M.(phi)BssHII, a novel cytosine-C5-DNA-methyltransferase with target-recognizing domains at separated locations of the enzyme

A GCDGC-specific DNA (cytosine-5) methyltransferase that methylates the GCWGC sequence on both strands and the GCSGC sequence on one strand

5-Methylcytosine is one of the major epigenetic marks of DNA in living organisms. Some bacterial species possess DNA methyltransferases that modify cytosines on both strands to produce fully-methylated sites or on either strand to produce hemi-methylated sites. In this study, we characterized a DNA methyltransferase that produces two sequences with different methylation patterns: one methylated on both strands and another on one strand. M.BatI is the orphan DNA methyltransferase of Bacillus anthracis coded in one of the prophages on the chromosome. Analysis of M.BatI modified DNA by bisulfite sequencing revealed that the enzyme methylates the first cytosine in sequences of 5ʹ-GCAGC-3ʹ, 5ʹ-GCTGC-3ʹ, and 5ʹ-GCGGC-3ʹ, but not of 5ʹ-GCCGC-3ʹ. This resulted in the production of fully-methylated 5ʹ-GCWGC-3ʹ and hemi-methylated 5ʹ-GCSGC-3ʹ. M.BatI also showed toxicity when expressed in E. coli, which was caused by a mechanism other than DNA modification activity. Homologs of M.BatI were found in other Bacillus species on different prophage like regions, suggesting the spread of the gene by several different phages. The discovery of the DNA methyltransferase with unique modification target specificity suggested unrevealed diversity of target sequences of bacterial cytosine DNA methyltransferase.

Biosynthesis and Function of Modified Bases in Bacteria and Their Viruses

Naturally occurring modification of the canonical A, G, C, and T bases can be found in the DNA of cellular organisms and viruses from all domains of life. Bacterial viruses (bacteriophages) are a particularly rich but still underexploited source of such modified variant nucleotides. The modifications conserve the coding and base-pairing functions of DNA, but add regulatory and protective functions. In prokaryotes, modified bases appear primarily to be part of an arms race between bacteriophages (and other genomic parasites) and their hosts, although, as in eukaryotes, some modifications have been adapted to convey epigenetic information. The first half of this review catalogs the identification and diversity of DNA modifications found in bacteria and bacteriophages. What is known about the biogenesis, context, and function of these modifications are also described. The second part of the review places these DNA modifications in the context of the arms race between bacteria and bacteriophages. It focuses particularly on the defense and counter-defense strategies that turn on direct recognition of the presence of a modified base. Where modification has been shown to affect other DNA transactions, such as expression and chromosome segregation, that is summarized, with reference to recent reviews.

Characterization of the large subunit of EcoHK31I methyltransferase by structural modeling and mutagenesis

M.EcoHK31I is a naturally occurring mC5-methyltransferase with a large alpha polypeptide and a small beta polypeptide. Polypeptide alpha contains conserved motifs I-VIII and X, and polypeptide beta contains motif IX. To understand how polypeptide alpha carries out its function, a molecular model of the large domain of polypeptide alpha was generated using M.HhaI and M.HaeIII as templates. The large domain is a mixed alpha/beta structure. Residues 15-19 in motif I (Phe-Naa-Gly-Naa) are conserved for cofactor binding. The key catalytic residue Cys-79 in motif IV is also conserved in comparison with other C-5 MTases. Comparing polypeptide alpha with M.HhaI and M.HaeIII revealed a unique region upstream of motif X. To understand the role of this region, 14 charged residues between R224 and E271 in the putative small domain were mutated. Activity assays indicated that most of these charges can be eliminated or changed conservatively. Among these charged residues, R224, E240, D245 and D251 may take part in proper interaction with DNA in the presence of polypeptide beta.

A dichotomous epigenetic mechanism governs expression of the LlaJI restriction/modification system

The LlaJI restriction/modification (R/M) system is comprised of two 5mC MTase-encoding genes, llaJIM1 and llaJIM2, and two genes required for restriction activity, llaJIR1 and llaJIR2. Here, we report the molecular mechanism by which this R/M system is transcriptionally regulated. The recognition sequence for the LlaJI MTases was deduced to be 5'GACGC'3 for M1.LlaJI and 5'GCGTC'3 for M2.LlaJI, thus together constituting an asymmetric complementary recognition site. Two recognition sequences for both LlaJI MTases are present within the LlaJI promoter region, indicative of an epigenetic role. Following in vivo analysis of expression of the LlaJI promoter, we established that both LlaJI MTases were required for complete transcriptional repression. A mutational analysis and DNA binding studies of this promoter revealed that the methylation of two specific cytosines by M2.LlaJI within this region was required to trigger the specific and high affinity binding of M1.LlaJI, which serves to regulate expression of the LlaJI operon. This regulatory system therefore represents the amalgamation of an epigenetic stimulation coupled to the formation of a MTase/repressor:promoter complex.

Allosteric activator domain of maintenance human DNA (cytosine-5) methyltransferase and its role in methylation spreading

The human maintenance DNA (cytosine-5) methyltransferase (hDNMT1) consists of a large N-terminal regulatory domain fused to a catalytic C-terminal domain by randomly repeated Gly-Lys dipeptides. Several N-terminal deletion mutants of hDNMT1 were made, purified, and tested for substrate specificity. Deletion mutants lacking 121, 501, 540, or 580 amino acids from the N-terminus still functioned as DNA methyltransferases, methylated CG sequences, and preferred hemimethylated to unmethylated DNA, as did the full-length hDNMT1. Methylated DNA stimulated methylation spreading on unmethylated CpG sequences for the full-length and the 121 amino acid deletion hDNMT1 equally well but not for the mutants lacking 501, 540, or 580 amino acids, indicating the presence of an allosteric activation determinant between amino acids 121 and 501. Peptides from the N- and C-termini bound methylated DNA independently. Point mutation analysis within the allosteric region revealed that amino acids 284-287 (KKHR) were involved in methylated DNA-mediated allosteric activation. Allosteric activation was reduced in the double point mutant enzymes D25 (K284A and K285A) and D12 (H286A and R287A). Retinoblastoma gene product (Rb), a negative regulator of DNA methylation, bound to the allosteric site of hDNMT1 and inhibited methylation, suggesting Rb may regulate methylation spreading.

Sequence permutations in the molecular evolution of DNA methyltransferases

BACKGROUND

DNA methyltransferases (MTases), unlike MTases acting on other substrates, exhibit sequence permutation. Based on the sequential order of the cofactor-binding subdomain, the catalytic subdomain, and the target recognition domain (TRD), several classes of permutants have been proposed. The majority of known DNA MTases fall into the alpha, beta, and gamma classes. There is only one member of the zeta class known and no members of the delta and epsilon classes have been identified to date. Two mechanisms of permutation have been proposed: one involving gene duplication and in-frame fusion, and the other involving inter- and intragenic shuffling of gene segments.

RESULTS

Two novel cases of sequence permutation in DNA MTases implicated in restriction-modification systems have been identified, which suggest that members of the delta and zeta classes (M.MwoI and M.TvoORF1413P, respectively) evolved from beta-class MTases. This is the first identification of the delta-class MTase and the second known zeta-class MTase (the first zeta-class member among DNA:m4C and m6A-MTases).

CONCLUSIONS

Fragmentation of a DNA MTase gene may result from attack of nucleases, for instance when the RM system invades a new cell. Its reassembly into a functional form, the order of motifs notwithstanding, may be strongly selected for, if the cognate ENase gene remains active and poses a threat to the host's chromosome. The "cut-and-paste" mechanism is proposed for beta-delta permutation, which is non-circular and involves relocation of one segment of a gene. The circular beta-zeta permutation may be explained both by gene duplication or shuffling of gene fragments. These two mechanisms are not mutually exclusive and probably both played a role in the evolution of permuted DNA MTases.

Homology modelling of the DNA 5mC methyltransferase M.BssHII. Is permutation of functional subdomains common to all subfamilies of DNA methyltransferases?

This work presents a full tertiary model of the M.BssHII methyltransferase (MTase) complexed with substrate DNA and cofactor S-adenosyl-L-methionine, built by homology modelling based on previously solved complete structures of DNA MTases M.HaeIII and M. HhaI. M.BssHII and the template proteins show high sequence similarity, which indicates that they are evolutionary related. However, they are topologically different: M.BssHII is a circularly permuted variant of template MTases (Xu et al. Nucleic Acids Res 1997;25:3991). The model developed in this work will be a good starting point and valuable help in designing mutagenesis experiments to better understand the biological function of methyltransferases and the process of domain swapping.

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.