Evolution of type II DNA methyltransferases. A gene duplication model

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).

Conserved DNA Methyltransferases: A Window into Fundamental Mechanisms of Epigenetic Regulation in Bacteria

An increasing number of studies have reported that bacterial DNA methylation has important functions beyond the roles in restriction-modification systems, including the ability of affecting clinically relevant phenotypes such as virulence, host colonization, sporulation, biofilm formation, among others. Although insightful, such studies have a largely ad hoc nature and would benefit from a systematic strategy enabling a joint functional characterization of bacterial methylomes by the microbiology community. In this opinion article, we propose that highly conserved DNA methyltransferases (MTases) represent a unique opportunity for bacterial epigenomic studies. These MTases are rather common in bacteria, span various taxonomic scales, and are present in multiple human pathogens. Apart from well-characterized core DNA MTases, like those from Vibrio cholerae, Salmonella enterica, Clostridioides difficile, or Streptococcus pyogenes, multiple highly conserved DNA MTases are also found in numerous human pathogens, including those belonging to the genera Burkholderia and Acinetobacter. We discuss why and how these MTases can be prioritized to enable a community-wide, integrative approach for functional epigenomic studies. Ultimately, we discuss how some highly conserved DNA MTases may emerge as promising targets for the development of novel epigenetic inhibitors for biomedical applications.

A model for the evolution of prokaryotic DNA restriction-modification systems based upon the structural malleability of Type I restriction-modification enzymes

Restriction Modification (RM) systems prevent the invasion of foreign genetic material into bacterial cells by restriction and protect the host's genetic material by methylation. They are therefore important in maintaining the integrity of the host genome. RM systems are currently classified into four types (I to IV) on the basis of differences in composition, target recognition, cofactors and the manner in which they cleave DNA. Comparing the structures of the different types, similarities can be observed suggesting an evolutionary link between these different types. This work describes the ‘deconstruction’ of a large Type I RM enzyme into forms structurally similar to smaller Type II RM enzymes in an effort to elucidate the pathway taken by Nature to form these different RM enzymes. Based upon the ability to engineer new enzymes from the Type I ‘scaffold’, an evolutionary pathway and the evolutionary pressures required to move along the pathway from Type I RM systems to Type II RM systems are proposed. Experiments to test the evolutionary model are discussed.

Genomic Characteristics of Desulfonema ishimotonii Tokyo 01T Implying Horizontal Gene Transfer Among Phylogenetically Dispersed Filamentous Gliding Bacteria

Desulfonema ishimotonii strain Tokyo 01^T is a filamentous sulfate-reducing bacterium isolated from a marine sediment. In this study, the genome of this strain was sequenced and analyzed with a focus on gene transfer from phylogenetically distant organisms. While the strain belongs to the class Deltaproteobacteria, hundreds of proteins encoded in the genome showed the highest sequence similarities to those of organisms outside of the class Deltaproteobacteria, suggesting that more than 20% of the genome is putatively of foreign origins. Many of these proteins had the highest sequence identities with proteins encoded in the genomes of filamentous bacteria, including giant sulfur oxidizers of the orders Thiotrichales, cyanobacteria of various genera, and uncultured bacteria of the candidate phylum KSB3. As mobile genetic elements transferred from phylogenetically distant organisms, putative inteins were identified in the GyrB and DnaE proteins encoded in the genome of strain Tokyo 01^T. Genes involved in DNA recombination and repair were enriched in comparison to the closest relatives in the same family. Some of these genes were also related to those of organisms outside of the class Deltaproteobacteria, suggesting that they were acquired by horizontal gene transfer from diverse bacteria. The genomic data suggested significant genetic transfer among filamentous gliding bacteria in phylogenetically dispersed lineages including filamentous sulfate reducers. This study provides insights into the genomic evolution of filamentous bacteria belonging to diverse lineages, characterized by various physiological functions and different ecological roles.

Diverse functions of restriction-modification systems in addition to cellular defense

Restriction-modification (R-M) systems are ubiquitous and are often considered primitive immune systems in bacteria. Their diversity and prevalence across the prokaryotic kingdom are an indication of their success as a defense mechanism against invading genomes. However, their cellular defense function does not adequately explain the basis for their immaculate specificity in sequence recognition and nonuniform distribution, ranging from none to too many, in diverse species. The present review deals with new developments which provide insights into the roles of these enzymes in other aspects of cellular function. In this review, emphasis is placed on novel hypotheses and various findings that have not yet been dealt with in a critical review. Emerging studies indicate their role in various cellular processes other than host defense, virulence, and even controlling the rate of evolution of the organism. We also discuss how R-M systems could have successfully evolved and be involved in additional cellular portfolios, thereby increasing the relative fitness of their hosts in the population.

Recognition of nontrivial remote homology relationships involving proteins of Helicobacter pylori: implications for function recognition

This chapter explains techniques for recognition of nontrivial remote homology relationships involving proteins of Helicobacter pylori and their implications for function recognition. Using the remote homology detection method, employing multiple-profile representations for every protein domain family, remotely related domain family information has been assigned for the 122, 77, and 95 protein sequences of 26695, and J99, and HPAG1 strains of H. pylori, respectively. Relationships for some of the H. pylori protein sequences with Pfam domain families are reported for the first time. In publicly available domain databases such as Pfam, for some of the H. pylori protein sequences functional domain information is associated only with part(s) of the proteins. In the current study other parts of such proteins have been shown to be remotely related to known domain families, raising the possibility of identifying functions for parts of the proteins that do not yet have domains assigned. Further, homologues of enzymes that potentially catalyze step(s) in various metabolic processes in H. pylori have been identified for the first time.

Evolution of sequence specificity in a restriction endonuclease by a point mutation

Restriction endonucleases (REases) protect bacteria from invading foreign DNAs and are endowed with exquisite sequence specificity. REases have originated from the ancestral proteins and evolved new sequence specificities by genetic recombination, gene duplication, replication slippage, and transpositional events. They are also speculated to have evolved from nonspecific endonucleases, attaining a high degree of sequence specificity through point mutations. We describe here an example of generation of exquisitely site-specific REase from a highly-promiscuous one by a single point mutation.

DNA methyltransferases from Neisseria meningitidis and Neisseria gonorrhoeae FA1090 associated with mismatch nicking endonucleases

The genes encoding the DNA methyltransferases M.NmeDI and M.NmeAI from Neisseria meningitidis associated with the genes encoding putative Vsr endonucleases were overexpressed in Escherichia coli. The enzymes were purified to apparent homogeneity on Ni-NTA agarose columns, yielding proteins of 49+/-1 kDa and 39.6+/-1 kDa, respectively, under denaturing conditions. M.NmeDI recognizes the degenerate sequence 5'-RCCGGB-3'. It methylates the first 5' cytosine residue on both strands within the core sequence CCGG. The enzyme shows higher affinity with the hemimethylated degenerate sequence than with the unmethylated degenerate sequence. Comparison of the amino acid sequence of the target-recognizing domain of M.NmeDI with the closest neighbours recognizing the sequence 5'-RCCGGY-3' showed the presence of the homologous domain and an additional domain that may be responsible for recognizing the degenerate sequence. M.NmeAI recognizes the sequence 5'-CCGG-3' and methylates the second 5' cytosine residue on both DNA strands. In Neisseria gonorrhoeae strain FA1090 the homologues of these ORFs are truncated due to a variety of mutations.

The N-terminus of m5C-DNA methyltransferase MspI is involved in its topoisomerase activity

DNA cytosine methyltransferase MspI (M.MspI) must require a different type of interaction of protein with DNA from other bacterial DNA cytosine methyltransferases (m5C-MTases) to evoke the topoisomerase activity that it possesses in addition to DNA-methylation ability. This may require a different structural organization in the solution phase from the reported consensus structural arrangement for m5C-MTases. Limited proteolysis of M.MspI, however, generates two peptide fragments, a large one (p26) and a small one (p18), consistent with reported m5C-MTase structures. Examination of the amino-acid sequence of M.MspI revealed similarity to human topoisomerase I at the N-terminus. Alignment of the amino-acid sequence of M.MspI also uncovered similarity (residues 245-287) to the active site of human DNA ligase I. To evaluate the role of the N-terminus of M.MspI, 2-hydroxy-5-nitrobenzyl bromide (HNBB) was used to truncate M.MspI between residues 34 and 35. The purified HNBB-truncated protein has a molecular mass of approximately equal 45 kDa, retains DNA binding and methyltransferase activity, but does not possess topoisomerase activity. These findings were substantiated using a purified recombinant MspI protein with the N-terminal 34 amino acids deleted. Changing the N-terminal residues Trp34 and Tyr74 to alanine results in abolition of the topoisomerase I activity while the methyltransferase activity remains intact.

Structure-based phylogenetic analysis of short-chain alcohol dehydrogenases and reclassification of the 17beta-hydroxysteroid dehydrogenase family

Short-chain alcohol dehydrogenases (SCAD) constitute a large and diverse family of ancient origin. Several of its members play an important role in human physiology and disease, especially in the metabolism of steroid substrates (e.g., prostaglandins, estrogens, androgens, and corticosteroids). Their involvement in common human disorders such as endocrine-related cancer, osteoporosis, and Alzheimer disease makes them an important candidate for drug targets. Recent phylogenetic analysis of SCAD is incomplete and does not allow any conclusions on very ancient divergences or on a functional characterization of novel proteins within this complex family. We have developed a 3D structure-based approach to establish the deep-branching pattern within the SCAD family. In this approach, pairwise superpositions of X-ray structures were used to calculate similarity scores as an input for a tree-building algorithm. The resulting phylogeny was validated by comparison with the results of sequence-based algorithms and biochemical data. It was possible to use the 3D data as a template for the reliable determination of the phylogenetic position of novel proteins as a first step toward functional predictions. We were able to discern new patterns in the phylogenetic relationships of the SCAD family, including a basal dichotomy of the 17beta-hydroxysteroid dehydrogenases (17beta-HSDs). These data provide an important contribution toward the development of type-specific inhibitors for 17beta-HSDs for the treatment and prevention of disease. Our structure-based phylogenetic approach can also be applied to increase the reliability of evolutionary reconstructions in other large protein families.

Cloning and characterization of PIMT, a protein with a methyltransferase domain, which interacts with and enhances nuclear receptor coactivator PRIP function

The nuclear receptor coactivators participate in the transcriptional activation of specific genes by nuclear receptors. In this study, we report the isolation of a nuclear receptor coactivator-interacting protein from a human liver cDNA library by using the coactivator peroxisome proliferator-activated receptor-interacting protein (PRIP) (ASC2/AIB3/RAP250/NRC/TRBP) as bait in a yeast two-hybrid screen. Human PRIP-interacting protein cDNA has an ORF of 2,556 nucleotides, encodes a protein with 852 amino acids, and contains a 9-aa VVDAFCGVG methyltransferase motif I and an invariant GXXGXXI segment found in K-homology motifs of many RNA-binding proteins. The gene encoding this protein, designated PRIP-interacting protein with methyltransferase domain (PIMT), is localized on chromosome 8q11 and spans more than 40 kb. PIMT mRNA is ubiquitously expressed, with a high level of expression in heart, skeletal muscle, kidney, liver, and placenta. Using the immunofluorescence localization method, we found that PIMT and PRIP proteins appear colocalized in the nucleus. PIMT strongly interacts with PRIP under in vitro and in vivo conditions, and the PIMT-binding site on PRIP is in the region encompassing amino acids 773-927. PIMT binds S-adenosyl-l-methionine, the methyl donor for methyltransfer reaction, and it also binds RNA, suggesting that it is a putative RNA methyltransferase. PIMT enhances the transcriptional activity of peroxisome proliferator-activated receptor gamma and retinoid-X-receptor alpha, which is further stimulated by coexpression of PRIP, implying that PIMT is a component of nuclear receptor signal transduction apparatus acting through PRIP. Definitive identification of the specific substrate of PIMT and the role of this RNA-binding protein in transcriptional regulation remain to be determined.

Evolutionary Role of Restriction/Modification Systems as Revealed by Comparative Genome Analysis

Type II restriction modification systems (RMSs) have been regarded either as defense tools or as molecular parasites of bacteria. We extensively analyzed their evolutionary role from the study of their impact in the complete genomes of 26 bacteria and 35 phages in terms of palindrome avoidance. This analysis reveals that palindrome avoidance is not universally spread among bacterial species and that it does not correlate with taxonomic proximity. Palindrome avoidance is also not universal among bacteriophage, even when their hosts code for RMSs, and depends strongly on the genetic material of the phage. Interestingly, palindrome avoidance is intimately correlated with the infective behavior of the phage. We observe that the degree of palindrome and restriction site avoidance is significantly and consistently less important in phages than in their bacterial hosts. This result brings to the fore a larger selective load for palindrome and restriction site avoidance on the bacterial hosts than on their infecting phages. It is then consistent with a view where type II RMSs are considered as parasites possibly at the verge of mutualism. As a consequence, RMSs constitute a nontrivial third player in the host–parasite relationship between bacteria and phages.

Specificity of DNA binding and methylation by the M.FokI DNA methyltransferase

The M.FokI adenine-N(6) DNA methyltransferase recognizes the asymmetric DNA sequence GGATG/CATCC. It consists of two domains each containing all motifs characteristic for adenine-N(6) DNA methyltransferases. We have studied the specificity of DNA-methylation by both domains using 27 hemimethylated oligonucleotide substrates containing recognition sites which differ in one or two base pairs from GGATG or CATCC. The N-terminal domain of M.FokI interacts very specifically with GGATG-sequences, because only one of the altered sites is modified. In contrast, the C-terminal domain shows lower specificity. It prefers CATCC-sequences but only two of the 12 star sites (i.e. sites that differ in 1 bp from the recognition site) are not accepted and some star sites are modified with rates reduced only 2-3-fold. In addition, GGATGC- and CGATGC-sites are modified which differ at two positions from CATCC. DNA binding experiments show that the N-terminal domain preferentially binds to hemimethylated GGATG/C(m)ATCC sequences whereas the C-terminal domain binds to DNA with higher affinity but without specificity. Protein-protein interaction assays show that both domains of M.FokI are in contact with each other. However, several DNA-binding experiments demonstrate that DNA-binding of both domains is mutually exclusive in full-length M.FokI and both domains do not functionally influence each other. The implications of these results on the molecular evolution of type IIS restriction/modification systems are discussed.

Structural characterization of two tandemly arranged DNA methyltransferase genes from Neisseria gonorrhoeae MS11: N4-cytosine specific M.NgoMXV and nonfunctional 5-cytosine-type M.NgoMorf2P

Two adjacent genes encoding DNA methyltransferases (MTases) of Neisseria gonorrhoeae MS11, an active N4-cytosine specific M. NgoMXV and an inactive 5-cytosine type M. NgoMorf2P, were cloned into Escherichia coli and sequenced. We analyzed the deduced amino acid sequence of both gene products and localized conserved regions characteristic for DNA MTases. Structure prediction, threading-derived alignments, and comparison with the common fold for DNA MTases allowed for construction of super-secondary and tertiary models for M.NgoMorf2P and M.NgoMXV, respectively. These models helped in identification of amino acids and structural elements essential for function of both enzymes. The implications of this putative structural model on the catalytic mechanism of M.NgoMXV and its possible relation to the common ancestor of modern DNA amino-MTases are also discussed.

Molecular evolution of DNA-(cytosine-N4) methyltransferases: evidence for their polyphyletic origin

DNA N4-cytosine methyltransferases (N4mC MTases) are a family of S-adenosyl-L-methionine (AdoMet)-dependent MTases. Members of this family were previously found to share nine conserved sequence motifs, but the evolutionary basis of these similarities has never been studied in detail. We performed phylogenetic analysis of 37 known and potential new family members from the multiple sequence alignment using distance matrix, parsimony and maximum likelihood approaches to infer the evolutionary relationship among the N4mC MTases and classify them into groups of orthologs. All the treeing algorithms employed as well as results of exhaustive sequence database searching support a scenario, in which the majority of N4mC MTases, except for M. Bal I and M. Bam HI, arose by divergence from a common ancestor. Interestingly, MTases M. Bal I and M. Bam HI apparently originated from N6-adenine MTases and represent the most recent addendum to the N4mC MTase family. In addition to the previously reported nine sequence motifs, two more conserved sequence patches were detected. Phylogenetic analysis also provided the evidence for massive horizontal transfer of MTase genes, presumably with the whole restriction-modification systems, between Bacteria and Archaea.

Identification of specific residues involved in substrate discrimination in two plant O-methyltransferases

Among the large number of plant O-methyltransferases that are involved in secondary metabolism, only a few have been enzymatically characterized, and little information is available on the structure of their substrate binding site and the mechanism which determines their substrate specificity and methylation regiospecificity. We have previously reported the isolation of two O-methyltransferases, S-adenosyl-l-methionine:(iso)eugenol O-methyltransferase (IEMT) and S-adenosyl-l-methionine:caffeic acid O-methyltransferase (COMT) from Clarkia breweri, an annual plant from California. While IEMT and COMT (which methylate eugenol/isoeugenol and caffeic acid/5-hydroxyferulic acid, respectively) share 83% identity at the amino acid level, they have distinct substrate specificity and methylation regiospecificity. We report here that seven amino acids play a critical role in discriminating between eugenol/isoeugenol and caffeic acid/5-hydroxyferulic acid. When these amino acids in IEMT were replaced by the corresponding residues of COMT, the hybrid protein showed activity only with caffeic acid/5-hydroxyferulic acid. Conversely, when these amino acids in COMT were replaced by corresponding IEMT residues, the hybrid protein had activity only with eugenol/isoeugenol. These results provide strong evidence that O-methyltransferase substrate preference could be determined by a few amino acid residues and that new OMTs with different substrate specificity could begin to evolve from an existing OMT by mutation of a few amino acids. Phylogenetic analysis confirms that C. breweri IEMT evolved recently from COMT.

A type IC restriction-modification system in Lactococcus lactis

Three genes coding for the endonuclease, methylase, and specificity subunits of a type I restriction-modification (R-M) system in the Lactococcus lactis plasmid pIL2614 have been characterized. Plasmid location, sequence homologies, and inactivation studies indicated that this R-M system is most probably of type IC.

A putative leucine zipper activator of Pasteurella haemolytica leukotoxin transcription and the potential for modulation of its synthesis by slipped-strand mispairing

A Pasteurella haemolytica cosmid clone that activates leukotoxin transcription in Escherichia coli has been isolated. The activator locus, alxA, is part of a continuous open reading frame that includes the type I hsdM methylase gene. AlxA and HsdM peptides are processed from a precursor, and translation of the polyprotein can be modulated by slipped-strand mispairing across a pentanucleotide repeat, ACAGC, within the 5' end of alxA-hsdM. Extracts containing AlxA can bind to a leukotoxin promoter fragment.

Structure of pvu II DNA-(cytosine N4) methyltransferase, an example of domain permutation and protein fold assignment

We have determined the structure of Pvu II methyltransferase (M. Pvu II) complexed with S -adenosyl-L-methionine (AdoMet) by multiwavelength anomalous diffraction, using a crystal of the selenomethionine-substituted protein. M. Pvu II catalyzes transfer of the methyl group from AdoMet to the exocyclic amino (N4) nitrogen of the central cytosine in its recognition sequence 5'-CAGCTG-3'. The protein is dominated by an open alpha/beta-sheet structure with a prominent V-shaped cleft: AdoMet and catalytic amino acids are located at the bottom of this cleft. The size and the basic nature of the cleft are consistent with duplex DNA binding. The target (methylatable) cytosine, if flipped out of the double helical DNA as seen for DNA methyltransferases that generate 5-methylcytosine, would fit into the concave active site next to the AdoMet. This M. Pvu IIalpha/beta-sheet structure is very similar to those of M. Hha I (a cytosine C5 methyltransferase) and M. Taq I (an adenine N6 methyltransferase), consistent with a model predicting that DNA methyltransferases share a common structural fold while having the major functional regions permuted into three distinct linear orders. The main feature of the common fold is a seven-stranded beta-sheet (6 7 5 4 1 2 3) formed by five parallel beta-strands and an antiparallel beta-hairpin. The beta-sheet is flanked by six parallel alpha-helices, three on each side. The AdoMet binding site is located at the C-terminal ends of strands beta1 and beta2 and the active site is at the C-terminal ends of strands beta4 and beta5 and the N-terminal end of strand beta7. The AdoMet-protein interactions are almost identical among M. Pvu II, M. Hha I and M. Taq I, as well as in an RNA methyltransferase and at least one small molecule methyltransferase. The structural similarity among the active sites of M. Pvu II, M. Taq I and M. Hha I reveals that catalytic amino acids essential for cytosine N4 and adenine N6 methylation coincide spatially with those for cytosine C5 methylation, suggesting a mechanism for amino methylation.

The restriction-modification system of Pasteurella haemolytica is a member of a new family of type I enzymes

Genes encoding the type I restriction-modification (R-M) system of the bovine pathogen, Pasteurella haemolytica, have been identified immediately downstream of a locus that encodes a transcriptional activator of P. haemolytica leukotoxin expression. Type I enzymes are encoded by three genes called hsdM, hsdS and hsdR, and have fallen into three groups, called Ia, Ib and Ic. HsdS provides a sequence recognition function which in concert with HsdM forms an active methyltransferase (MTase). Inclusion of the HsdR subunit in the complex creates an active restriction endonuclease (ENase) capable of cleaving unmethylated target DNA. The P. haemolytica hsdMSR genes were mapped using transposon Tn10d-Cam insertions, and bacteriophage restriction and modification assays in Escherichia coli. We determined the nucleotide sequences of hsdM, hsdS and hsdR, and observed that the deduced amino acid (aa) sequences were very similar to predicted R-M subunits in the respiratory pathogen, Haemophilus influenzae. Phylogenetic comparisons of all known Hsd aa sequences placed the P. haemolytica and H. influenzae proteins into a new group which we labeled the Type Id R-M family. Expression of the P. haemolytica R-M genes in E. coli was inefficient and is likely to be a consequence of the unusual codon usage in P. haemolytica genes.

Cloning and characterization of the MamI restriction-modification system from Microbacterium ammoniaphilum in Escherichia coli

The genes encoding a class-IIN restriction-modification (R-M) system (MamI, sequence specificity [symbol: see text] from Microbacterium ammoniaphilum have been cloned in Escherichia coli. The vector used for cloning was plasmid pUC18 modified by the inclusion of three MamI recognition sites. Recombinant clones containing the mamIM gene in its genomic context became fully methylated in vivo and remained completely resistant against digestion with the R.MamI restriction endonuclease (ENase). Determination of the nucleotide (nt) sequence revealed three open reading frames with lengths of 1089 bp (ORF1), 276 bp (ORFc) and 927 bp (ORF2). On the basis of expression and deletion experiments, the 1089-bp ORF1 was assigned to mamIM encoding the M.MamI DNA methyltransferase (MTase). By amino acid sequencing of the N terminus of R.MamI and comparison of the deduced nt sequence with ORF2, the 927-bp ORF2 was identified as the mamIR gene encoding R.MamI. The 276-bp ORFc, located between mamIR and mamIM, is part of the DNA sequence downstream from mamIM shown to be necessary for controlled mamIM expression.

Function of Pro-185 in the ProCys of conserved motif IV in the EcoRII [cytosine-C5]-DNA methyltransferase

ProCys in the conserved sequence motif IV of [cytosine-C5]-DNA methyltransferases is known to be part of the catalytic site. The Cys residue is directly involved in forming a covalent bond with the C6 of the target cytosine. We have found that substitution of Pro-185 with either Ala or Ser resulted in a reduced rate of methyl group transfer by the EcoRII DNA methyltransferase. In addition, we observed an increase in the Km for substrate S-adenosyl-L-methionine (AdoMet), but a decrease in the Km for substrate DNA. This is reflected in minor changes in kcat/Km for DNA, but in 10- to 100-fold reductions in kcat/Km for AdoMet. This suggests that Pro-185 is important to properly orient the activated cytosine and AdoMet for methyl group transfer by direct interaction with AdoMet and indirectly via the Cys interaction with cytosine.

Cloning and sequencing of LlaDCHI [corrected] restriction/modification genes from Lactococcus lactis and relatedness of this system to the Streptococcus pneumoniae DpnII system

The natural 7.8-kb plasmid pSRQ700 was isolated from Lactococcus lactis subsp. cremoris DCH-4. It encodes a restriction/modification system named LlaDCHI [corrected]. When introduced into a phage-sensitive L. lactis strain, pSRQ700 confers strong phage resistance against the three most common lactococcal phage species, namely, 936, c2, and P335. The LlaDCHI [corrected] endonuclease was purified and found to cleave the palindromic sequence 5'-GATC-3'. It is an isoschizomer of Streptococcus pneumoniae DpnII. The plasmid pSRQ700 was mapped, and the genetic organization of LlaDCHI [corrected] was localized. Cloning and sequencing of the entire LlaDCHI [corrected] system allowed the identification of three open reading frames. The three genes (llaIIA, llaIIB, and llaIIC) overlapped and are under one putative promoter. A putative terminator was found at the end of llaIIC. The genes llaIIA and llaIIB coded for m6A methyltransferases, and llaIIC coded for an endonuclease. The LlaDCHI [corrected] system shares strong genetic similarities with the DpnII system. The deduced amino acid sequence of M.LlaIIA was 75% identical with that of M.DpnII, whereas M.LlaIIB was 88% identical with M.DpnA. However, R.LlalII shared only 31% identity with R.DpnII.

Selection of mutations altering specificity in restriction-modification enzymes using the bacteriophage P22 challenge-phage system

A method for selecting mutants of site-specific DNA-binding proteins has been applied to the study of the EcoRI and RsrI restriction-modification enzymes. Catalytically inactive variants of both endonucleases are shown to function as pseudo-repressors in the bacteriophage P22 challenge-phage assay, and, upon further mutagenesis of the gene encoding R.EcoRI, a variant of that enzyme has been selected which appears to bind EcoRI-methylated GAATTC sequences to the exclusion of unmethylated sites: this specificity is the opposite of that belonging to the native enzyme. Variants of the EcoRI methylase have also been found that lack either catalytic activity or both binding and catalytic activities.

Protein damage and methylation-mediated repair in the erythrocyte

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Regulation of a restriction and modification system via DNA inversion in Mycoplasma pulmonis

An invertible DNA element of 6.8 kb, designated the hsd1 locus, was identified in the chromosome of Mycoplasma pulmonis. Infection of host cells with mycoplasma virus P1 revealed that the organism's restriction and modification (R-M) properties are controlled by inversion of hsd1. The nucleotide sequence of hsd1 revealed several genes, the predicted amino acids of which bear striking similarity to the subunits of the type I R-M enzymes previously found only in enteric bacteria.

DNA-protein interactions. Flip out and modify

The crystal structure of a complex between a methyltransferase and DNA shows that, remarkably, the target cytosine base is swung out of the double helix and located next to the enzyme's S-adenosyl-L-homocysteine cofactor.

Cloning and characterization of a cDNA from Aspergillus parasiticus encoding an O-methyltransferase involved in aflatoxin biosynthesis

Aflatoxins are polyketide-derived secondary metabolites produced by the fungi Aspergillus flavus and Aspergillus parasiticus. Among the catalytic steps in the aflatoxin biosynthetic pathway, the conversion of sterigmatocystin to O-methylsterigmatocystin and the conversion of dihydrosterigmatocystin to dihydro-O-methylsterigmatocystin are catalyzed by an S-adenosylmethionine-dependent O-methyltransferase. A cDNA library was constructed by using RNA isolated from a 24-h-old culture of wild-type A. parasiticus SRRC 143 and was screened by using polyclonal antiserum raised against a purified 40-kDa O-methyltransferase protein. A clone that harbored a full-length cDNA insert (1,460 bp) containing the 1,254-bp coding region of the gene omt-1 was identified by the antiserum and isolated. The complete cDNA sequence was determined, and the corresponding 418-amino-acid sequence of the native enzyme with a molecular weight of 46,000 was deduced. This 46-kDa native enzyme has a leader sequence of 41 amino acids, and the mature form of the enzyme apparently consists of 377 amino acids and has a molecular weight of 42,000. Direct sequencing of the purified mature enzyme from A. parasiticus SRRC 163 showed that 19 of 22 amino acid residues were identical to the amino acid residues in an internal region of the deduced amino acid sequence of the mature protein. The 1,460-bp omt-1 cDNA was cloned into an Escherichia coli expression system; a Western blot (immunoblot) analysis of crude extracts from this expression system revealed a 51-kDa fusion protein (fused with a 5-kDa beta-galactosidase N-terminal fragment).(ABSTRACT TRUNCATED AT 250 WORDS)

Conserved sequence motif DPPY in region IV of the phage T4 Dam DNA-[N6-adenine]-methyltransferase is important for S-adenosyl-L-methionine binding

Comparison of the deduced amino acid sequences of DNA-[N6-adenine]-methyltransferases has revealed several conserved regions. All of these enzymes contain a DPPY [or closely related] motif. By site-directed mutagenesis of a cloned T4 dam gene, we have altered the first proline residue in this motif [located in conserved region IV of the T4 Dam-MTase] to alanine or threonine. The mutant enzymic forms, P172A and P172T, were overproduced and purified. Kinetic studies showed that compared to the wild-type [wt] the two mutant enzymic forms had: (i) an increased [5 and 20-fold, respectively] Km for substrate, S-adenosyl-methionine [AdoMet]; (ii) a slightly reduced [2 and 4-fold lower] kcat; (iii) a strongly reduced kcat/KmAdoMet [10 and 100-fold]; and (iv) almost the same Km for substrate DNA. Equilibrium dialysis studies showed that the mutant enzymes had a reduced [4 and 9-fold lower] Ka for AdoMet. Taken together these data indicate that the P172A and P172T alterations resulted primarily in a reduced affinity for AdoMet. This suggests that the DPPY-motif is important for AdoMet-binding, and that region IV contains or is part of an AdoMet-binding site.

Dam methyltransferase from Escherichia coli: sequence of a peptide segment involved in S-adenosyl-methionine binding

DNA adenine methyltransferase (Dam methylase) has been crosslinked with its cofactor S-adenosyl methionine (AdoMet) by UV irradiation. About 3% of the enzyme was radioactively labelled after the crosslinking reaction performed either with (methyl-3H)-AdoMet or with (carboxy-14C)-AdoMet. Radiolabelled peptides were purified after trypsinolysis by high performance liquid chromatography in two steps. They could not be sequenced due to radiolysis. Therefore we performed the same experiment using non-radioactive AdoMet and were able to identify the peptide modified by the crosslinking reaction by comparison of the separation profiles obtained from two analytical control experiments performed with 3H-AdoMet and Dam methylase without crosslink, respectively. This approach was possible due to the high reproducibility of the chromatography profiles. In these three experiments only one radioactively labelled peptide was present in the tryptic digestions of the crosslinked enzyme. Its sequence was found to be XA-GGK, corresponding to amino acids 10-14 of Dam methylase. The non-identified amino acid in the first sequence cycle should be a tryptophan, which is presumably modified by the crosslinking reaction. The importance of this region near the N-terminus for the structure and function of the enzyme was also demonstrated by proteolysis and site-directed mutagenesis experiments.

Cloning and sequences of the genes encoding the CfrBI restriction-modification system from Citrobacter freundii

The genes encoding the CfrBI restriction and modification (R-M) systems from Citrobacter freundii and recognizing the sequence 5'-CCWWGG-3' (W = A or T) were cloned in Escherichia coli McrBC- cells. The nucleotide (nt) sequences of the genes were determined. Two large open reading frames were found. Deletion analysis showed that one of them [1128 nt coding for 376 amino acids (aa)] corresponds to a methyltransferase (MTase)-encoding gene and the other (1065 nt coding for 355 aa) to a restriction endonuclease-encoding gene. The genes are oriented divergently and separated by 76 bp. A CfrBI site (5'-m4CCATGG) was found in the intergenic region of the cfrBIRM genes. Analysis of the deduced aa sequence of M.CfrBI made it possible to determine the typical features of a m4C-specific MTase. Limited homology between the M.CfrBI and R.CfrBI proteins was also found.

The role of the preserved sequences of Dam methylase

We have undertaken a site directed mutational analysis of two of the preserved regions in the amino acid sequence of Dam methylase in order to characterize their role. Mutations in region IV (sequence DPPY) abolish catalytic activity and greatly affect AdoMet crosslinking. Mutants in region III display a lowered specific activity with an unchanged AdoMet crosslinking capacity. We have also made a series of deletions both at the N and C terminal parts of the protein, which have been found to provide inactive enzyme. We discuss the significance of these results for the understanding of the functional properties of the enzyme.

Identification of nodSUIJ genes in Nod locus 1 of Azorhizobium caulinodans: evidence that nodS encodes a methyltransferase involved in Nod factor modification

The Azorhizobium caulinodans strain ORS571 nodulation genes nodSUIJ were located downstream from nodABC. Complementation data and transcriptional analysis suggest that nodABCSUIJ form a single operon. Mutants with Tn5 insertions in the genes nodS, nodU, and nodJ were delayed in nodulation of Sesbania rostrata roots and stems. The NodS amino acid sequences of ORS571, Bradyrhizobium japonicum, and Rhizobium sp. strain NGR234, contain a consensus with similarity to S-adenosylmethionine (SAM)-utilizing methyltransferases. A naringenin-inducible nodS-dependent protein of approximately 25 kDa could be cross-linked to radiolabelled SAM. By applying L-[methyl-3H]-methionine in vivo, Nod factors of ORS571, known to be N-methylated, could be labelled in wild type and nodU mutants but not in nodS mutants. Therefore, we propose that NodS is a SAM-utilizing methyltransferase involved in Nod factor synthesis.

Biology of DNA restriction

Our understanding of the evolution of DNA restriction and modification systems, the control of the expression of the structural genes for the enzymes, and the importance of DNA restriction in the cellular economy has advanced by leaps and bounds in recent years. This review documents these advances for the three major classes of classical restriction and modification systems, describes the discovery of a new class of restriction systems that specifically cut DNA carrying the modification signature of foreign cells, and deals with the mechanisms developed by phages to avoid the restriction systems of their hosts.

Gene structure and expression of the MboI restriction--modification system

The genes from Moraxella bovis encoding the MboI restriction--modification system were cloned and expressed in Escherichia coli. Three open reading frames were found in the sequence containing the genes. These genes, which we named mboA, mboB, and mboC, had the same orientation in the genome. Genes mboA and mboC encoded MboI methyltransferases (named M.MboA and M.MboC) with 294 and 273 amino acid residues, respectively. The mboB gene coded for MboI restriction endonuclease (R.MboI) with 280 amino acid residues. Recombinant E.coli-MBOI, which contained the whole MboI system, overproduced R.MboI. R.MboI activity from E.coli-MBOI was 480-fold that of M.bovis. The amino acid sequences deduced from these genes were compared with those of other restriction--modification systems. The protein sequences of the MboI system had 38-49% homology with those of the DpnII system.

Determination of the order of substrate addition to MspI DNA methyltransferase using a novel mechanism-based inhibitor

The cloning and overexpression of the MspI DNA methyltransferase as a functional fusion with glutathione S-transferase is described. The fusion enzyme retains full biological activity and has been used to investigate the interaction of substrates and inhibitors with MspI DNA methyltransferase. The fusion enzyme has been purified to homogeneity in a single step on GSH-agarose and is free from contaminating exonuclease activity. The enzyme can be photolabelled with S-adenosyl-L-methionine and the level of incorporation of label is enhanced by the presence of a nonspecific DNA duplex. In the presence of a cognate oligodeoxynucleotide, no photolabelling was observed since methyl transfer occurs instead. The inclusion of a mechanism-based inhibitor of C-5 deoxycytidine DNA methylation (an oligodeoxynucleotide containing the base 2-pyrimidinone-1-beta-D-2'-deoxyribofuranoside in the position of the deoxycytidine to which methyl addition occurs), which is thought to form a covalent interaction with the reactive cysteine of such enzymes, led to an enhancement of S-adenosyl-L-methionine photolabelling which suggests that, in contrast with results obtained with EcoRII DNA methyltransferase [Som and Friedman (1991) J. Biol. Chem. 266, 2937-2945], methylcysteine is not the photolabelled product. The implications of the results obtained with this mechanism-based inhibitor are discussed with respect to other C-5-specific DNA methyltransferases. Gel-retardation assays in the presence of cognate oligodeoxynucleotides that contain the reactive pyrimidinone base in place of the deoxycytidine target base are described. These demonstrate that most probably a stable covalent bond is formed between the methyltransferase and this oligodeoxynucleotide. However, the alternative of extremely tight non-covalent binding cannot be rigorously excluded. Furthermore, the results from these experiments indicate that the reaction mechanism proceeds in a manner similar to that of HhaI DNA methyltransferase with sequence-specific DNA binding being followed by addition of S-adenosyl-L-methionine and concomitant isomerization of the ternary complex leading to methyl transfer. S-Adenosyl-L-homocysteine appears to inhibit the reaction pathway as a result of either competition with the methyl donor and potentiation of a high-affinity interaction between the enzyme and DNA in an abortive ternary complex or through an allosteric interaction.

Sequence motifs common to the EcoRII restriction endonuclease and the proposed sequence specificity domain of three DNA-[cytosine-C5] methyltransferases

We have compared the deduced amino acid (aa) sequences of the EcoRII restriction endonuclease (R.EcoRII) and the proposed specificity (target recognition) domains of three DNA-[cytosine-C5] methyltransferases (MTases), M.EcoRII, M.Dcm, and M.SPR, each of which recognizes the same nucleotide sequence, CCWGG (where W is A or T). We have identified a region containing sequence motifs that are partially conserved in the MTases and R.EcoRII. This may be the first example of aa sequence homology between a MTase specificity (target recognition) domain and its cognate restriction endonuclease (ENase). It suggests that this region is important for DNA recognition by R.EcoRII and that the EcoRII ENase and MTase genes may have evolved from a common progenitor.

Molecular characterization of the enniatin synthetase gene encoding a multifunctional enzyme catalysing N-methyldepsipeptide formation in Fusarium scirpi

The gene encoding the multifunctional enzyme enniatin synthetase from Fusarium scirpi (esyn1) was isolated and characterized by transcriptional mapping and expression studies in Escherichia coli. This is the first example of a gene encoding an N-methyl peptide synthetase. The nucleotide sequence revealed an open reading frame of 9393 bp encoding a protein of 3131 amino acids (M(r) 346,900). Two domains designated EA and EB within the protein were identified which share similarity to each other and to microbial peptide synthetase domains. In contrast to the N-terminal domain EA, the carboxyl terminal domain EB is interrupted by a 434-amino-acid portion which shows local similarity to a motif apparently conserved within adenine and cytosine RNA and DNA methyltransferases and therefore seems to harbour the N-methyl-transferase function of the multienzyme.

Analysis of the nucleotide and derived amino acid sequences of the SsoII restriction endonuclease and methyltransferase

A 2648-bp fragment from the P4 plasmid of Shigella sonnei strain 47 coding for the SsoII restriction endonuclease (ENase) and methyltransferase (MTase) (recognition sequence 5'-CCNGG) was sequenced. Two divergently arranged open reading frames of 905 bp for the SsoII ENase (R.SsoII) and 1137 bp for the MTase (M.SsoII) were identified. The coding regions are separated by 110 bp. The calculated M(r) of R.SsoII (35937) and M.SsoII (42887) are in good agreement with values previously obtained by in vitro transcription-translation experiments, i.e., 35 and 43 kDa for the ENase and MTase, respectively. The M.SsoII amino acid (aa) sequence revealed a considerable similarity to m5C-MTases recognizing the related sequences--M.EcoRII, M.dcm, M.MspI, M.BsuFI, M.HpaII, and M.HhaI. Surprisingly, the greatest degree of homology has been observed between the aa sequences of M.SsoII and M.NlaX, with an unidentified recognition sequence. The multiple alignment of aa sequences helps to identify the blocks of conserved aa in variable regions of MTases. These conserved aa can play a key role in target recognition. Some aspects of evolution of m5C-MTases are discussed.

Purification of a 40-kilodalton methyltransferase active in the aflatoxin biosynthetic pathway

The penultimate step in the aflatoxin biosynthetic pathway of the filamentous fungi Aspergillus flavus and A. parasiticus involves conversion of sterigmatocystin to O-methylsterigmatocystin. An S-adenosylmethionine-dependent methyltransferase that catalyzes this reaction was purified to homogeneity (> 90%) from 78-h-old mycelia of A. parasiticus SRRC 163. Purification of this soluble enzyme was carried out by five soft-gel chromatographic steps: cell debris remover treatment, QMA ACELL chromatography, hydroxylapatite-Ultrogel chromatography, DEAE-Spherodex chromatography, and Octyl Avidgel chromatography, followed by MA7Q high-performance liquid chromatography. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the protein peak from this step on silver staining identified a single band of approximately 40 kDa. This purified protein was distinct from the dimeric 168-kDa methyltransferase purified from the same fungal strain under identical growth conditions (D. Bhatnagar, A. H. J. Ullah, and T. E. Cleveland, Prep. Biochem. 18:321-349, 1988). The chromatographic behavior and N-terminal sequence of the 40-kDa enzyme were also distinct from those of the 168-kDa methyltransferase. The molar extinction coefficient of the 40-kDa enzyme at 278 nm was estimated to be 4.7 x 10(4) M-1 cm-1 in 50 mM potassium phosphate buffer (pH 7.5).

Mammalian small molecule methyltransferases: their structural and functional features

Structural and functional features of mammalian S-adenosyl-methionine-dependent small molecule methyltransferases are reviewed. The methyltransferases have similar protomer molecular weights in the range of 25,000-35,000. Two common sequence motifs are found in all enzymes of known sequence. Whereas the kinetic mechanisms may be different, the methyltransferases in the free form bind S-adenosylmethionine. Most, if not all, of mammalian small molecule methyltransferases appear to have vicinal thiols in a catalytically important area of the enzyme.