Bacillus subtilis phage SPR codes for a DNA methyltransferase with triple sequence specificity.

SPR, a temperate Bacillus subtilis phage, codes for a DNA methyltransferase that can methylate the sequences GGCC (or GGCC) and CCGG at the cytosines indicated. We show here that it can also methylate the sequence CC(A/T)GG and protect it from cleavage with EcoRII and ApyI. This methylation can be seen in vivo as well as in vitro with purified SPR methyltransferase. SPR19 and SPR83 are two mutant phages, defective in GGCC or CCGG methylation, respectively. These mutants have not lost their ability to methylate CC(A/T)GG sites. Mutation SPR26 has lost the ability to methylate all three sites. Thus the SPR methyltransferase codes for three genetically distinguishable methylation abilities.     

Sequential order of target-recognizing domains in multispecific DNA-methyltransferases.

In the multispecific DNA(cytosine-5)-methyltransferases (Mtases) of Bacillus subtilis phages SPR and phi 3T the domains responsible for recognition of DNA methylation targets CCA/TGG, CCGG, GGCC (SPR) and GCNGC, GGCC (phi 3T) represent contiguous sequences of approximately 50 amino acids each. These domains are tandemly arranged and do not overlap. They are part of a 'variable' segment within the enzymes which is flanked by 'conserved' amino acids, which are very similar amongst bacterial monospecific and the multispecific Mtases studied here. These results follow from a mutational analysis of the SPR and phi 3T Mtase genes. They further support our concept of a modular enzyme organization, according to which variability of type II Mtases with respect to target recognition is achieved by a combination of the same enzyme core with a variety of target-recognizing domains.     

Exact size and organization of DNA target-recognizing domains of multispecific DNA-(cytosine-C5)-methyltransferases.

A large portion of the sequences of type II DNA-(cytosine-C5)-methyltransferases (C5-MTases) represent highly conserved blocks of amino acids. General steps in the methylation reaction performed by C5-MTases have been found to be mediated by some of these domains. C5-MTases carry, in addition at the same relative location, a region variable in size and amino acid composition, part of which is associated with the capacity of each C5-MTase to recognize its characteristic target. Individual target-recognizing domains (TRDs) for the targets CCGG (M), CC(A/T)GG (E), GGCC (H), GCNGC (F) and G(G/A/T)GC(C/A/T)C (B) could be identified in the C-terminal part of the variable region of multispecific C5-MTases. With experiments reported here, we have established the organization of the variable regions of the multispecific MTases M.SPRI, M.phi3TI, M.H2I and M.rho 11SI at the resolution of individual amino acids. These regions comprise 204, 175, 268 and 268 amino acids, respectively. All variable regions are bipartite. They contain at their N-terminal side a very similar sequence of 71 amino acids. The integrity of this sequence must be assured to provide enzyme activity. Bracketed by 6-10 'linker' amino acids, they have, depending on the enzyme studied, towards their C-terminal end ensembles of individual TRDs of 38 (M), 39 (E), 40 (H), 44 (F) and 54 (B) amino acids. TRDs of different enzymes with equal specificity have the same size. TRDs do not overlap but are either separated by linker amino acids or abut each other.     

Multispecific DNA methyltransferases from Bacillus subtilis phages. Properties of wild-type and various mutant enzymes with altered DNA affinity

Temperate Bacillus subtilis phages SPR, phi 3T, rho 11 and SP beta code for DNA methyltransferases, each having multiple sequence specificities. The SPR wild-type and various mutant methyltransferases were overproduced 1000-fold in Escherichia coli and were purified by three consecutive chromatographic steps. The stable form of these multispecific enzymes in solution are monomers with a relative molecular mass (Mr) of about 50,000. The methyl-transfer kinetics of the SPR wild-type and mutant enzymes were determined with DNA substrates carrying either none or one of the three recognition sequences (GGCC, CCGG, CCATGG). Evaluation of the catalytic properties for DNA and S-adenosylmethionine binding suggested that the NH2-terminal part of the protein is important for both non-sequence-specific DNA binding and S-adenosylmethionine binding as well as transfer of methyl groups. On the other hand, mutations in the COOH-terminal part lead to weaker site-specific interactions of the enzyme. Antibodies raised against the purified SPR enzyme specifically immunoprecipitated the phi 3T, rho 11 and SP beta methyltransferases, bu failed to precipitate the chromosomally coded enzymes from B. subtilis (BsuRI) and B. sphaericus (BspRI). Immunoaffinity chromatography is an efficient purification step for the related phage methyltransferases.     

Organization of multispecific DNA methyltransferases encoded by temperate Bacillus subtilis phages.

B. subtilis phage rho 11s codes for a multispecific DNA methyltransferase (Mtase) which methylates cytosine within the sequences GGCC and GAGCTC. The Mtase gene of rho 11s was isolated and sequenced. It has 1509 bp, corresponding to 503 amino acids (aa). The enzyme's Mr of 57.2 kd predicted from the nucleotide sequence was verified by direct Mr determinations of the Mtase. A comparison of the aa sequence of the rho 11s Mtase with those of related phages SPR and phi 3%, which differ in their methylation potential, revealed generalities in the building plan of such enzymes. At least 70% of the aa of each enzyme are contained in two regions of 243 and 109 aa at the N and C termini respectively, which are highly conserved among the three enzymes. In each enzyme, variable sequences separate the conserved regions. Variability is generated through the single or multiple use of related and unrelated sequence motifs. We propose that the recognition of those DNA target sequences, which are unique for each of the three enzymes, is determined by these variable regions. Evolutionary relationships between the three enzymes are discussed.     

The amino acid sequence of the CCGG recognizing DNA methyltransferase M.BsuFI: implications for the analysis of sequence recognition by cytosine DNA methyltransferases.

The Bacillus subtilis FI DNA methyltransferase (M.BsuFI) modifies the outer cytosine of the DNA sequence CCGG, causing resistance against R.BsuFI and R.MspI restriction. The M.BsuFI gene was cloned and expressed in B.subtilis and Escherichia coli. As derived from the nucleotide sequence, the M.BsuFI protein has 409 amino acids, corresponding to a molecular mass of 46,918 daltons. Including these data we have compared the nucleotide and amino acid sequences of different CCGG recognizing enzymes. These analyses showed that M.BsuFI is highly related to two other CCGG specific methyltransferases, M.MspI and M.HpaII, which were isolated from Gram-negative bacteria. Between M.BsuFI and M.MspI the sequence similarity is particularly significant in a region, which has been postulated to contain the target recognition domains (TRDs) of cytosine-specific DNA methyltransferases. Apparently M.BsuFI and M.MspI, derived from phylogenetic distant organisms, use highly conserved structural elements for the recognition of the CCGG target sequence. In contrast the very same region of M.HpaII is quite different from those of M.BsuFI and M.MspI. We attribute this difference to the different targeting of methylation within the sequence CCGG, where M.HpaII methylates the inner, M.BsuFI/M.MspI the outer cytosine. Also the CCGG recognizing TRD of the multispecific B.subtilis phage SPR Mtase is distinct from that of the host enzyme, possibly indicating different requirements for TRDs operative in mono- and multispecific enzymes.     

Restriction and modification in Bacillus subtilis: nucleotide sequence, functional organization and product of the DNA methyltransferase gene of bacteriophage SPR

Bacillus subtilis phage SPR codes for a DNA methyltransferase (Mtase) which methylates the 5' cytosine in the sequence GGCC and both cytosines in the sequence CCGG. A 2126-bp fragment of SPR DNA containing the Mtase gene has been sequenced. This fragment has only one significant open reading frame of 1347 bp, which corresponds to the Mtase gene. Within the sequence the Mtase promoter has been defined by S1 mapping. The size of the SPR Mtase predicted from the deduced amino acid composition is 49.9 kDal. This is in agreement with both the Mr of the purified enzyme and with that of the SPR Mtase gene product identified here by minicell technique. Base changes leading to mutants affected in Mtase activity were localized within the Mtase gene.     

The sequence specificity of endonucleases CauI and CauII isolated from chloroflexus aurantiacus

The type II restriction enzymes CauI and CauII, isolated from Chloroflexus aurantiacus, recognize and cleave (at the position indicated by an arrow) the sequences G decreases G A/T CC and CC decreases G/C GG, respectively. These conclusions are supported by the results from restriction site mapping, sequence analysis by partial chemical degradation, end-group analysis after lambda exonuclease treatment and computer-assisted comparison of DNA sequence data.     

DsaV methyltransferase and its isoschizomers contain a conserved segment that is similar to the segment in Hhai methyltransferase that is in contact with DNA bases.

The methyltransferase (MTase) in the DsaV restriction--modification system methylates within 5'-CCNGG sequences. We have cloned the gene for this MTase and determined its sequence. The predicted sequence of the MTase protein contains sequence motifs conserved among all cytosine-5 MTases and is most similar to other MTases that methylate CCNGG sequences, namely M.ScrFI and M.SsoII. All three MTases methylate the internal cytosine within their recognition sequence. The 'variable' region within the three enzymes that methylate CCNGG can be aligned with the sequences of two enzymes that methylate CCWGG sequences. Remarkably, two segments within this region contain significant similarity with the region of M.HhaI that is known to contact DNA bases. These alignments suggest that many cytosine-5 MTases are likely to interact with DNA using a similar structural framework.     

Different methylation pattern of melon satellite DNA sequences in hypocotyl and callus tissues

Satellite DNA sequences from Cucumis melo have been examined with respect to modification at CCGG sequences in hypocotyls and in callus tissues. For this purpose, restriction fragments given by HpaII and MspI were compared (both enzymes recognize CCGG sequences but have different sensitivity to methylation at this site). Whereas the methylation level of satellite DNA sequences is on average higher in hypocotyls than in callus tissues, the comparison of partially methylated repeat units of satellite DNA reveals that in callus tissues, all methylated restriction sites are doubly methylated.     

Methylation of mitochondrial DNA in carrot (Daucus carota L.)

The methylation status of carrot (Daucus carota L.) mitochondrial DNA (mtDNA) was studied using isoschizomeric restriction enzymes MspI/HpaII (CCGG) and MvaI/EcoRII [CC(A/T)GG]. Southern hybridisations with probes for mitochondrial genes coxII and atpA were performed. MtDNAs isolated from non-embryogenic cell suspensions and roots were analysed. No differences were found using MspI/HpaII but after digesting the mtDNA with MvaI and EcoRII, some qualitative and quantitative differences between the restriction patterns appeared. Distinction was also revealed after Southern hybridisation with the coxII probe. These data indicate that the mtDNA of carrot is methylated in CNG trinucleotides and unmethylated in CG dinucleotides in CCGG sequences. The results were reproducible for cell suspensions of various genotypes and even cultivars but the extent of methylation was different in the root. The possible role of methylation in the mitochondrial genome of higher plants is discussed. Received: 16 April 1997 / Revision received: 4 July 1997 / Accepted: 30 July 1997     

Presence of 5-methylcytosine in CC(A/T)GG sequences (Dcm methylation) in DNAs from different bacteria.

The presence of CC(A/T)GG sequences with methylated internal cytosine (Dcm methylation) was determined in DNA from different genera of eubacteria. This methylation was studied by using restriction enzymes EcoRII and BstNI, which cleave unmethylated or methylated CC(A/T)GG sequences. Dcm methylation was only detected in genera of the family Enterobacteriaceae closely related to Escherichia: Shigella, Citrobacter, Salmonella, and Klebsiella.     

Sequence specificity in spermine-induced structural changes in CG-oligomers

The role of spermine in inducing A-DNA conformation in deoxyoligonucleotides has been studied using CCGG and GGCC as model sequences. It has been found that while CCGG adopts an alternating B-DNA conformation in low salt solution at low temperature, addition of spermine to this medium induces a B --greater than A transition. In contrast, the A-DNA-like structure of GGCC in low salt solution at low temperature does not change under the influence of spermine. This suggests a sequence-dependent behaviour of spermine. Further these results suggest that the A-DNA conformation observed in the crystals of d(iCCGG) and d(GGCC)2 might have been due to the presence of spermine in the crystallization cocktail.     

Specifically unmethylated cytidylic-guanylate sites in Herpesvirus saimiri DNA in tumor cells.

The restriction endonucleases MspI (CCGG), HpaII (CCGG), FnuDII (CGCG), and HaeIII (GGCC) were used to study the methylation of Herpesvirus saimiri DNA in tumor cells taken directly from tumor-bearing animals. No evidence was found for methylation of the 5' terminal C in the sequence CCGG or of the internal C in the sequence GGCC, but extensive methylation of CG was detected. Fifteen HpaII sites and 17 FnuDII sites were detected in the unique DNA region of the H. saimiri strain used. Twenty-eight of the 32 sites were methylated in greater than 90% of the viral DNA molecules in tumor cells, but the remaining 4 sites were unmethylated in greater than 95% of the viral DNA molecules in tumor cells. The locations of the four specifically unmethylated sites were mapped and appeared to be identical in the four different induced leukemias examined (one owl monkey and three white-lipped marmosets). The nonproducer 1670 tumor cell line, in continuous passage for over 7 years, contained four similar specifically unmethylated sites. Possibilities for the physiological significance of the unmethylated sites are discussed.     

DNA binding and cleavage selectivity of the Escherichia coli DNA G:T-mismatch endonuclease (vsr protein).

The Escherichia coli vsr endonuclease recognises T:G base-pair mismatches in double-stranded DNA and initiates a repair pathway by hydrolysing the phosphate group 5' to the incorrectly paired T. The gene encoding the vsr endonuclease is next to the gene specifying the E. coli dcm DNA-methyltransferase; an enzyme that adds CH3 groups to the first dC within its target sequence CC[A/T]GG, giving C5MeC[A/T]GG. Deamination of the d5MeC results in CT[A/T]GG in which the first T is mis-paired with dG and it is believed that the endonuclease preferentially recognises T:G mismatches within the dcm recognition site. Here, the preference of the vsr endonuclease for bases surrounding the T:G mismatch has been evaluated. Determination of specificity constant (kst/KD; kst = rate constant for single turnover, KD = equilibrium dissociation constant) confirms vsr's preference for a T:G mismatch within a dcm sequence i.e. CT[A/T]GG (the underlined T being mis-paired with dG) is the best substrate. However, the enzyme is capable of binding and hydrolysing sequences that differ from the dcm target site by a single base-pair (dcm star sites). Individual alteration of any of the four bases surrounding the mismatched T gives a substrate, albeit with reduced binding affinity and slowed turnover rates. The vsr endonuclease has a much lower selectivity for the dcm sequence than type II restriction endonucleases have for their target sites. The results are discussed in the light of the known crystal structure of the vsr protein and its possible physiological role.     

In vivo DNA protection by relaxed-specificity SinI DNA methyltransferase variants

The SinI DNA methyltransferase, a component of the SinI restriction-modification system, recognizes the sequence GG(A/T)CC and methylates the inner cytosine to produce 5-methylcytosine. Previously isolated relaxed-specificity mutants of the enzyme also methylate, at a lower rate, GG(G/C)CC sites. In this work we tested the capacity of the mutant enzymes to function in vivo as the counterpart of a restriction endonuclease, which can cleave either site. The viability of Escherichia coli cells carrying recombinant plasmids with the mutant methyltransferase genes and expressing the GGNCC-specific Sau96I restriction endonuclease from a compatible plasmid was investigated. The sau96IR gene on the latter plasmid was transcribed from the araBAD promoter, allowing tightly controlled expression of the endonuclease. In the presence of low concentrations of the inducer arabinose, cells synthesizing the N172S or the V173L mutant enzyme displayed increased plating efficiency relative to cells producing the wild-type methyltransferase, indicating enhanced protection of the cell DNA against the Sau96I endonuclease. Nevertheless, this protection was not sufficient to support long-term survival in the presence of the inducer, which is consistent with incomplete methylation of GG(G/C)CC sites in plasmid DNA purified from the N172S and V173L mutants. Elevated DNA ligase activity was shown to further increase viability of cells producing the V173L variant and Sau96I endonuclease.     

Cloning and expression of Bacillus subtilis phage DNA methyltransferase genes in Escherichia coli and B. subtilis

The DNA methyltransferase (Mtase) genes of the temperate Bacillus subtilis phages SPR (wild type and various mutants), phi 3T, rho 11 and SP beta have been cloned and expressed in Escherichia coli and B. subtilis host-plasmid vector systems. Mtase activity has been quantitated in these clones by performing in vitro methylation assays of cell-free extracts. The four-phage Mtase genes differ in the amount of Mtase synthesized when transcribed from their genuine promoters. In B. subtilis as well as in E. coli the SPR Mtase is always produced in smaller amounts than the other phage Mtases. Expression levels of the SPR Mtase are dependent on the strength of the upstream vector promoter sequences. Overproduction of the SPR wild-type and mutant enzymes was achieved in E. coli (inducible expression) by fusions to the lambda pL or the tac promoter and in B. subtilis (constitutive expression) by means of the phage SP02 promoter.     

Characterization of type II and III restriction-modification systems from Bacillus cereus strains ATCC 10987 and ATCC 14579

The genomes of two Bacillus cereus strains (ATCC 10987 and ATCC 14579) have been sequenced. Here, we report the specificities of type II/III restriction (R) and modification (M) enzymes. Found in the ATCC 10987 strain, BceSI is a restriction endonuclease (REase) with the recognition and cut site CGAAG 24-25/27-28. BceSII is an isoschizomer of AvaII (G/GWCC). BceSIII cleaves at ACGGC 12/14. The BceSIII C terminus resembles the catalytic domains of AlwI, MlyI, and Nt.BstNBI. BceSIV is composed of two subunits and cleaves on both sides of GCWGC. BceSIV activity is strongly stimulated by the addition of cofactor ATP or GTP. The large subunit (R1) of BceSIV contains conserved motifs of NTPases and DNA helicases. The R1 subunit has no endonuclease activity by itself; it strongly stimulates REase activity when in complex with the R2 subunit. BceSIV was demonstrated to hydrolyze GTP and ATP in vitro. BceSIV is similar to CglI (GCSGC), and homologs of R1 are found in 11 sequenced bacterial genomes, where they are paired with specificity subunits. In addition, homologs of the BceSIV R1-R2 fusion are found in many sequenced microbial genomes. An orphan methylase, M.BceSV, was found to modify GCNGC, GGCC, CCGG, GGNNCC, and GCGC sites. A ParB-methylase fusion protein appears to nick DNA nonspecifically. The ATCC 14579 genome encodes an active enzyme Bce14579I (GCWGC). BceSIV and Bce14579I belong to the phospholipase D (PLD) family of endonucleases that are widely distributed among Bacteria and Archaea. A survey of type II and III restriction-modification (R-M) system genes is presented from sequenced B. cereus, Bacillus anthracis, and Bacillus thuringiensis strains.     

Ras (CXXX) and Rab (CC/CXC) prenylation signal sequences are unique and functionally distinct.

Rab proteins typically lack the consensus carboxyl-terminal CXXX motif that signals isoprenoid modification of Ras and other isoprenylated proteins and, instead, terminate in either CC or CXC sequences (C = cysteine, X = any amino acid). To compare the functional relationship between the Ras CXXX and the Rab CC/CXC motifs, we have generated chimeric Ras proteins terminating in Rab carboxyl-terminal CC or CXC sequences. These mutant Ras proteins were not isoprenylated in vitro or in vivo, demonstrating that the CC and CXC sequences alone are not sufficient to replace a CXXX sequence to signal Ras isoprenoid modification. Surprisingly, chimeric Ras/Rab proteins terminating in significant lengths of carboxyl-terminal sequences from Rab1b (7-139 residues), Rab2 (5-151 residues), or Rab3a (12 residues) were also not isoprenylated. These results demonstrate that the sequence requirements for isoprenoid modification of Rab proteins are more complex than the simple tetrapeptide CXXX sequence for isoprenoid modification of Ras proteins and suggest that the Rab geranylgeranyl transferase(s) requires recognition of protein conformation to signal the addition of geranylgeranyl groups. Finally, competition studies demonstrate that a common geranylgeranyl transferase activity is responsible for the modification of Rab proteins terminating in CC or CXC motifs.