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.

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.

Chimeric multispecific DNA methyltransferases with novel combinations of target recognition.

DNA target recognizing domains of different multispecific DNA-cytosine-methyltransferases can be rearranged through engineering of the corresponding genes to generate enzymes with novel combinations of target recognition.

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.

Restriction and modification in Bacillus subtilis: DNA methylation potential of the related bacteriophages Z, SPR, SP beta, phi 3T, and rho 11.

The DNA methylation capacity and some other properties of the related temperate Bacillus subtilis phages Z, SPR, SP beta, phi 3T, and rho 11 are compared. With phage mutants affected in their methylation potential, we show that phage-coded methyltransferase genes are interchangeable among the phages studied. DNA/DNA hybridization experiments indicate that phage methyltransferase genes are structurally related, whereas no such relationship is observed to a bacterial gene, specifying a methyltransferase with the same specificity.

Restriction and modification in Bacillus subtilis: expression of the cloned methyltransferase gene from B. subtilis phage SPR in E. coli and B. subtilis.

Expression of the SPR methyltransferase gene from B. subtilis phage SPR cloned into lambda and SPP1 was studied by analyzing the sensitivity of the hybrid phage DNAs to restriction by the enzymes HaeIII, MspI, and HpaII. The following results were obtained: (1) The genes were expressed both in the homologous (B. subtilis) and heterologous (E. coli) host. (2) The specificity of the expression of the cloned gene was identical to that of the gene in SPR. (3) Expression depended on the orientation of the cloned segment within the vector DNAs suggesting that vector promoters were involved in transcription. The coding strand of the cloned DNA was identified through hybridization with SPR mRNA.

Restriction and modification in Bacillus subtilis: gene coding for a BsuR-specific modification methyltransferase in the temperate bacteriophage phi 3T.

The resistance of Phi3T DNA to degradation by the restriction enzyme BsuR or its isoschizomer HaeIII is due to obligatory modification of such DNA. Biochemical and genetical experiments indicate that Phi3T codes for a methyltransferase, which methylates Phi3T DNA itself or heterologous DNA at target sites 5'-GG(*)CC.

Restriction and modification in Bacillus subtilis: identification of a gene in the temperate phage SP beta coding for a BsuR specific modification methyltransferase.

A gene coding for a modifying DNA-methyltransferase which methylates the central C in the BsuR recognition sequence 5'GGCC was identified in the genome of the temperature Bacillus subtilis phage SP beta. This gene is expressed only after induction of the prophage by either mitomycin C or UV. The presence of active methyltransferase in induced cells leads to modification of BsuR recognition sites in SP beta DNA as well as in heterologous DNA.

Restriction and modification in Bacillus subtilis: inducibility of a DNA methylating activity in nonmodifying cells.

The nonrestricting/nonmodifying strain Bacillus subtilis 222 (r-m-) can be induced to synthesize a DNA-modifying activity upon treatment with either mitomycin C (MC) or UV light. This is shown by the following facts. (i) Infection of MC-pretreated 222 cells with unmodified SPP1 phage yields about 3% modified phage that are resistant to restriction in B. subtilis R (r+m+). The induced modifying activity causes the production of a small fraction of fully modified phage in a minority class of MC-treated host cells. (ii) The MC-pretreated host cells contain a DNA cytosine methylating activity: both bacterial and phage DNAs have elevated levels of 5-methylcytosine. (iii) The MC-induced methylation of SPP1 DNA takes place at the recognition nucleotide sequences of restriction endonuclease R from B. subtilis R. (iv) Crude extracts of MC-pretreated 222 cells have enhanced DNA methyltransferase activities, with a substrate specificity similar to that found in modification enzymes present in (constitutively) modifying strains.