Comprehensive analysis of regulation of DNA methyltransferase isoforms in human breast tumors

Significant reprogramming of epigenome is widely described during pathogenesis of breast cancer. Transformation of normal cell to hyperplastic cell and to neoplastic phenotype is associated with aberrant DNA (de)methylation, which, through promoter and enhancer methylation changes, activates oncogenes and silence tumor suppressor genes in variety of tumors including breast. DNA methylation, one of the major epigenetic mechanisms is catalyzed by evolutionarily conserved isoforms namely, DNMT1, DNMT3A and DNMT3B in humans. Over the years, studies have demonstrated intricate and complex regulation of DNMT isoforms at transcriptional, translational and post-translational levels. The recent findings of allosteric regulation of DNMT isoforms and regulation by other interacting chromatin modifying proteins emphasizes functional integrity and their contribution for the development of breast cancer and progression. DNMT isoforms are regulated by several intrinsic and extrinsic parameters. In the present review, we have extensively performed bioinformatics analysis of expression of DNMT isoforms along with their transcriptional and post-transcriptional regulators such as transcription factors, interacting proteins, hormones, cytokines and dietary elements along with their significance during pathogenesis of breast tumors. Our review manuscript provides a comprehensive understanding of key factors regulating DNMT isoforms in breast tumor pathology and documents unsolved issues.

A novel Cas9-targeted long-read assay for simultaneous detection of IDH1/2 mutations and clinically relevant MGMT methylation in fresh biopsies of diffuse glioma

Molecular biomarkers provide both diagnostic and prognostic results for patients with diffuse glioma, the most common primary brain tumor in adults. Here, we used a long-read nanopore-based sequencing technique to simultaneously assess IDH mutation status and MGMT methylation level in 4 human cell lines and 8 fresh human brain tumor biopsies. Currently, these biomarkers are assayed separately, and results can take days to weeks. We demonstrated the use of nanopore Cas9-targeted sequencing (nCATS) to identify IDH1 and IDH2 mutations within 36 h and compared this approach against currently used clinical methods. nCATS was also able to simultaneously provide high-resolution evaluation of MGMT methylation levels not only at the promoter region, as with currently used methods, but also at CpGs across the proximal promoter region, the entirety of exon 1, and a portion of intron 1. We compared the methylation levels of all CpGs to MGMT expression in all cell lines and tumors and observed a positive correlation between intron 1 methylation and MGMT expression. Finally, we identified single nucleotide variants in 3 target loci. This pilot study demonstrates the feasibility of using nCATS as a clinical tool for cancer precision medicine.

Genome-wide identification, evolution of DNA methyltransferases and their expression during gonadal development in Nile tilapia

DNA methyltransferases (dnmts) are responsible for DNA methylation and play important roles in organism development. In this study, seven dnmts genes (dnmt1, dnmt2, dnmt3aa, dnmt3ab, dnmt3ba, dnmt3bb.1, dnmt3bb.2) were identified in Nile tilapia. Comprehensive analyses of dnmts were performed using available genome databases from representative animal species. Phylogenetic analysis revealed that the dnmts family were highly conserved in teleosts. Based on transcriptome data from eight adult tilapia tissues, the dnmts were found to be dominantly expressed in the head kidney, testis and ovary. Analyses of the gonadal transcriptome data in different developmental stages revealed that all dnmts were expressed in both ovary and testis, and four de novo dnmts (dnmt3aa, dnmt3ab, dnmt3bb.1, dnmt3bb.2) showed higher expression in the testis than in the ovary. Furthermore, during sex reversal induced by Fadrozole, the expression of these four de novo dnmts increased significantly in treated group compared to female control group. By in situ hybridization, the seven dnmts were found to be expressed mainly in phase I and II oocytes of the ovary and spermatocytes of the testis. When gonads were incubated with a methyltransferase inhibitor (5-AzaCdR) in vitro, the expression of dnmts genes were down-regulated significantly, while the expression of cyp19a1a (a key gene in female pathway) and dmrt1 (a key gene in male pathway) increased significantly. Our results revealed the conservation of dnmts during evolution and indicated a potential role of dnmts in epigenetic regulation of gonadal development.

DNA Labeling Using DNA Methyltransferases

DNA methyltransferases (MTases) uniquely combine the ability to recognize and covalently modify specific target sequences in DNA using the ubiquitous cofactor S-adenosyl-L-methionine (AdoMet). Although DNA methylation plays important roles in biological signaling, the transferred methyl group is a poor reporter and is highly inert to further biocompatible derivatization. To unlock the biotechnological power of these enzymes, two major types of cofactor AdoMet analogs were developed that permit targeted MTase-directed attachment of larger moieties containing functional or reporter groups onto DNA. One such approach (named sequence-specific methyltransferase-induced labeling, SMILing) uses reactive aziridine or N-mustard mimics of the cofactor AdoMet, which render targeted coupling of a whole cofactor molecule to the target DNA. The second approach (methyltransferase-directed transfer of activated groups, mTAG) uses AdoMet analogs with a sulfonium-bound extended side chain replacing the methyl group, which permits MTase-directed covalent transfer of the activated side chain alone. As the enlarged cofactors are not always compatible with the active sites of native MTases, steric engineering of the active site has been employed to optimize their alkyltransferase activity. In addition to the described cofactor analogs, recently discovered atypical reactions of DNA cytosine-5 MTases involving non-cofactor-like compounds can also be exploited for targeted derivatization and labeling of DNA. Altogether, these approaches offer new powerful tools for sequence-specific covalent DNA labeling, which not only pave the way to developing a variety of useful techniques in DNA research, diagnostics, and nanotechnologies but have already proven practical utility for optical DNA mapping and epigenome studies.

Saccharomyces cerevisiae Eukaryotic Elongation Factor 1A (eEF1A) Is Methylated at Lys-390 by a METTL21-Like Methyltransferase

The human methyltransferases (MTases) METTL21A and VCP-KMT (METTL21D) were recently shown to methylate single lysine residues in Hsp70 proteins and in VCP, respectively. The yet uncharacterized MTase encoded by the YNL024C gene in Saccharomyces cerevisiae shows high sequence similarity to METTL21A and VCP-KMT, as well as to their uncharacterized paralogues METTL21B and METTL21C. Despite being most similar to METTL21A, the Ynl024c protein does not methylate yeast Hsp70 proteins, which were found to be unmethylated on the relevant lysine residue. Eukaryotic translation elongation factor eEF1A in yeast has been reported to contain four methylated lysine residues (Lys30, Lys79, Lys318 and Lys390), and we here show that the YNL024C gene is required for methylation of eEF1A at Lys390, the only of these methylations for which the responsible MTase has not yet been identified. Lys390 was found in a partially monomethylated state in wild-type yeast cells but was exclusively unmethylated in a ynl024cΔ strain, and over-expression of Ynl024c caused a dramatic increase in Lys390 methylation, with trimethylation becoming the predominant state. Our results demonstrate that Ynl024c is the enzyme responsible for methylation of eEF1A at Lys390, and in accordance with prior naming of similar enzymes, we suggest that Ynl024c is renamed to Efm6 (Elongation factor MTase 6).

[Bioinformatic analysis of potential post-translational modification sites of the human O6-methylguanine-DNA methyltransferase (MGMT) protein]

Using in silico analysis a number of potential sites for post-translational modifications has been revealed within the human O6-methylguanine-DNA methyltransferase (MGMT) protein. In particular these were the acetylation of Gly3 residue in the N-terminus of protein and internal residues Lys132 and Lys135; Arg166 residue methylation; Lys63 SUMOylation and ubiquitination of Lys31, Lys39, Lys49, Lys63, Lys67, Lys135, Lys156, Lys196, Lys209. Also it has been predicted 16 novel potential phosphorylation sites of serine residues (positions 13, 124, 144, 182, 183, 190, 215, 216 and 230), tyrosine residues (positions 100 and 189) and threonine residues (positions 23, 69, 94, 126 and 229), as well as five binding sites for kinases and other proteins (Serl3 with 14-3-3, Val21 and Ile172 with D-domain, Pro78 and Pro111 with SH3-domain, Pro111 with MAPK3). Some kinases predicted by the authors are known as partners of the MGMT protein, that confirms the probability of modification of the given sites. Potential sites require further experimental confirmation of modifications and investigation of their influence on stability and DNA-repair activity of this protein.

Protein and nucleic acid methylating enzymes: mechanisms and regulation

Protein and nucleic acid methylating enzymes are implicated in myriad cellular processes. These enzymes utilize diverse chemical mechanisms ranging from nucleophilic substitution-displacement to a novel radical-based reaction found in bacterial iron-sulfur cluster proteins. Within the cell, methylation activity is governed by interactions with endogenous molecular machinery. Of particular interest are the observations that methylating enzyme activity can be allosterically controlled by regulatory binding partners. Recent advances and emerging trends in the study of methylating enzyme mechanisms and regulation highlight the importance of protein and nucleic acid methylation in cellular physiology and disease.

The mammalian de novo DNA methyltransferases DNMT3A and DNMT3B are also DNA 5-hydroxymethylcytosine dehydroxymethylases

For cytosine (C) demethylation of vertebrate DNA, it is known that the TET proteins could convert 5-methyl C (5-mC) to 5-hydroxymethyl C (5-hmC). However, DNA dehydroxymethylase(s), or enzymes able to directly convert 5-hmC to C, have been elusive. We present in vitro evidence that the mammalian de novo DNA methyltransferases DNMT3A and DNMT3B, but not the maintenance enzyme DNMT1, are also redox-dependent DNA dehydroxymethylases. Significantly, intactness of the C methylation catalytic sites of these de novo enzymes is also required for their 5-hmC dehydroxymethylation activity. That DNMT3A and DNMT3B function bidirectionally both as DNA methyltransferases and as dehydroxymethylases raises intriguing and new questions regarding the structural and functional aspects of these enzymes and their regulatory roles in the dynamic modifications of the vertebrate genomes during development, carcinogenesis, and gene regulation.

Near-infrared fluorescence imaging of mammalian cells and xenograft tumors with SNAP-tag

Fluorescence in the near-infrared (NIR) spectral region is suitable for in vivo imaging due to its reduced background and high penetration capability compared to visible fluorescence. SNAP(f) is a fast-labeling variant of SNAP-tag that reacts with a fluorescent dye-conjugated benzylguanine (BG) substrate, leading to covalent attachment of the fluorescent dye to the SNAP(f). This property makes SNAP(f) a valuable tool for fluorescence imaging. The NIR fluorescent substrate BG-800, a conjugate between BG and IRDye 800CW, was synthesized and characterized in this study. HEK293, MDA-MB-231 and SK-OV-3 cells stably expressing SNAP(f)-Beta-2 adrenergic receptor (SNAP(f)-ADRβ2) fusion protein were created. The ADRβ2 portion of the protein directs the localization of the protein to the cell membrane. The expression of SNAP(f)-ADRβ2 in the stable cell lines was confirmed by the reaction between BG-800 substrate and cell lysates. Microscopic examination confirmed that SNAP(f)-ADRβ2 was localized on the cell membrane. The signal intensity of the labeled cells was dependent on the BG-800 concentration. In vivo imaging study showed that BG-800 could be used to visualize xenograph tumors expressing SNAP(f)-ADRβ2. However, the background signal was relatively high, which may be a reflection of non-specific accumulation of BG-800 in the skin. To address the background issue, quenched substrates that only fluoresce upon reaction with SNAP-tag were synthesized and characterized. Although the fluorescence was successfully quenched, in vivo imaging with the quenched substrate CBG-800-PEG-QC1 failed to visualize the SNAP(f)-ADRβ2 expressing tumor, possibly due to the reduced reaction rate. Further improvement is needed to apply this system for in vivo imaging.

[A new DNA methyltransferase M.BstC8I forms 5'-G(M5C)NNGC-3'. Studying of restriction endonuclease sensitivity to M.BstC8I-methylation]

Bacillus stearothermophilus C8 was grown up on the Luria agar at 37 degrees C. A new DNA-methylase was determined in cellular lysate. The methylation of the DNAs of bacteriophages lambda and T7 in the region of 5'-G(m5C)NNGC-3' blocked the activity of BstC8I. Specificity of M.BstC8I was analyzed on methylated lambda DNA. For this purpose, we used computer modeling and the data on the sensitivity of restrictases BstC8I, BsuRI, AjnI, and PvuII to methylation. The sensitivity of some restrictases to new methylation was studied. The results may be used for DNA methylation studying.

Targeted DNA methylation by a DNA methyltransferase coupled to a triple helix forming oligonucleotide to down-regulate the epithelial cell adhesion molecule

The epithelial cell adhesion molecule (EpCAM) is a membrane glycoprotein that has been identified as a marker of cancer-initiating cells. EpCAM is highly expressed on most carcinomas, and transient silencing of EpCAM expression leads to reduced oncogenic potential. To silence the EpCAM gene in a persistent manner via targeted DNA methylation, a low activity mutant (C141S) of the CpG-specific DNA methyltransferase M.SssI was coupled to a triple-helix-forming oligonucleotide (TFO-C141S) specifically designed for the EpCAM gene. Reporter plasmids encoding the green fluorescent protein under control of different EpCAM promoter fragments were treated with the TFO-C141S conjugate to determine the specificity of targeted DNA methylation in the context of a functional EpCAM promoter. Treatment of the plasmids with TFO-C141S resulted in efficient and specific methylation of the targeted CpG located directly downstream of the triple helix forming site (TFS). No background DNA methylation was observed neither in a 700 bp region of the EpCAM promoter nor in a 400 bp region of the reporter gene downstream of the TFS. Methylation of the target CpG did not have a detectable effect on promoter activity. This study shows that the combination of a specific TFO and a reduced activity methyltransferase variant can be used to target DNA methylation to predetermined sites with high specificity, allowing determination of crucial CpGs for promoter activity.

[Recombinant DNA-methyltransferase M1.Bst19I from Bacillus stearothermophilus 19: purification, propeties and amino acids sequence analysis]

The M1.Bst19I DNA-methyltransferase gene from restriction-modification system Bst19I (recognition sequence 5'-GCATC-3') in Bacillus stearothermophilus 19 has been cloned in the expressing vector pJW, that carries a tandem of thermo inducible promoters P(R)/P(L) from phage lambda. Highly purified enzyme has been isolated by chromatography on various resins from E. coli cells where it accumulates in a soluble form. Study of M1.Bst19I properties has revealed that enzyme has a temperature optimum 50 degrees C and demonstrates the maximum activity at pH 8.0. M1.Bst19I modifies adenine in sequence 5'-GCATC-3'. Kinetic parameters of M1.Bst19I DNA methylation reaction have been determined as follows: Km for lambda DNA is 0.68 +/- 0.07 microM, Km for S-adenosil-L-methionine is 2.02 +/- 0.31 microM. Catalytical constant (kcat) is 1.8 +/- 0.05 min(-1). Comparative analysis of Target Recognition Domain amino acid sequences for M1.Bst19I and others alpha-N6-DNA methyltransferases has allowed to suppose a presence of two types of the enzymes containing a triplet ATG or ATC in the recognition sequence.

Purification and characterization of rice DNA methyltransferase

Epigenetic modification is essential for normal development and plays important roles in gene regulation in higher plants. Multiple factors interact to regulate the establishment and maintenance of DNA methylation in plant genome. We had previously cloned and characterized DNA methyltransferase (DNA MTase) gene homologues (OsMET1) from rice. In this present study, determination of DNA MTase activity in different cellular compartments showed that DNA MTase was enriched in nuclei and the activity was remarkably increased during imbibing dry seeds. We had optimized the purification technique for DNA MTase enzyme from shoots of 10-day-old rice seedlings using the three successive chromatographic columns. The Econo-Pac Q, the Hitrap-Heparin and the Superdex-200 columns yielded a protein fraction of a specific activity of 29, 298 and 800 purification folds, compared to the original nuclear extract, respectively. The purified protein preferred hemi-methylated DNA substrate, suggesting the maintenance activity of methylation. The native rice DNA MTase was approximately 160-170 kDa and exhibited a broad pH optimum in the range of 7.6 and 8.0. The enzyme kinetics and inhibitory effects by methyl donor analogs, base analogs, cations, and cationic amines on rice DNA MTase were examined. Global cytosine methylation status of rice genome during development and in various tissue culture systems were monitored and the results suggested that the cytosine methylation level is not directly correlated with the DNA MTase activity. The purification and characterization of rice DNA MTase enzyme are expected to enhance our understanding of this enzyme function and their possible contributions in Gramineae plant development.

[Synthesis and characteristics of modified DNA fragments containing thymidine glycol residues]

Chemical synthesis of a series of modified oligodeoxyribonucleotides containing one or two residues of thymidine glycol (5,6-dihydro-5,6-dihydroxythymidine), the main product of oxidative DNA damage, is described. The thermal stability of DNA duplexes containing thymidine glycol residues was studied using UV spectroscopy. Introduction of even one thymidine glycol residue into the duplex structure was shown to result in its significant destabilization. Data on the interaction of DNA methyltransferases and type II restriction endonucleases with DNA ligands containing oxidized thymine were obtained for the first time. Introduction of a thymidine glycol residue into the central degenerate position of the recognition site of restriction endonuclease SsoII was found to result in an increase in the initial hydrolysis rate of the modified duplex in comparison with that of the unmodified structure. The affinity of C5-cytosine methyltransferase SsoII for the DNA duplex bearing thymidine glycol was found to be twofold higher than for the unmodified substrate. However, such a modification of the DNA ligand prevents its methylation. The English version of the paper: Russian Journal of Bioorganic Chemistry, 2008, vol. 34, no. 2; see also http://www.maik.ru.

Isolation and expression analysis of genes encoding MET, CMT, and DRM methyltransferases in oil palm (Elaeis guineensis Jacq.) in relation to the 'mantled' somaclonal variation

In oil palm (Elaeis guineensis Jacq.), approximately 5% of somatic embryo-derived regenerants show homeotic changes during floral development, involving an apparent feminization of male parts in flowers of both sexes, called the 'mantled' phenotype. This variant phenotype is associated with a reduction in the level of global DNA methylation. To explore possible relationships between DNA methylation level and accumulation of DNA-(cytosine-5) methyltransferase (DNMT) transcripts, the full-length coding sequences corresponding to three different DNMT families in oil palm, namely the MET, CMT, and DRM classes, have been isolated and characterized. The corresponding genes were designated as EgMET1, EgCMT1, and EgDRM1, and encode predicted polypeptides of 1543, 925, and 591 amino acid residues, respectively. Expression of oil palm DNMTs was compared between normal and variant calli and inflorescence tissues using quantitative reverse-transcription PCR. A consistent increase in transcript levels of EgMET1 and EgCMT1 was found in variant fast-growing calli relative to nodular-compact calli. Nodular-compact calli give rise to about 5% of abnormal regenerants whereas fast-growing calli generate 95% of 'mantled' palms in their clonal offspring and were previously demonstrated as having markedly hypomethylated DNA. In immature abnormal inflorescences only EgMET1 transcript levels were increased, while no changes in relative abundance of the EgCMT1 or EgDRM1 transcripts were observed. Therefore, the genome-wide hypomethylation previously described in 'mantled' material cannot be explained by a decrease in expression levels of the de novo or maintenance DNMTs, a paradox which has been previously reported in tumour cells, where there is evidence for global hypomethylation of DNA.

Mammalian DNA methyltransferases: a structural perspective

The methylation of mammalian DNA, primarily at CpG dinucleotides, has long been recognized to play a major role in controlling gene expression, among other functions. Given their importance, it is surprising how many basic questions remain to be answered about the proteins responsible for this methylation and for coordination with the parallel chromatin-marking system that operates at the level of histone modification. This article reviews recent studies on, and discusses the resulting biochemical and structural insights into, the DNA nucleotide methyltransferase (Dnmt) proteins 1, 3a, 3a2, 3b, and 3L.

The methyltransferase YfgB/RlmN is responsible for modification of adenosine 2503 in 23S rRNA

A2503 in 23S rRNA of the gram-negative bacterium Escherichia coli is located in a functionally important region of the ribosome, at the entrance to the nascent peptide exit tunnel. In E. coli, and likely in other species, this adenosine residue is post-transcriptionally modified to m2A. The enzyme responsible for this modification was previously unknown. We identified E. coli protein YfgB, which belongs to the radical SAM enzyme superfamily, as the methyltransferase that modifies A2503 of 23S rRNA to m2A. Inactivation of the yfgB gene in E. coli led to the loss of modification at nucleotide A2503 of 23S rRNA as revealed by primer extension analysis and thin layer chromatography. The A2503 modification was restored when YfgB protein was expressed in the yfgB knockout strain. A similar protein was shown to catalyze post-transcriptional modification of A2503 in 23S rRNA in gram-positive Staphylococcus aureus. The yfgB knockout strain loses in competition with wild type in a co-growth experiment, indicating functional importance of A2503 modification. The location of A2503 in the exit tunnel suggests its possible involvement in interaction with the nascent peptide and raises the possibility that its post-transcriptional modification may influence such an interaction.

Identification of yeast tRNA Um(44) 2'-O-methyltransferase (Trm44) and demonstration of a Trm44 role in sustaining levels of specific tRNA(Ser) species

A characteristic feature of tRNAs is the numerous modifications found throughout their sequences, which are highly conserved and often have important roles. Um(44) is highly conserved among eukaryotic cytoplasmic tRNAs with a long variable loop and unique to tRNA(Ser) in yeast. We show here that the yeast ORF YPL030w (now named TRM44) encodes tRNA(Ser) Um(44) 2'-O-methyltransferase. Trm44 was identified by screening a yeast genomic library of affinity purified proteins for activity and verified by showing that a trm44-delta strain lacks 2'-O-methyltransferase activity and has undetectable levels of Um(44) in its tRNA(Ser) and by showing that Trm44 purified from Escherichia coli 2'-O-methylates U(44) of tRNA(Ser) in vitro. Trm44 is conserved among metazoans and fungi, consistent with the conservation of Um(44) in eukaryotic tRNAs, but surprisingly, Trm44 is not found in plants. Although trm44-delta mutants have no detectable growth defect, TRM44 is required for survival at 33 degrees C in a tan1-delta mutant strain, which lacks ac(4)C12 in tRNA(Ser) and tRNA(Leu). At nonpermissive temperature, a trm44-delta tan1-delta mutant strain has reduced levels of tRNA(Ser(CGA)) and tRNA(Ser(UGA)), but not other tRNA(Ser) or tRNA(Leu) species. The trm44-delta tan1-delta growth defect is suppressed by addition of multiple copies of tRNA(Ser(CGA)) and tRNA(Ser(UGA)), directly implicating these tRNA(Ser) species in this phenotype. The reduction of specific tRNA(Ser) species in a trm44-delta tan1-delta mutant underscores the importance of tRNA modifications in sustaining tRNA levels and further emphasizes that tRNAs undergo quality control.

Kinetic analysis of Yersinia pestis DNA adenine methyltransferase activity using a hemimethylated molecular break light oligonucleotide

Background

DNA adenine methylation plays an important role in several critical bacterial processes including mismatch repair, the timing of DNA replication and the transcriptional control of gene expression. The dependence of bacterial virulence on DNA adenine methyltransferase (Dam) has led to the proposal that selective Dam inhibitors might function as broad spectrum antibiotics.

Methodology/Principal Findings

Herein we report the expression and purification of Yersinia pestis Dam and the development of a continuous fluorescence based assay for DNA adenine methyltransferase activity that is suitable for determining the kinetic parameters of the enzyme and for high throughput screening against potential Dam inhibitors. The assay utilised a hemimethylated break light oligonucleotide substrate containing a GATC methylation site. When this substrate was fully methylated by Dam, it became a substrate for the restriction enzyme DpnI, resulting in separation of fluorophore (fluorescein) and quencher (dabcyl) and therefore an increase in fluorescence. The assays were monitored in real time using a fluorescence microplate reader in 96 well format and were used for the kinetic characterisation of Yersinia pestis Dam, its substrates and the known Dam inhibitor, S-adenosylhomocysteine. The assay has been validated for high throughput screening, giving a Z-factor of 0.71±0.07 indicating that it is a sensitive assay for the identification of inhibitors.

Conclusions/Significance

The assay is therefore suitable for high throughput screening for inhibitors of DNA adenine methyltransferases and the kinetic characterisation of the inhibition.

Alkyltransferase-like proteins

Recent in silico analysis has revealed the presence of a group of proteins in pro and lower eukaryotes, but not in Man, that show extensive amino acid sequence similarity to known O(6)-alkylguanine-DNA alkyltransferases, but where the cysteine at the putative active site is replaced by another residue, usually tryptophan. Here we review recent work on these proteins, which we designate as alkyltransferase-like (ATL) proteins, and consider their mechanism of action and role in protecting the host organisms against the biological effects of O(6)-alkylating agents, and their evolution. ATL proteins from Escherichia coli (eAtl, transcribed from the ybaz open reading frame) and Schizosaccharomyces pombe (Atl1) are able to bind to a range of O(6)-alkylguanine residues in DNA and to reversibly inhibit the action of the human alkyltransferase (MGMT) upon these substrates. Isolated proteins were not able to remove the methyl group in O(6)-methylguanine-containing DNA or oligonucleotides, neither did they display glycosylase or endonuclease activity. S. pombe does not contain a functional alkyltransferase and atl1 inactivation sensitises this organism to a variety of alkylating agents, suggesting that Atl1 acts by binding to O(6)-alkylguanine lesions and signalling them for processing by other DNA repair pathways. Currently we cannot exclude the possibility that ATL proteins arose through independent mutation of the alkyltransferase gene in different organisms. However, analyses of the proteins from E. coli and S. pombe, are consistent with a common function.

Genetic association and functional studies of major polymorphic variants of MGMT

The DNA repair protein, O(6)-methylguanine DNA-methyltransferase (MGMT) prevents mutations and cell death that result from aberrant alkylation of DNA. The polymorphic variants Leu84Phe, Ile143Val, and Lys178Arg are frequent in the human population. We review here studies of these and other MGMT polymorphisms and their association with risk for lung, breast, colorectal and endometrial cancer with a consideration of gene-environment interactions. In addition, we review studies of the effects of polymorphic variation on alkyltransferase activity and expression. It is formally possible that polymorphic variation could modify functions of MGMT other than its alkyltransferase activity. While it was previously reported that an alkylated form of MGMT modifies Estrogen Receptor alpha activity, from our studies we conclude that this regulation is not a major function of MGMT. Overall, the effects of polymorphic variation on protein function are subtle, and further investigation is required to provide a comprehensive mechanism that explains the observed associations of these variants with risk for cancer.

Shape and subunit organisation of the DNA methyltransferase M.AhdI by small-angle neutron scattering

Type I restriction-modification (R-M) systems encode multisubunit/multidomain enzymes. Two genes (M and S) are required to form the methyltransferase (MTase) that methylates a specific base within the recognition sequence and protects DNA from cleavage by the endonuclease. The DNA methyltransferase M.AhdI is a 170 kDa tetramer with the stoichiometry M(2)S(2) and has properties typical of a type I MTase. The M.AhdI enzyme has been prepared with deuterated S subunits, to allow contrast variation using small-angle neutron scattering (SANS) methods. The SANS data were collected in a number of (1)H:(2)H solvent contrasts to allow matching of one or other of the subunits in the multisubunit enzyme. The radius of gyration (R(g)) and maximum dimensions (D(max)) of the M subunits in situ in the multisubunit enzyme (50 A and 190 A, respectively) are close of those of the entire MTase (51 A and 190 A). In contrast, the S subunits in situ have experimentally determined values of R(g)=35 A and D(max)=110 A, indicating their more central location in the enzyme. Ab initio reconstruction methods yield a low-resolution structural model of the shape and subunit organization of M.AhdI, in which the Z-shaped structure of the S subunit dimer can be discerned. In contrast, the M subunits form a much more elongated and extended structure. The core of the MTase comprises the two S subunits and the globular regions of the two M subunits, with the extended portion of the M subunits most probably forming highly mobile regions at the outer extremities, which collapse around the DNA when the MTase binds.

DNA binding, nucleotide flipping, and the helix-turn-helix motif in base repair by O6-alkylguanine-DNA alkyltransferase and its implications for cancer chemotherapy

O(6)-Alkylguanine-DNA alkyltransferase (AGT) is a crucial target both for the prevention of cancer and for chemotherapy, since it repairs mutagenic lesions in DNA, and it limits the effectiveness of alkylating chemotherapies. AGT catalyzes the unique, single-step, direct damage reversal repair of O(6)-alkylguanines by selectively transferring the O(6)-alkyl adduct to an internal cysteine residue. Recent crystal structures of human AGT alone and in complex with substrate DNA reveal a two-domain alpha/beta fold and a bound zinc ion. AGT uses its helix-turn-helix motif to bind substrate DNA via the minor groove. The alkylated guanine is then flipped out from the base stack into the AGT active site for repair by covalent transfer of the alkyl adduct to Cys145. An asparagine hinge (Asn137) couples the helix-turn-helix DNA binding and active site motifs. An arginine finger (Arg128) stabilizes the extrahelical DNA conformation. With this newly improved structural understanding of AGT and its interactions with biologically relevant substrates, we can now begin to unravel the role it plays in preserving genetic integrity and discover how it promotes resistance to anticancer therapies.

REBASE--enzymes and genes for DNA restriction and modification

REBASE is a comprehensive database of information about restriction enzymes, DNA methyltransferases and related proteins involved in the biological process of restriction-modification. It contains fully referenced information about recognition and cleavage sites, isoschizomers, neoschizomers, commercial availability, methylation sensitivity, crystal and sequence data. Experimentally characterized homing endonucleases are also included. All newly sequenced genomes are analyzed for the presence of putative restriction systems and these data are included within the REBASE. The contents or REBASE may be browsed from the web (http://rebase.neb.com/rebase/rebase.ftp.html) and selected compilations can be downloaded by ftp (ftp.neb.com). Additionally, monthly updates can be requested via email.

[The ability of bacterial dna methyltransferases to use methylcobalamine as a cofactor in DNA methylation reactions]

The ability of bacterial DNA methyltransferases Alu I, Cfr I, Cfr 6, Cfr 10, Eco RI, Eco RII, Msp I, Mva I, Pvu I, Pvu II, and Sau 3A to use methyl-cobalamine and methyl-methionine as cofactors of DNA methylation in vitro. These bacterial DNA methyl transferase used methyl-cobalamine, but not methylmethionine for DNA methylation.

DNA Demethylating Agents and Histone Deacetylase Inhibitors in Hematologic Malignancies

The pivotal role of aberrant promoter methylation in gene silencing and cancer development has fueled the interest in DNA methyltransferase inhibitors as novel anticancer drugs. Modulation of gene expression through targeting of epigenetic marks is one of the emerging and promising strategies that has demonstrated successful clinical outcome in hematologic malignancies. Epigenetic modifiers, including DNA methyltransferase inhibitors and histone deacetylase inhibitors, have demonstrated significant clinical activity; several are or are likely to soon be approved by the U.S. Food and Drug Administration. However, the exact mechanism of the clinical response achieved is not fully understood. This review focuses on the pharmacology of the known DNA methyltransferase and histone deacetylase inhibitors and their potential as promising anticancer drugs.

Sequence-specific modification of mitochondrial DNA using a chimeric zinc finger methylase

We used engineered zinc finger peptides (ZFPs) to bind selectively to predetermined sequences in human mtDNA. Surprisingly, we found that engineered ZFPs cannot be reliably routed to mitochondria by using only conventional mitochondrial targeting sequences. We here show that addition of a nuclear export signal allows zinc finger chimeric enzymes to be imported into human mitochondria. The selective binding of mitochondria-specific ZFPs to mtDNA was exemplified by targeting the T8993G mutation, which causes two mitochondrial diseases, neurogenic muscle weakness, ataxia, and retinitis pigmentosa (NARP) and also maternally inherited Leigh's syndrome. To develop a system that allows the monitoring of site-specific alteration of mtDNA we combined a ZFP with the easily assayed DNA-modifying activity of hDNMT3a methylase. Expression of the mutation-specific chimeric methylase resulted in the selective methylation of cytosines adjacent to the mutation site. This is a proof of principle that it is possible to target and alter mtDNA in a sequence-specific manner by using zinc finger technology.

High allelic diversity in the methyltransferase gene of a phase variable type III restriction-modification system has implications for the fitness of Haemophilus influenzae

Phase variable restriction-modification (R-M) systems are widespread in Eubacteria. Haemophilus influenzae encodes a phase variable homolog of Type III R-M systems. Sequence analysis of this system in 22 non-typeable H.influenzae isolates revealed a hypervariable region in the central portion of the mod gene whereas the res gene was conserved. Maximum likelihood (ML) analysis indicated that most sites outside this hypervariable region experienced strong negative selection but evidence of positive selection for a few sites in adjacent regions. A phylogenetic analysis of 61 Type III mod genes revealed clustering of these H.influenzae mod alleles with mod genes from pathogenic Neisseriae and, based on sequence analysis, horizontal transfer of the mod-res complex between these species. Neisserial mod alleles also contained a hypervariable region and all mod alleles exhibited variability in the repeat tract. We propose that this hypervariable region encodes the target recognition domain (TRD) of the Mod protein and that variability results in alterations to the recognition sequence of this R-M system. We argue that the high allelic diversity and phase variable nature of this R-M system have arisen due to selective pressures exerted by diversity in bacteriophage populations but also have implications for other fitness attributes of these bacterial species.

Location of the bases modified by M.BcoKIA and M.BcoKIB methylases in the sequence 5 -CTCTTC-3 /5 -GAAGAG-3

The strain Bacillus coagulans K contains two DNA-methyltransferases, M.BcoKIA and M.BcoKIB, which recognize the sequence 5 -CTCTTC-3 /5 -GAAGAG-3 and possess N4-methylcytosine and N6-methyladenine specificities, respectively. A special construct containing the recognition site of BcoKI and sites of four IIS restriction endonucleases (IIS restriction endonuclease cassette) was designed to locate the nucleotides modified by the methylases. The modified bases were determined as: 5 -m(4)CTCTTC-3 /5 -GAAGAm(6)G-3 .

DNA methyltransferases: facts, clues, mysteries

DNA methylation plays a pivotal role during development in mammals and is central to transcriptional silencing. The DNA methyltransferases (DNMTs) are responsible for the generation of genomic methylation patterns leading to gene silencing, but the underlying molecular basis remains largely shrouded in mystery. Here we review our current understanding of the mechanisms by which DNMTs repress transcription and how they are targeted to preferred DNA sequences. Emerging evidence points to an essential and intricate web of interactions between DNMTs and the chromatin environment in which they function. The recent identification of novel transcription factors recruiting the DNMTs may open new avenues of research into the origin of DNA methylation patterns. Thanks to these emerging clues, researchers have begun to lift the veil on the multi-faceted DNMTs, but there remains fascinating work ahead for whoever wants to fully understand DNMTs and their role in the mammalian cell.

DNA methyltransferases and structural-functional specificity of eukaryotic DNA modification

Properties of the main families of mammalian, plant, and fungal DNA methyltransferases are considered. Structural-functional specificity of eukaryotic genome sequences methylated by DNA methyltransferases is characterized. The total methylation of cytosine in DNA sequences is described, as well as its relation with RNA interference. Mechanisms of regulation of expression and modulation of DNA methyltransferase activity in the eukaryotic cell are discussed.

Mammalian DNA methyltransferases

DNA methylation is an epigenetic process affecting gene expression and chromatin organization. It can heritably silence or activate transcription of genes without any change in their nucleotide sequences, and for a long time was not recognized as an important regulatory mechanism. However, during the recent years it has been shown that improper methylation, especially hypermethylation of promoter regions, is observed in nearly all steps of tumorigenesis. Aberrant methylation is also the cause of several major pathologies including developmental disorders involving chromosome instabilities and mental retardation. A great progress has been made in our understanding of the enzymatic machinery involved in establishing and maintaining methylation patterns. This allowed for the development of new diagnostic tools and epigenetic treatment therapies. The new approaches hold a great potential; several inhibitors of DNA methyltransferases have already shown very promising therapeutic effects.

Identification of Borinic Esters as Inhibitors of Bacterial Cell Growth and Bacterial Methyltransferases, CcrM and MenH

As bacteria continue to develop resistance toward current antibiotics, we find ourselves in a continual battle to identify new antibacterial agents and targets. We report herein a class of boron-containing compounds termed borinic esters that have broad spectrum antibacterial activity with minimum inhibitory concentrations (MIC) in the low microgram/mL range. These compounds were identified by screening for inhibitors against Caulobacter crescentus CcrM, an essential DNA methyltransferase from gram negative alpha-proteobacteria. In addition, we demonstrate that borinic esters inhibit menaquinone methyltransferase in gram positive bacteria using a new biochemical assay for MenH from Bacillus subtilis. Our data demonstrate the potential for further development of borinic esters as antibacterial agents as well as leads to explore more specific inhibitors against two essential bacterial enzymes.

Isolation and characterization of biochemical properties of DNA methyltransferase FauIA modifying the second cytosine in the nonpalindromic sequence 5'-CCCGC-3'

A gene encoding DNA methyltransferase (methylase) FauIA of the restriction-modification system FauI from Flavobacterium aquatile (recognizing sequence 5'-CCCGC-3') was cloned in pJW vector. The latter was used for transformation of E. coli RRI cells followed by subsequent thermoinduction and biomass elaboration. Highly purified DNA methyltransferase FauIA preparation was obtained using chromatography on different sorbents. The molecular mass of the isolated enzyme of about 39 kD corresponds to its theoretical value. The enzyme was characterized by temperature and pH optima of 33 degrees C and pH 7.5, respectively. Methylation of a synthetic oligonucleotide by FauIA methylase followed by its cleavage with various restrictases and analysis of the resultant restriction fragments revealed that FauIA methylase modified the second cytosine residue in the sequence 5'-CCCGC-3'. Kinetic analysis revealed Km and catalytic constant values of 0.16 microM and 0.05 min(-1), respectively.

A novel methyltransferase required for the formation of the hypermodified nucleoside wybutosine in eucaryotic tRNA

We demonstrate that the product of the yeast open reading frame YML005w is required for wybutosine (yW) formation in the phenylalanine-accepting tRNA of the yeast Saccharomyces cerevisiae. tRNA isolated from a deletion mutant of the YML005w gene accumulates 4-demethylwyosine (ImG-14), a precursor lacking three of the methyl groups of the yW hypermodified base. Since the amino acid sequence of the YML005w gene contains the signature motifs of the seven beta-strand methyltransferases, we now designate the gene TRM12 for tRNA methyltransferase. Using pulse-chase labeling of intact yeast cells with S-adenosyl-L-[methyl-(3)H]methionine, we show that the methylesterified form of yW is metabolically stable.

REBASE--restriction enzymes and DNA methyltransferases

REBASE is a comprehensive database of information about restriction enzymes, DNA methyltransferases and related proteins involved in restriction–modification. It contains both published and unpublished work with information about recognition and cleavage sites, isoschizomers, commercial availability, crystal and sequence data. Experimentally characterized homing endonucleases are also included. Additionally, REBASE contains complete and up-to-date information about the methylation sensitivity of restriction endonucleases. An extensive analysis is included of the restriction–modification systems that are predicted to be present in the sequenced bacterial and archaeal genomes from GenBank. The contents of REBASE are available by browsing from the web (http://rebase.neb.com/rebase/rebase.html) and through selected compilations by ftp (ftp.neb.com) and as monthly updates that can be requested via email.

Structure of the Q237W mutant of HhaI DNA methyltransferase: an insight into protein-protein interactions

We have determined the structure of a mutant (Q237W) of HhaI DNA methyltransferase, complexed with the methyl-donor product AdoHcy. The Q237W mutant proteins were crystallized in the monoclinic space group C2 with two molecules in the crystallographic asymmetric unit. Protein-protein interface calculations in the crystal lattices suggest that the dimer interface has the specific characteristics for homodimer protein-protein interactions, while the two active sites are spatially independent on the outer surface of the dimer. The solution behavior suggests the formation of HhaI dimers as well. The same HhaI dimer interface is also observed in the previously characterized binary (M.HhaI-AdoMet) and ternary (M.HhaI-DNA-AdoHcy) complex structures, crystallized in different space groups. The dimer is characterized either by a non-crystallographic two-fold symmetry or a crystallographic symmetry. The dimer interface involves three segments: the amino-terminal residues 2-8, the carboxy-terminal residues 313-327, and the linker (amino acids 179-184) between the two functional domains--the catalytic methylation domain and the DNA target recognition domain. Both the amino- and carboxy-terminal segments are part of the methylation domain. We also examined protein-protein interactions of other structurally characterized DNA MTases, which are often found as a 2-fold related 'dimer' with the largest dimer interface area for the group-beta MTases. A possible evolutionary link between the Type I and Type II restriction-modification systems is discussed.

Processive Methylation of Hemimethylated CpG Sites by Mouse Dnmt1 DNA Methyltransferase

DNA methyltransferase Dnmt1 ensures clonal transmission of lineage-specific DNA methylation patterns in a mammalian genome during replication. Dnmt1 is targeted to replication foci, interacts with PCNA, and favors methylating the hemimethylated form of CpG sites. To understand the underlying mechanism of its maintenance function, we purified recombinant forms of full-length Dnmt1, a truncated form of Dnmt1-(291-1620) lacking the binding sites for PCNA and DNA and examined their processivity using a series of long unmethylated and hemimethylated DNA substrates. Direct analysis of methylation patterns using bisulfite-sequencing and hairpin-PCR techniques demonstrated that full-length Dnmt1 methylates hemimethylated DNA with high processivity and a fidelity of over 95%, but unmethylated DNA with much less processivity. The truncated form of Dnmt1 showed identical properties to full-length Dnmt1 indicating that the N-terminal 290-amino acid residue region of Dnmt1 is not required for preferential activity toward hemimethylated sites or for processivity of the enzyme. Remarkably, our analyses also revealed that Dnmt1 methylates hemimethylated CpG sites on one strand of double-stranded DNA during a single processive run. Our findings suggest that these inherent enzymatic properties of Dnmt1 play an essential role in the faithful and efficient maintenance of methylation patterns in the mammalian genome.

Determinants of cofactor binding to DNA methyltransferases: insights from a systematic series of structural variants of S-adenosylhomocysteine

S-Adenosylmethionine (AdoMet) is a commonly used cofactor, second only to ATP in the variety of reactions in which it participates. It is the methyl donor in the majority of methyl transfer reactions, including methylation of DNA, RNA, proteins and small molecules. Almost all structurally characterised methyltransferases share a conserved AdoMet-dependent methyltransferase fold, in which AdoMet is bound in the same orientation. Although potential interactions between the cofactor and methyltransferases have been inferred from crystal structures, there has not been a systematic study of the contributions of each functional group to binding. To explore the binding interaction we synthesised a series of seven analogues of the methyltransferase inhibitor S-adenosylhomocysteine (AdoHcy), each containing a single modification, and tested them for the ability to inhibit methylation by HhaI and HaeIII DNA methyltransferase. Comparison of the Ki values highlights the structural determinants for cofactor binding, and indicates which nucleoside and amino acid functional groups contribute significantly to AdoMet binding. An understanding of the binding of AdoHyc to methyltransferases will greatly assist the design of AdoMet inhibitors.

[Cloning, primary structure determination and comparative analysis of DNA-methyltransferases from SfaNI and Bst19I restriction-modification systems]

Genes encoding DNA-methyltransferases which recognize the same sequence 5'-GCATC-3' from SfaNI and Bst19I restriction-modification systems have been cloned and primary structures of these have been determined. It has been revealed that restriction-modification system Bst19I contains two DNA-methyltransferases M1.Bst19I and M2.Bst19I, whereas RM system SfaNI include only one DNA-methyltransferase M.SfaNI, N- and C-domain of which are homologous of M2.Bst19I and M1.Bst19I, respectively. M1.Bst19I and M2.Bst19I as well as both domains of M.SfaNI contain conservative elements in an order that is typical for N6-adenine DNA-methyltransferases alpha class. SfaNI and Bst19I DNA-methyltransferases share high homology level with methylases of FokI and BstF5I RM systems. Probably this reflects presence of the common DNA sequence 5'-GATG-3' in the recognition sites of all these RM systems. Basing on primary structures homology of methylases, highly conserved amino acid residues on known spatial model of DNA-methyltransferase M.DpnIIA have been determined.

Isolation and characterization of site-specific DNA-methyltransferases from Bacillus coagulans K

Two site-specific DNA methyltransferases, M.BcoKIA and M.BcoKIB, were isolated from the thermophilic strain Bacillus coagulans K. Each of the methylases protects the recognition site 5'-CTCTTC-3'/5'-GAAGAG-3' from cleavage with the cognate restriction endonuclease BcoKI. It is shown that M.BcoKIB is an N6-adenine specific methylase and M.BcoKIA is an N4-cytosine specific methylase. According to bisulfite mapping, M.BcoKIA methylates the first cytosine in the sequence 5'-CTCTTC-3'.

Purification and characterisation of a novel DNA methyltransferase, M.AhdI

We have cloned the M and S genes of the restriction-modification (R-M) system AhdI and have purified the resulting methyltransferase to homogeneity. M.AhdI is found to form a 170 kDa tetrameric enzyme having a subunit stoichiometry M2S2 (where the M and S subunits are responsible for methylation and DNA sequence specificity, respectively). Sedimentation equilibrium experiments show that the tetrameric enzyme dissociates to form a heterodimer at low concentration, with K(d) approximately 2 microM. The intact (tetrameric) enzyme binds specifically to a 30 bp DNA duplex containing the AhdI recognition sequence GACN5GTC with high affinity (K(d) approximately 50 nM), but at low enzyme concentration the DNA binding activity is governed by the dissociation of the tetramer into dimers, leading to a sigmoidal DNA binding curve. In contrast, only non-specific binding is observed if the duplex lacks the recognition sequence. Methylation activity of the purified enzyme was assessed by its ability to prevent restriction by the cognate endonuclease. The subunit structure of the M.AhdI methyltransferase resembles that of type I MTases, in contrast to the R.AhdI endonuclease which is typical of type II systems. AhdI appears to be a novel R-M system with properties intermediate between simple type II systems and more complex type I systems, and may represent an intermediate in the evolution of R-M systems.

Interactions within the mammalian DNA methyltransferase family

BACKGROUND

In mammals, epigenetic information is established and maintained via the postreplicative methylation of cytosine residues by the DNA methyltransferases Dnmt1, Dnmt3a and Dnmt3b. Dnmt1 is required for maintenance methylation whereas Dnmt3a and Dnmt3b are responsible for de novo methylation. Contrary to Dnmt3a or Dnmt3b, the isolated C-terminal region of Dnmt1 is catalytically inactive, despite the presence of the sequence motifs typical of active DNA methyltransferases. Deletion analysis has revealed that a large part of the N-terminal domain is required for enzymatic activity.

RESULTS

The role played by the N-terminal domain in this regulation has been investigated using the yeast two-hybrid system. We show here the presence of an intra-molecular interaction in Dnmt1 but not in Dnmt3a or Dnmt3b. This interaction was confirmed by immunoprecipitation and was localized by deletion mapping. Furthermore, a systematic analysis of interactions among the Dnmt family members has revealed that DNMT3L interacts with the C-terminal domain of Dnmt3a and Dnmt3b.

CONCLUSIONS

The lack of methylating ability of the isolated C-terminal domain of Dnmt1 could be explained in part by a physical interaction between N- and C-terminal domains that apparently is required for activation of the catalytic domain. Our deletion analysis suggests that the tertiary structure of Dnmt1 is important in this process rather than a particular sequence motif. Furthermore, the interaction between DNMT3L and the C-terminal domains of Dnmt3a and Dnmt3b suggests a mechanism whereby the enzymatically inactive DNMT3L brings about the methylation of its substrate by recruiting an active methylase.

Cloning, expression, purification, crystallization and preliminary X-ray diffraction analysis of HP1352, a putative DNA methyltransferase in Helicobacter pylori

The putative methyltransferase gene HP1352 from Helicobacter pylori strain 26695 was heterologously expressed in Escherichia coli. The 359-amino-acid gene product was purified and crystallized. The crystals belong to space group I2(1)2(1)2(1) and show diffraction to at least 2.5 A resolution. The unit-cell parameters are a = 69.6, b = 86.6, c = 140.0 A. A greater than 90% complete native data set has been collected and structure determination using the molecular-replacement method is ongoing.

[Prokaryotic DNA methyltransferases: the structure and the mechanism of interaction with DNA]

The review considers current views on the function of DNA methyltransferases (MTases) that belong to prokaryotic type II restriction-modification systems. A commonly accepted classification of MTases is described along with their primary and tertiary structures and molecular mechanisms of their specific interaction with DNA (including methylation). MTase inhibitors are also considered. Special emphasis is placed on the flipping of the target heterocyclic base out of the double helix and on the methods employed in its analysis. Base flipping is a fundamentally new type of DNA conformational changes and is also of importance in the case of other DNA-operating enzymes. MTases show unique sequence homology, and are similar in structure of functional centers and in the mechanism of methylation. These data contribute to the understanding of the general biological significance of methylation, since prokaryotic and eukaryotic MTases are structurally and functionally similar.

REBASE: restriction enzymes and methyltransferases

REBASE contains comprehensive information about restriction enzymes, DNA methyltransferases and related proteins such as nicking enzymes, specificity subunits and control proteins. It contains published and unpublished references, recognition and cleavage sites, isoschizomers, commercial availability, crystal and sequence data. Homing endonucleases are also included. REBASE contains the most complete and up-to-date information about the methylation sensitivity of restriction endonucleases. In addition, there is extensive information about the known and putative restriction-modification (R-M) systems in more than 100 sequenced bacterial and archaeal genomes. The data is available on the web (http://rebase.neb.com/rebase/rebase.html), through ftp (ftp.neb.com) and as monthly updates via email.

Determination of methylation site of DNA-methyltransferase NlaX by a hybrid method

Using a new method based on a combination of bisulfite reaction, the repair enzyme uracil-DNA glycosylase, and synthetic oligodeoxyribonucleotides, the methylation site of DNA-methyltransferase NlaX (M.NlaX) from Neisseria lactamica was established to be the inner cytosine in the double-stranded pentanucleotide recognition sequence 5'-CCNGG-3' (where N = any nucleoside). 5-Methylcytosine (m5C) type modification by M-N1aX was confirmed by the use of oligonucleotide substrates that contain 5-fluoro-2'-deoxycytidine.

Selective inhibition of DNA methyltransferase enzymes as a novel strategy for cancer treatment

A common event in the development of human neoplasia is the loss of growth regulatory tumor suppressor functions. Methylation of 5'-CpG islands of tumor suppressor genes and elevated levels of the DNA-(cytosine-5)-methyltransferase enzymes (DNMT1, 3A and 3B) are also prevalent features of human neoplasia. However, direct evidence that elevated DNMT enzyme levels alter gene expression and influence oncogenesis has been difficult to obtain due to the lack of specific DNMT inhibitors. We have developed potent and selective antisense inhibitors of the known DNA methyltransferases. MG-98, a second-generation DNMT1-specific antisense inhibitor currently in phase II clinical trials, reactivates silenced tumor suppressor genes and inhibits the growth of cancer cells in vitro and in preclinical in vivo models. Here, we will review the discovery and development of MG-98 as a cancer therapeutic.