DNA binding properties in vivo and target recognition domain sequence alignment analyses of wild-type and mutant RsrI [N6-adenine] DNA methyltransferases

Beta class amino methyltransferases from bacteria to humans: evolution and structural consequences

S-adenosyl-l-methionine dependent methyltransferases catalyze methyl transfers onto a wide variety of target molecules, including DNA and RNA. We discuss a family of methyltransferases, those that act on the amino groups of adenine or cytosine in DNA, have conserved motifs in a particular order in their amino acid sequence, and are referred to as class beta MTases. Members of this class include M.EcoGII and M.EcoP15I from Escherichia coli, Caulobacter crescentus cell cycle-regulated DNA methyltransferase (CcrM), the MTA1-MTA9 complex from the ciliate Oxytricha, and the mammalian MettL3-MettL14 complex. These methyltransferases all generate N6-methyladenine in DNA, with some members having activity on single-stranded DNA as well as RNA. The beta class of methyltransferases has a unique multimeric feature, forming either homo- or hetero-dimers, allowing the enzyme to use division of labor between two subunits in terms of substrate recognition and methylation. We suggest that M.EcoGII may represent an ancestral form of these enzymes, as its activity is independent of the nucleic acid type (RNA or DNA), its strandedness (single or double), and its sequence (aside from the target adenine).

The impact of DNA methylation in Alphaproteobacteria

Alphaproteobacteria include bacteria with very different modes of life, from free-living to host-associated and pathogenic bacteria. Their genomes vary in size and organization from single circular chromosomes to multipartite genomes and are often methylated by one or more adenine or cytosine methyltransferases (MTases). These include MTases that are part of restriction/modification systems and so-called orphan MTases. The development of novel technologies accelerated the analysis of methylomes and revealed the existence of epigenetic patterns in several Alphaproteobacteria. This review describes the known functions of DNA methylation in Alphaproteobacteria and also discusses its potential drawbacks through the accidental deamination of methylated cytosines. Particular emphasis is given to the strong connection between the cell cycle-regulated orphan MTase CcrM and the complex network that controls gene expression and cell cycle progression in Alphaproteobacteria.

Structure and dynamics of H. pylori 98-10 C5-cytosine specific DNA methyltransferase in complex with S-adenosyl-l-methionine and DNA

Helicobacter pylori is a Gram-negative bacterium that inhabits the human gastrointestinal tract, and some strains of this bacterium cause gastric ulcers and cancer. DNA methyltransferases (MTases) are promising drug targets for the treatment of cancer and other diseases that are also caused by epigenetic alternations of the genome. The C5-cytosine specific DNA methyltransferase from H. pylori (M. Hpy C5mC) catalyzes the transfer of the methyl group from the cofactor S-adenosyl-l-methionine (AdoMet) to the flipped cytosine of the substrate DNA. Herein we report the sequence analyses, 3-D structure modeling and molecular dynamics simulations of M. Hpy C5mC, when complexed with AdoMet as well as DNA. We analyzed the protein-DNA interactions prominently established by the flipped cytosine and the interactions between the protein and cofactor in the active site. We propose that the contacts made by cytosine O2 with Arg155 and Arg157, and the water-mediated interactions with cytosine N3 may be essential for the activity of methyl transfer as well as the deprotonation at the C5 position in our C5mC model. Specific recognition of DNA was mediated mainly by residues from Ser221-Arg229 and Ser243-Gln246 of the target recognition domain (TRD) and some residues of the loop Ser75-Lys83 from the large domain. These findings are further supported by alanine scanning mutagenesis studies. The results reported here explain the sequence, structure and binding features necessary for the recognition between the cofactor and the substrate by the key epigenetic enzyme, M. Hpy C5mC.

Salmonella phages and prophages: genomics, taxonomy, and applied aspects

Since this book was originally published in 2007 there has been a significant increase in the number of Salmonella bacteriophages, particularly lytic virus, and Salmonella strains which have been fully sequenced. In addition, new insights into phage taxonomy have resulted in new phage genera, some of which have been recognized by the International Committee of Taxonomy of Viruses (ICTV). The properties of each of these genera are discussed, along with the role of phage as agents of genetic exchange, as therapeutic agents, and their involvement in phage typing.

Type I restriction-modification system and its resistance in electroporation efficiency in Flavobacterium columnare

Flavobacterium columnare, the causative agent of columnaris disease, infects freshwater fish worldwide. However, the pathogenicity of this bacterium is poorly understood due possibly to the lack of an efficient in-frame knockout technique. In order to improve electroporation efficiency, the type I restriction-modification system (R-M system) was cloned and its role in electroporation was examined in F. columnare G(4) strain. The complete sequence of type I R-M system in the bacterium, designated as Fcl, contains all three subunits of type I R-M system, named as fclM, fclS, fclR, respectively, with the identification of a hypothetical gene, fclX. Constitutive transcription of the three genes was observed in F. columnare G(4) by RT-PCR. The ORF of fclM and fclS was cloned into the plasmid pACYC184 and transformed into Escherichia coli TOP10. The resultant E. coli strain, designated as E. coli TOPmt, was transformed with the integrative plasmid pGL006 constructed for F. columnare G(4). The integrative plasmid was re-isolated from TOPmt and incubated with the lysate of F. columnare G(4). The re-isolated integrative plasmid, designated as pGL006', showed higher resistance than pGL006. With pGL006', the electroporation efficiency of the strain G(4) increased 2.6 times, while that of F. columnare G(18) was not obviously improved. Furthermore, a method to improve the electroporation efficiency of F. columnare G(4) was developed using the integrative plasmid methylated by E. coli TOPmt which contains the fclM and fclS gene of F. columnare G(4). Further analyses showed that the fcl gene cluster may be a unique type I R-M system in F. columnare G(4). It will be of significant interest to examine the composition and diversity of R-M systems in strains of F. columnare in order to set up a suitable genetic manipulation system for the bacterium.

Homology modeling and molecular dynamics simulations of HgiDII methyltransferase in complex with DNA and S-adenosyl-methionine: catalytic mechanism and interactions with DNA

M.HgiDII is a methyltransferase (MTase) from Herpetosiphon giganteus that recognizes the sequence GTCGAC. This enzyme belongs to a group of MTases that share a high degree of amino acid similarity, albeit none of them has been thoroughly characterized. To study the catalytic mechanism of M.HgiDII and its interactions with DNA, we performed molecular dynamics simulations with a homology model of M.HgiDII complexed with DNA and S-adenosyl-methionine. Our results indicate that M.HgiDII may not rely only on Glu119 to activate the cytosine ring, which is an early step in the catalysis of cytosine methylation; apparently, Arg160 and Arg162 may also participate in the activation by interacting with cytosine O2. Another residue from the catalytic site, Val118, also played a relevant role in the catalysis of M.HgiDII. Val118 interacted with the target cytosine and kept water molecules from accessing the region of the catalytic pocket where Cys79 interacts with cytosine, thus preventing water-mediated disruption of interactions in the catalytic site. Specific recognition of DNA was mediated mainly by amino acids of the target recognition domain, although some amino acids (loop 80-88) of the catalytic domain may also contribute to DNA recognition. These interactions involved direct contacts between M.HgiDII and DNA, as well as indirect contacts through water bridges. Additionally, analysis of sequence alignments with closely related MTases helped us to identify a motif in the TRD of M.HgiDII that may be relevant to specific DNA recognition.

Characterisation of the 11 Kb DNA region adjacent to the gene encodingDesulfovibrio gigasflavoredoxin

Flavoredoxin is an FMN binding protein that functions as an electron carrier in the sulphate metabolism of Desulfovibrio gigas. The neighbouring DNA regions of the gene encoding flavoredoxin were sequenced and characterised. Transcript analysis of the flavoredoxin gene resulted in a positive band corresponding to the size of the coding region, suggesting that flavoredoxin is encoded by a monocystronic unit, as previously suggested by sequence analysis. Analysis of the adjacent DNA regions revealed several interesting genes. The sequenced DNA regions contain nine open reading frames (ORFs) organised in two polycystronic and two monocystronic units. These genes encode proteins involved in different metabolic pathways, namely in DNA methylation, tRNA and rRNA modification, mRNA metabolism, cell division, CoA synthesis and lipoprotein transport across the membrane.

Plant cytosine-5 DNA methyltransferases: Structure, function, and molecular evolution

A detailed analysis of the structure and function, along with evolutionary aspects, of the main plant cytosine-5 DNA methyltransferases (C5-MTases) is presented. The evolutionary relationships between the already known and four candidate plant C5-MTases identified in this work were investigated using the distance, maximum-parsimony, and maximum-likelihood approaches. The topologies of the trees were overall congruent: four monophyletic groups corresponding to the four plant C5-MTase families were clearly distinguished. In addition, sequence analyses of the plant C5-MTase target recognition domain sequences were performed and phylogenetic trees were reconstructed showing that there is good conservation among but not within the plant C5-MTase families. Furthermore, a conserved dipeptide that plays an important role in flipping the target base into the catalytic site of the C5-MTases was identified in all plant C5-MTases under study.

Dissecting nucleic acid-protein interactions using challenge phage

The bacteriophage P22-based challenge system is a sophisticated genetic tool for the characterization of sequence-specific recognition of DNA and RNA in vivo. The construction of challenge phage follows simple phage lysate preparations and detection of constructs by positive selection methods for plaques on selective strains. The challenge phage system is a powerful tool for the characterization of protein-DNA and protein-RNA interactions in vivo. The challenge phage has been further developed to characterize the interactions of multiple proteins in heteromultimeric complexes that are required for DNA binding. Under appropriate conditions, expression of the ant gene determines the lysis-lysogeny decision of P22. This provides a positive selection for and against DNA binding: repression of ant can be selected by requiring growth of lysogens, and mutants that cannot repress ant can be selected by requiring lytic growth of the phage. Thus, placing ant gene expression under the control of a specific DNA-protein interaction provides very strong genetic selections for regulatory mutations in the DNA-binding protein and DNA-binding site that either increase or decrease the apparent strength of a DNA-protein interaction in vivo. Furthermore, the challenge phage contains a kanamycin-resistance element that can be used to either directly select for lysogeny or to determine the frequency of lysogeny for a given protein-DNA interaction to measure the efficiency of DNA binding in vivo. Selection for lysogeny can be used to isolate DNA-binding proteins with altered or enhanced DNA-binding specificities. The challenge phage selection provides a general method for identifying critical residues involved in DNA-protein interactions. Challenge phage selections have been used to genetically dissect many different prokaryotic and eukaryotic DNA-binding interactions.

Salmonella phages and prophages--genomics and practical aspects

Numerous bacteriophages specific to Salmonella have been isolated or identified as part of host genome sequencing projects. Phylogenetic analysis of the sequenced phages, based on related protein content using CoreGenes, reveals that these viruses fall into five groupings (P27-like, P2-like, lambdoid, P22-like, and T7-like) and three outliers (epsilon15, KS7, and Felix O1). The P27 group is only represented by ST64B; the P2 group contains Fels-2, SopEphi, and PSP3; the lambdoid Salmonella phages include Gifsy-1, Gifsy-2, and Fels-1. The P22-like viruses include epsilon34, ES18, P22, ST104, and ST64T. The only member of the T7-like group is SP6. The properties of each of these phages are discussed, along with their role as agents of genetic exchange and as therapeutic agents and their involvement in phage typing.

Structure, function and mechanism of exocyclic DNA methyltransferases

DNA MTases (methyltransferases) catalyse the transfer of methyl groups to DNA from AdoMet (S-adenosyl-L-methionine) producing AdoHcy (S-adenosyl-L-homocysteine) and methylated DNA. The C5 and N4 positions of cytosine and N6 position of adenine are the target sites for methylation. All three methylation patterns are found in prokaryotes, whereas cytosine at the C5 position is the only methylation reaction that is known to occur in eukaryotes. In general, MTases are two-domain proteins comprising one large and one small domain with the DNA-binding cleft located at the domain interface. The striking feature of all the structurally characterized DNA MTases is that they share a common core structure referred to as an 'AdoMet-dependent MTase fold'. DNA methylation has been reported to be essential for bacterial virulence, and it has been suggested that DNA adenine MTases (Dams) could be potential targets for both vaccines and antimicrobials. Drugs that block Dam could slow down bacterial growth and therefore drug-design initiatives could result in a whole new generation of antibiotics. The transfer of larger chemical entities in a MTase-catalysed reaction has been reported and this represents an interesting challenge for bio-organic chemists. In general, amino MTases could therefore be used as delivery systems for fluorescent or other reporter groups on to DNA. This is one of the potential applications of DNA MTases towards developing non-radioactive DNA probes and these could have interesting applications in molecular biology. Being nucleotide-sequence-specific, DNA MTases provide excellent model systems for studies on protein-DNA interactions. The focus of this review is on the chemistry, enzymology and structural aspects of exocyclic amino MTases.

Dimerization of the bacterial RsrI N6-adenine DNA methyltransferase

Dimeric restriction endonucleases and monomeric modification methyltransferases were long accepted as the structural paradigm for Type II restriction systems. Recent studies, however, have revealed an increasing number of apparently dimeric DNA methyltransferases. Our initial characterization of RsrI methyltransferase (M.RsrI) was consistent with the enzyme functioning as a monomer, but, subsequently, the enzyme crystallized as a dimer with 1500 Ų of buried surface area. This result led us to re-examine the biochemical properties of M.RsrI. Gel-shift studies of M.RsrI binding to DNA suggested that binding cooperativity targets hemimethylated DNA preferentially over unmethylated DNA. Size-exclusion chromatography indicated that the M.RsrI–DNA complex had a size and stoichiometry consistent with a dimeric enzyme binding to the DNA. Kinetic measurements revealed a quadratic relationship between enzyme velocity and concentration. Site-directed mutagenesis at the dimer interface affected the kinetics and DNA-binding of the enzyme, providing support for a model proposing an active enzyme dimer. We also identified a conserved motif in the dimer interfaces of the β-class methyltransferases M.RsrI, M.MboIIA and M2.DpnII. Taken together, these data suggest that M.RsrI may be part of a sub-class of MTases that function as dimers.

Structures of liganded and unliganded RsrI N6-adenine DNA methyltransferase: a distinct orientation for active cofactor binding

The structures of RsrI DNA methyltransferase (M.RsrI) bound to the substrate S-adenosyl-l-methionine (AdoMet), the product S-adenosyl-l-homocysteine (AdoHcy), the inhibitor sinefungin, as well as a mutant apo-enzyme have been determined by x-ray crystallography. Two distinct binding configurations were observed for the three ligands. The substrate AdoMet adopts a bent shape that directs the activated methyl group toward the active site near the catalytic DPPY motif. The product AdoHcy and the competitive inhibitor sinefungin bind with a straight conformation in which the amino acid moiety occupies a position near the activated methyl group in the AdoMet complex. Analysis of ligand binding in comparison with other DNA methyltransferases reveals a small, common subset of available conformations for the ligand. The structures of M.RsrI with the non-substrate ligands contained a bound chloride ion in the AdoMet carboxylate-binding pocket, explaining its inhibition by chloride salts. The L72P mutant of M.RsrI is the first DNA methyltransferase structure without bound ligand. With respect to the wild-type protein, it had a larger ligand-binding pocket and displayed movement of a loop (223-227) that is responsible for binding the ligand, which may account for the weaker affinity of the L72P mutant for AdoMet. These studies show the subtle changes in the tight specific interactions of substrate, product, and an inhibitor with M.RsrI and help explain how each displays its unique effect on the activity of the enzyme.

DNA methyltransferase and demethylase in human prostate cancer

Recent studies have shown that cytosine-5 methylation at CpG islands in the regulatory sequence of a gene is one of the key mechanisms of inactivation. The enzymes responsible for CpG methylation are DNA methyltransferase (DNMT) 1, DNMT3a, and DNMT3b, and the enzyme responsible for demethylation is DNA demethylase (MBD2). Studies on methylation-demethylation enzymes are lacking in human prostate cancer. We hypothesize that MBD2 enzyme activity is repressed and that DNMT1 enzyme activity is elevated in human prostate cancer. To test this hypothesis, we analyzed enzyme activities, mRNA, and protein levels of MBD2 and DNMT1, DNMT3a, and DNMT3b in human prostate cancer cell lines and tissues. The enzyme activities of DNMTs and MBD2 were analyzed by biochemical assay. The mRNA expression was analyzed by reverse transcriptase-polymerase chain reaction and by Northern blotting. The protein expression was measured by immunohistochemistry with specific antibodies. The results of these experiments demonstrated that (1) the activity of DNMTs was twofold to threefold higher in cancer cell lines and cancer tissues, as compared with a benign prostate epithelium cell line (BPH-1) and benign prostatic hyperplasia (BPH) tissues; (2) MBD2 activity was lacking in prostate cancer cell lines but present in BPH-1 cells; (3) immunohistochemical analyses exhibited higher expression of DNMT1 in all prostate cancer cell lines and cancer tissues, as compared with BPH-1 cell lines and BPH tissues; (4) MBD2 protein expression was significantly higher in BPH-1 cells and lacking in prostate cancer cell lines and, in BPH tissues, MBD2 protein expression was poorly observed, as compared with no expression in prostate cancer tissues; and (5) mRNA expression for DNMT1 was upregulated in prostate cancer, as compared with BPH-1, and mRNA expression for MBD2 was found to be significantly expressed in all cases. The results of these studies clearly demonstrate that DNMT1 activity is upregulated, whereas MBD2 is repressed at the level of translation in human prostate cancer. These results may demonstrate molecular mechanisms of CpG hypermethylation of various genes in prostate cancer.

Mutational analysis of two putative catalytic motifs of the type IV restriction endonuclease Eco57I

The role of two sequence motifs (SM) as putative cleavage catalytic centers (77)PDX(13)EAK (SM I) and (811)PDX(20)DQK (SM II) of type IV restriction endonuclease Eco57I was studied by site-directed mutational analysis. Substitutions within SM I; D78N, D78A, D78K, and E92Q reduced cleavage activity of Eco57I to a level undetectable both in vivo and in vitro. Residual endonucleolytic activity of the E92Q mutant was detected only when the Mg(2+) in the standard reaction mixture was replaced with Mn(2+). The mutants D78N and E92Q retained the ability to interact with DNA specifically. The mutants also retained DNA methylation activity of Eco57I. The properties of the SM I mutants indicate that Asp(78) and Glu(92) residues are essential for cleavage activity of the Eco57I, suggesting that the sequence motif (77)PDX(13)EAK represents the cleavage active site of this endonuclease. Eco57I mutants containing single amino acid substitutions within SM II (D812A, D833N, D833A) revealed only a small or moderate decrease of cleavage activity as compared with wild-type Eco57I, indicating that the SM II motif does not represent the catalytic center of Eco57I. The results, taken together, allow us to conclude that the Eco57I restriction endonuclease has one catalytic center for cleavage of DNA.

Substrate binding in vitro and kinetics of RsrI [N6-adenine] DNA methyltransferase

RSR:I [N:6-adenine] DNA methyltransferase (M.RSR:I), which recognizes GAATTC and is a member of a restriction-modification system in Rhodobacter sphaeroides, was purified to >95% homogeneity using a simplified procedure involving two ion exchange chromatographic steps. Electrophoretic gel retardation assays with purified M.RSR:I were performed on unmethylated, hemimethylated, dimethylated or non-specific target DNA duplexes (25 bp) in the presence of sinefungin, a potent inhibitory analog of AdoMet. M. RSR:I binding was affected by the methylation status of the DNA substrate and was enhanced by the presence of the cofactor analog. M. RSR:I bound DNA substrates in the presence of sinefungin with decreasing affinities: hemimethylated > unmethylated > dimethylated >> non-specific DNA. Gel retardation studies with DNA substrates containing an abasic site substituted for the target adenine DNA provided evidence consistent with M.RSR:I extruding the target base from the duplex. Consistent with such base flipping, an approximately 1.7-fold fluorescence intensity increase was observed upon stoichiometric addition of M.RSR:I to hemimethylated DNA containing the fluorescent analog 2-aminopurine in place of the target adenine. Pre-steady-state kinetic and isotope- partitioning experiments revealed that the enzyme displays burst kinetics, confirmed the catalytic competence of the M.RSR:I-AdoMet complex and eliminated the possibility of an ordered mechanism where DNA is required to bind first. The equilibrium dissociation constants for AdoMet, AdoHcy and sinefungin were determined using an intrinsic tryptophan fluorescence-quenching assay.

Structure of RsrI methyltransferase, a member of the N6-adenine beta class of DNA methyltransferases

DNA methylation is important in cellular, developmental and disease processes, as well as in bacterial restriction-modification systems. Methylation of DNA at the amino groups of cytosine and adenine is a common mode of protection against restriction endonucleases afforded by the bacterial methyltransferases. The first structure of an N:6-adenine methyltransferase belonging to the beta class of bacterial methyltransferases is described here. The structure of M. RSR:I from Rhodobacter sphaeroides, which methylates the second adenine of the GAATTC sequence, was determined to 1.75 A resolution using X-ray crystallography. Like other methyltransferases, the enzyme contains the methylase fold and has well-defined substrate binding pockets. The catalytic core most closely resembles the PVU:II methyltransferase, a cytosine amino methyltransferase of the same beta group. The larger nucleotide binding pocket observed in M. RSR:I is expected because it methylates adenine. However, the most striking difference between the RSR:I methyltransferase and the other bacterial enzymes is the structure of the putative DNA target recognition domain, which is formed in part by two helices on an extended arm of the protein on the face of the enzyme opposite the active site. This observation suggests that a dramatic conformational change or oligomerization may take place during DNA binding and methylation.