli K-12 DNA, two overlapping clones that carry the dcm locus. We show that the two clones carry overlapping sequences that are present in a dcm+ strain, but are absent in a delta dcm strain. We also show that the cloned gene codes for a methylase, that it complements mutations in the EcoRII methylase, and that it protects EcoRII recognition sites from cleavage by the EcoRII endonuclease. We found no phage restriction activity associated with the dcm clones.     

Sequence specificity of DNA adenine methylase in the protozoan Tetrahymena thermophila.

The sequence specificity of the Tetrahymena DNA-adenine methylase was determined by nearest-neighbor analyses of in vivo and in vitro methylated DNA. In vivo all four common bases were found to the 5' side of N6-methyladenine, but only thymidine was 3'. Homologous DNA already methylated in vivo and heterologous Micrococcus luteus DNA were methylated in vitro by a partially purified DNA-adenine methylase activity isolated from Tetrahymena macronuclei. The in vitro-methylated sequence differed from the in vivo sequence in that both thymidine and cytosine were 3' nearest neighbors of N6-methyladenine.     

Cloning, expression, and purification of a thermostable nonhomodimeric restriction enzyme, BslI

BslI is a thermostable type II restriction endonuclease with interrupted recognition sequence CCNNNNN/NNGG (/, cleavage position). The BslI restriction-modification system from Bacillus species was cloned and expressed in Escherichia coli. The system is encoded by three genes: the 2,739-bp BslI methylase gene (bslIM), the bslIRalpha gene, and the bslIRbeta gene. The alpha and beta subunits of BslI can be expressed independently in E. coli in the absence of BslI methylase (M.BslI) protection. BslI endonuclease activity can be reconstituted in vitro by mixing the two subunits together. Gel filtration chromatography and native polyacrylamide gel electrophoresis indicated that BslI forms heterodimers (alphabeta), heterotetramers (alpha(2)beta(2)), and possibly oligomers in solution. Two beta subunits can be cross-linked by a chemical cross-linking agent, indicating formation of heterotetramer BslI complex (alpha(2)beta(2)). In DNA mobility shift assays, neither subunit alone can bind DNA. DNA mobility shift activity was detected after mixing the two subunits together. Because of the symmetric recognition sequence of the BslI endonuclease, we propose that its active form is alpha(2)beta(2). M.BslI contains nine conserved motifs of N-4 cytosine DNA methylases within the beta group of aminomethyltransferase. Synthetic duplex deoxyoligonucleotides containing cytosine hemimethylated or fully methylated at N-4 in BslI sites in the first or second cytosine are resistant to BslI digestion. C-5 methylation of the second cytosine on both strands within the recognition sequence also renders the site refractory to BslI digestion. Two putative zinc fingers are found in the alpha subunit of BslI endonuclease.     

In vitro methylation of DNA with Hpa II methylase.

The enzyme Hpa II methylase extracted and partially purified from Haemophilus parainfluenza catalyzes the methylation of the tetranucleotide sequence CCGG at the internal cytosine. The enzyme will methylate this sequence if both DNA strands are unmethylated or if only one strand is unmethylated. Conditions have been developed for producing fully methylated DNA from various sources. In vitro methylation of this site protects the DNA against digestion by the restriction enzyme Hpa II as well as the enzyme Sma I which recognizes the hexanucleotide sequence CCCGGG. These properties make this enzyme a valuable tool for analyzing methylation in eukaryotic DNA where the sequence CCGG is highly methylated. The activity of this methylase on such DNA indicates the degree of undermethylation of the CCGG sequence. Several examples show that this technique can be used to detect small changes in the methylation state of eukaryotic DNA.     

The effects of DNA methylation by Hha I methylase on the cleavage reactions by Hae II, Aha II and Ban I endonucleases

The DNA methylated by Hha I methylase was resistant against cleavage of Hae II or Aha II endonuclease indicating that the methyl group of the C5 position of the inmost cytosine nucleotide interferes with the interaction between the enzyme and the hexameric recognition sequence. Considering that Hae II or Aha II methylase has not been isolated yet, the result explained above is a useful information for protecting a double stranded DNA from being cleaved by Hae II or Aha II endonuclease. In contrast to Hae II or Aha II endonuclease, Ban I endonuclease which also has Hha I sequence as its tetrameric core was able to cleave the same DNA normally. This result suggests that the C5 position of the inmost pyrimidine nucleotide is not an important contact point between Ban I endonuclease and its hexameric recognition sequence.     

2-Pyrimidinone as a probe for studying the EcoRII DNA methyltransferase-substrate interaction.

EcoRII DNA methyltransferase (M.EcoRII) recognizes the 5' em leader CC*T/AGG em leader 3' DNA sequence and catalyzes the transfer of the methyl group from S-adenosyl-l-methionine to the C5 position of the inner cytosine residue (C*). Here, we study the mechanism of inhibition of M.EcoRII by DNA containing 2-pyrimidinone, a cytosine analogue lacking an NH(2) group at the C4 position of the pyrimidine ring. Also, DNA containing 2-pyrimidinone was used for probing contacts of M.EcoRII with functional groups of pyrimidine bases of the recognition sequence. 2-Pyrimidinone was incorporated into the 5' em leader CCT/AGG em leader 3' sequence replacing the target and nontarget cytosine and central thymine residues. Study of the DNA stability using thermal denaturation of 2-pyrimidinone containing duplexes pointed to the influence of the bases adjacent to 2-pyrimidinone and to a greater destabilizing influence of 2-pyrimidinone substitution for thymine than that for cytosine. Binding of M.EcoRII to 2-pyrimidinone containing DNA and methylation of these DNA demonstrate that the amino group of the outer cytosine in the EcoRII recognition sequence is not involved in the DNA-M.EcoRII interaction. It is probable that there are contacts between the functional groups of the central thymine exposed in the major groove and M.EcoRII. 2-Pyrimidinone replacing the target cytosine in the EcoRII recognition sequence forms covalent adducts with M.EcoRII. In the absence of the cofactor S-adenosyl-l-methionine, proton transfer to the C5 position of 2-pyrimidinone occurs and in the presence of S-adenosyl-l-methionine, methyl transfer to the C5 position of 2-pyrimidinone occurs.     

Isolation and Characterization of Biochemical Properties of DNA Methyltransferase <Emphasis Type="Italic">Fau</Emphasis>IA Modifying the Second Cytosine in the Nonpalindromic Sequence 5′-CCCGC-3′

A gene encoding DNA methyltransferase (methylase) FauIA of the restriction-modification system FauI from Flavobacterium aquatile (recognizing sequence 5'-CCCGC-3') was cloned in pJW vector. The latter was used for transformation of E. coli RRI cells followed by subsequent thermoinduction and biomass elaboration. Highly purified DNA methyltransferase FauIA preparation was obtained using chromatography on different sorbents. The molecular mass of the isolated enzyme of about 39 kD corresponds to its theoretical value. The enzyme was characterized by temperature and pH optima of 33 degrees C and pH 7.5, respectively. Methylation of a synthetic oligonucleotide by FauIA methylase followed by its cleavage with various restrictases and analysis of the resultant restriction fragments revealed that FauIA methylase modified the second cytosine residue in the sequence 5'-CCCGC-3'. Kinetic analysis revealed Km and catalytic constant values of 0.16 microM and 0.05 min(-1), respectively.     

Two restriction endonucleases from Bacillus globiggi.

The sites of action of the restriction enzyme Bgl II on lambda DNA are mapped. This enzyme recognises the sequence 5' ...AGATCT...3' and makes staggered cuts producing sticky ends. In lambda DNA, the second A in this sequence is methylated about 50% of the time by a bacterial methylase absent in E. coli dam. In contrast to Bgl II, Bgl I makes many cuts in lambda DNA and produces 5' terminals which are not substrates for polynucleotide kinase.