Procaryotic and eucaryotic traits of DNA methylation in spiroplasmas (mycoplasmas)

DNA methylome regulates virulence and metabolism in Pseudomonas syringae

Bacterial pathogens employ epigenetic mechanisms, including DNA methylation, to adapt to environmental changes, and these mechanisms play important roles in various biological processes. Pseudomonas syringae is a model phytopathogenic bacterium, but its methylome is less well known than that of other species. In this study, we conducted single-molecule real-time sequencing to profile the DNA methylation landscape in three model pathovars of P. syringae. We identified one Type I restriction-modification system (HsdMSR), including the conserved sequence motif associated with N6-methyladenine (6mA). About 25-40% of the genes involved in DNA methylation were conserved in two or more of the strains, revealing the functional conservation of methylation in P. syringae. Subsequent transcriptomic analysis highlighted the involvement of HsdMSR in virulent and metabolic pathways, including the Type III secretion system, biofilm formation, and translational efficiency. The regulatory effect of HsdMSR on transcription was dependent on both strands being fully 6mA methylated. Overall, this work illustrated the methylation profile in P. syringae and the critical involvement of DNA methylation in regulating virulence and metabolism. Thus, this work contributes to a deeper understanding of epigenetic transcriptional control in P. syringae and related bacteria.

Impact of G-Quadruplex Structures on Methylation of Model Substrates by DNA Methyltransferase Dnmt3a

In mammals, de novo methylation of cytosines in DNA CpG sites is performed by DNA methyltransferase Dnmt3a. Changes in the methylation status of CpG islands are critical for gene regulation and for the progression of some cancers. Recently, the potential involvement of DNA G-quadruplexes (G4s) in methylation control has been found. Here, we provide evidence for a link between G4 formation and the function of murine DNA methyltransferase Dnmt3a and its individual domains. As DNA models, we used (i) an isolated G4 formed by oligonucleotide capable of folding into parallel quadruplex and (ii) the same G4 inserted into a double-stranded DNA bearing several CpG sites. Using electrophoretic mobility shift and fluorescence polarization assays, we showed that the Dnmt3a catalytic domain (Dnmt3a-CD), in contrast to regulatory PWWP domain, effectively binds the G4 structure formed in both DNA models. The G4-forming oligonucleotide displaced the DNA substrate from its complex with Dnmt3a-CD, resulting in a dramatic suppression of the enzyme activity. In addition, a direct impact of G4 inserted into the DNA duplex on the methylation of a specific CpG site was revealed. Possible mechanisms of G4-mediated epigenetic regulation may include Dnmt3a sequestration at G4 and/or disruption of Dnmt3a oligomerization on the DNA surface.

Rapid and Definitive Analysis of In Vitro DNA Methylation by Nano-electrospray Ionization Mass Spectrometry

CpG methylation of DNA is an epigenetic marker that is highly related to the regulation of transcription initiation. For analysis of CpG methylation in genomic DNA sequences, bisulfite-induced modification in combination with polymerase chain reaction (PCR) is usually utilized, but it cannot be straightforwardly applied to methylated short- and middle-sized DNAs, such as < 500 base pairs (bp), which are often utilized in structural biology studies. In the present study, we applied nano-electrospray ionization mass spectrometry (nano-ESI-MS) for the characterization of methylated DNA with < 400 bp prepared in vitro. First, double-stranded DNA oligomers were methylated with recombinant M.SssI DNA methylase, which has been reported to modify completely and exclusively CpG sites in the sequence. The fragments generated by the digestion with methylation-insensitive restriction nuclease were then analyzed to identify the methylation levels by nano-ESI-MS, without liquid chromatography (LC) separation. By methylation-insensitive nuclease digestion, we divided the DNA strands into several fragments, and nano-ESI-MS enabled the accurate analysis of methylation levels in the DNA fragments with a relatively small amount of DNA sample prepared under optimized conditions. Furthermore, it was revealed that M.SssI methylase hardly modifies the CpG sites closely positioned at the ends of linear DNA. The present method is similar to the strategy for post-translational modification analysis of proteins and is promising for the rapid and definitive characterization of methylated DNA that may be used in structural biology studies.

Bioinformatics and Translation Elongation

Codon usage depends on mutation bias, tRNA-mediated selection, and the need for high efficiency and accuracy in translation. One codon in a synonymous codon family is often strongly over-used, especially in highly expressed genes, which often leads to a high dN/dS ratio because dS is very small. Many different codon usage indices have been proposed to measure codon usage and codon adaptation. Sense codon could be misread by release factors and stop codons misread by tRNAs, which also contribute to codon usage in rare cases. This chapter outlines the conceptual framework on codon evolution, illustrates codon-specific and gene-specific codon usage indices, and presents their applications. A new index for codon adaptation that accounts for background mutation bias (Index of Translation Elongation) is presented and contrasted with codon adaptation index (CAI) which does not consider background mutation bias. They are used to re-analyze data from a recent paper claiming that translation elongation efficiency matters little in protein production. The reanalysis disproves the claim.

Complete Genome Sequence of Spiroplasma monobiae MQ-1T (ATCC 33825), a Bacterium Isolated from the Vespid Wasp (Monobia quadridens)

Spiroplasma monobiae MQ-1T (ATCC 33825) was isolated from the hemolymph of an adult vespid wasp (Monobia quadridens) collected in Maryland. Here, we report the complete genome sequence of this bacterium to facilitate the investigation of its biology and the comparative genomics among Spiroplasma species.

Two-color fluorescent cytosine extension assay for the determination of global DNA methylation

Here, we present a DNA restriction enzyme-based, fluorescent cytosine extension assay (CEA) to improve normalization and technical variation among sample-to-sample measurements. The assay includes end-labeling of parallel methylation-sensitive and methylation-insensitive DNA restriction enzyme digests along with co-purification and subsequent co-measurement of incorporated fluorescence. This non-radioactive, two-color fluorescent CEA (TCF-CEA) was shown to be a relatively rapid and accurate, with 3-fold greater precision than the one-color CEA. In addition, TCF-CEA provided an index of global DNA methylation that was sensitive to differences >5%. TCF-CEA results were highly correlated with LUminometric Methylation Assay (LUMA) results using human liver cell lines (HepG2, HepaRG, HC-04) as well as a human liver primary cell culture. Hypomethylation was observed in cells treated with the de-methylating agent 5-aza-2'-deoxycytidine. These results demonstrate that TCF-CEA provides a simple method for measuring relative degrees of global DNA methylation that could potentially be scaled up to higher-throughput formats.

Crystal structure of human nucleosome core particle containing enzymatically introduced CpG methylation

Cytosine methylation, predominantly of the CpG sequence in vertebrates, is one of the major epigenetic modifications crucially involved in the control of gene expression. Due to the difficulty of reconstituting site-specifically methylated nucleosomal DNA at crystallization quality, most structural analyses of CpG methylation have been performed using chemically synthesized oligonucleotides, There has been just one recent study of nucleosome core particles (NCPs) reconstituted with nonpalindromic human satellite 2-derived DNAs. Through the preparation of a 146-bp palindromic α-satellite-based nucleosomal DNA containing four CpG dinucleotide sequences and its enzymatic methylation and restriction, we reconstituted a 'symmetric' human CpG-methylated nucleosome core particle (NCP). We solved the crystal structures of the CpG-methylated and unmodified NCPs at 2.6 and 3.0 Å resolution, respectively. We observed the electron densities of two methyl groups, among the eight 5-methylcytosines introduced in the CpG-fully methylated NCP. There were no obvious structural differences between the CpG-methylated 'symmetric NCP' and the unmodified NCP. The preparation of a crystallization-grade CpG-methylated NCP provides a platform for the analysis of CpG-methyl reader and eraser proteins.

Dynamic changes in global and gene-specific DNA methylation during hibernation in adult thirteen-lined ground squirrels, Ictidomys tridecemlineatus

Hibernating mammals conserve energy in the winter by undergoing prolonged bouts of torpor, interspersed with brief arousals back to euthermia. These bouts are accompanied by a suite of reversible physiological and biochemical changes; however, much remains to be discovered about the molecular mechanisms involved. Given the seasonal nature of hibernation, it stands to reason that underlying plastic epigenetic mechanisms should exist. One such form of epigenomic regulation involves the reversible modification of cytosine bases in DNA by methylation. DNA methylation is well known to be a mechanism that confers upon DNA its cellular identity during differentiation in response to innate developmental cues. However, it has recently been hypothesized that DNA methylation also acts as a mechanism for adapting genome function to changing external environmental and experiential signals over different time scales, including during adulthood. Here, we tested the hypothesis that DNA methylation is altered during hibernation in adult wild animals. This study evaluated global changes in DNA methylation in response to hibernation in the liver and skeletal muscle of thirteen-lined ground squirrels along with changes in expression of DNA methyltransferases (DNMT1/3B) and methyl binding domain proteins (MBDs). A reduction in global DNA methylation occurred in muscle during torpor phases whereas significant changes in DNMTs and MBDs were seen in both tissues. We also report dynamic changes in DNA methylation in the promoter of the myocyte enhancer factor 2C (mef2c) gene, a candidate regulator of metabolism in skeletal muscle. Taken together, these data show that genomic DNA methylation is dynamic across torpor-arousal bouts during winter hibernation, consistent with a role for this regulatory mechanism in contributing to the hibernation phenotype.

The determination of DNA methyltransferase activity by quenching of tris(2,2′-bipyridine)ruthenium electrogenerated chemiluminescence with ferrocene

An electrogenerated chemiluminescence biosensing method for the determination of DNA methyltransferase activity is developed by the quenching of tris(2,2′-bipyridine)ruthenium ECL by ferrocene.

DNA repair in Mycoplasma gallisepticum

Background

DNA repair is essential for the maintenance of genome stability in all living beings. Genome size as well as the repertoire and abundance of DNA repair components may vary among prokaryotic species. The bacteria of the Mollicutes class feature a small genome size, absence of a cell wall, and a parasitic lifestyle. A small number of genes make Mollicutes a good model for a “minimal cell” concept.

Results

In this work we studied the DNA repair system of Mycoplasma gallisepticum on genomic, transcriptional, and proteomic levels. We detected 18 out of 22 members of the DNA repair system on a protein level. We found that abundance of the respective mRNAs is less than one per cell. We studied transcriptional response of DNA repair genes of M. gallisepticum at stress conditions including heat, osmotic, peroxide stresses, tetracycline and ciprofloxacin treatment, stationary phase and heat stress in stationary phase.

Conclusions

Based on comparative genomic study, we determined that the DNA repair system M. gallisepticum includes a sufficient set of proteins to provide a cell with functional nucleotide and base excision repair and mismatch repair. We identified SOS-response in M. gallisepticum on ciprofloxacin, which is a known SOS-inducer, tetracycline and heat stress in the absence of established regulators. Heat stress was found to be the strongest SOS-inducer. We found that upon transition to stationary phase of culture growth transcription of DNA repair genes decreases dramatically. Heat stress does not induce SOS-response in a stationary phase.

Sensitive detection of DNA methyltransferase using hairpin probe-based primer generation rolling circle amplification-induced chemiluminescence

DNA methyltransferases (MTases) catalyze the transfer of a methyl group from S-adenosylmethionine (SAM) to the 5-positon of cytosine in CpG islands, eventually inducing the DNA methylation in both prokaryotes and eukaryotes. Despite the development of various methods for the MTase assay, most of them are laborious and costly with poor sensitivity. Herein, we develop a highly sensitive chemiluminescence method for the MTase assay using hairpin probe-based primer generation rolling circle amplification (PG-RCA). In the presence of DNA adenine methylation (Dam) MTase, the methylation-responsive sequence of hairpin probe is methylated and cleaved by the methylation-sensitive restriction endonuclease Dpn I. The cleaved hairpin probe then functions as a signal primer to initiate PG-RCA reaction by hybridizing with the circular DNA template, producing a large number of horseradish peroxidase-mimicking DNAzyme chains, which can catalyze the oxidation of luminal by H2O2 in the presence of hemin to yield distinct chemiluminescence signal. While in the absence of Dam MTase, neither methylation/cleavage nor PG-RCA reaction can be initiated and no chemiluminescence signal is observed. The proposed method exhibits a wide dynamic range from 0.025 to 400 U/mL and an extremely low detection limit of 1.29 × 10(-4) U/mL, which is superior to most conventional approaches for the MTase assay. This method can be used for the screening of antimicrobial drugs and has a great potential to be further applied in early clinical diagnosis.

Probing murine methyltransfease Dnmt3a interactions with benzo[a]pyrene-modified DNA by fluorescence methods

The impact of bulky carcinogen-DNA adducts positioned at or near recognition sites (CpG) of eukaryotic DNA methyltransferases on their catalytic activities is poorly understood. In the present study, we employed site-specifically modified 30-mer oligodeoxyribonucleotides containing stereoisomeric benzo[a]pyrene diol epoxide (B[a]PDE)-derived guanine (B[a]PDE-N(2)-dG) or adenine (B[a]PDE-N(6)-dA) adducts of different conformations as substrates of the catalytic domain of murine Dnmt3a (Dnmt3a-CD). The fluorescence of these lesions was used to examine interactions between Dnmt3a-CD and DNA. In B[a]PDE-DNA•Dnmt3a-CD complexes, the intensity of fluorescence of the covalently bound B[a]PDE residues is enhanced relative to the protein-free value when the B[a]PDE is positioned in the minor groove [(+)- and (-)-trans-B[a]PDE-N(2)-dG adducts in the CpG site] and when it is intercalated on the 5'-side of the CpG site [(+)-trans-B[a]PDE-N(6)-dA adduct]. The fluorescence of B[a]PDE-modified DNA•Dnmt3a-CD complexes exhibits only small changes when the B[a]PDE is intercalated with base displacement in (+)- and (-)-cis-B[a]PDE-N(2)-dG adducts and without base displacement in the (-)-trans-B[a]PDE-N(6)-dA adduct. The initial rates of methylation were significantly reduced by the minor groove trans-B[a]PDE-N(2)-dG adducts, regardless of their position in the substrate and by the intercalated cis-B[a]PDE-N(2)-dG adducts within the CpG site. The observed changes in fluorescence and methylation rates are consistent with the flipping of the target cytosine and a catalytic loop motion within the DNA•Dnmt3a-CD complexes. In the presence of the regulatory factor Dnmt3L, an enhancement of both methylation rates and fluorescence was observed, which is consistent with a Dnmt3L-mediated displacement of the catalytic loop towards the CpG site.

Peripheral SLC6A4 DNA methylation is associated with in vivo measures of human brain serotonin synthesis and childhood physical aggression

The main challenge in addressing the role of DNA methylation in human behaviour is the fact that the brain is inaccessible to epigenetic analysis in living humans. Using positron emission tomography (PET) measures of brain serotonin (5-HT) synthesis, we found in a longitudinal sample that adult males with high childhood-limited aggression (C-LHPA) had lower in vivo 5-HT synthesis in the orbitofrontal cortex (OBFC). Here we hypothesized that 5-HT alterations associated with childhood aggression were linked to differential DNA methylation of critical genes in the 5-HT pathway and these changes were also detectable in peripheral white blood cells. Using pyrosequencing, we determined the state of DNA methylation of SLC6A4 promoter in T cells and monocytes isolated from blood of cohort members (N = 25) who underwent a PET scan, and we examined whether methylation status in the blood is associated with in vivo brain 5-HT synthesis. Higher levels of methylation were observed in both T cells and monocytes at specific CpG sites in the C-LHPA group. DNA methylation of SLC6A4 in monocytes appears to be associated more reliably with group membership than T cells. In both cell types the methylation state of these CpGs was associated with lower in vivo measures of brain 5-HT synthesis in the left and right lateral OBFC (N = 20) where lower 5-HT synthesis in C-LHPA group was observed. Furthermore, in vitro methylation of the SLC6A4 promoter in a luciferase reporter construct suppresses its transcriptional activity supporting a functional role of DNA methylation in SLC6A4 promoter regulation. These findings indicate that state of SLC6A4 promoter methylation is altered in peripheral white blood cells of individuals with physical aggression during childhood. This supports the relevance of peripheral DNA methylation for brain function and suggests that peripheral SLC6A4 DNA methylation could be a marker of central 5-HT function.

The lytic phase of epstein-barr virus requires a viral genome with 5-methylcytosine residues in CpG sites

Epstein-Barr virus (EBV) is a human herpesvirus which has been studied intensively for its role in certain human tumors. It also serves as a model of herpesviral latency because it establishes an immediate, latent infection in human B cells. When EBV infects quiescent, primary B cells it induces their continuous proliferation to yield growth-transformed B-cell lines in vitro. The lytic or productive phase of EBV's life cycle is induced by the expression of the viral BZLF1 gene in latently infected cells. The BZLF1 protein is a transactivator, which selectively binds to two classes of distinct DNA sequence motifs. One class is similar to the motifs that are bound by members of the AP-1 transcription factor family to which BZLF1 belongs. The second class, which contains CpG motifs, is predominant in viral promoters of early lytic genes and is BZLF1's preferred or exclusive target sequence when methylated. The BZLF1 gene is transiently expressed in newly infected B cells but fails to induce EBV's lytic cycle, potentially because the virion DNA is unmethylated. Here we report that the lack of 5-methylcytosine residues in CpG sites of virion DNA prevents the expression of essential lytic genes indispensable for viral DNA amplification during productive infection. This finding indicates that BZLF1 transactivates these promoters in a methylation-dependent fashion and explains how progeny virus synthesis is abrogated in newly infected B cells. Our data also reveal that viral lytic DNA synthesis precludes CpG methylation of virion DNA during EBV's lytic, productive cycle, which can be overcome by the ectopic expression of a prokaryotic cytosine methyltransferase to yield CpG-methylated virion DNA. Upon infection of B cells, randomly CpG-methylated virion DNA induces high expression of essential lytic genes in contrast to virion DNA free of 5-methylcytosine residues. Our data suggest that unmethylated virion DNA is part of EBV's strategy to prevent the viral lytic phase in newly infected B cells, allowing it to establish its characteristic latent infection in them.

MethylViewer: computational analysis and editing for bisulfite sequencing and methyltransferase accessibility protocol for individual templates (MAPit) projects

Bisulfite sequencing is a widely-used technique for examining cytosine DNA methylation at nucleotide resolution along single DNA strands. Probing with cytosine DNA methyltransferases followed by bisulfite sequencing (MAPit) is an effective technique for mapping protein-DNA interactions. Here, MAPit methylation footprinting with M.CviPI, a GC methyltransferase we previously cloned and characterized, was used to probe hMLH1 chromatin in HCT116 and RKO colorectal cancer cells. Because M.CviPI-probed samples contain both CG and GC methylation, we developed a versatile, visually-intuitive program, called MethylViewer, for evaluating the bisulfite sequencing results. Uniquely, MethylViewer can simultaneously query cytosine methylation status in bisulfite-converted sequences at as many as four different user-defined motifs, e.g. CG, GC, etc., including motifs with degenerate bases. Data can also be exported for statistical analysis and as publication-quality images. Analysis of hMLH1 MAPit data with MethylViewer showed that endogenous CG methylation and accessible GC sites were both mapped on single molecules at high resolution. Disruption of positioned nucleosomes on single molecules of the PHO5 promoter was detected in budding yeast using M.CviPII, increasing the number of enzymes available for probing protein-DNA interactions. MethylViewer provides an integrated solution for primer design and rapid, accurate and detailed analysis of bisulfite sequencing or MAPit datasets from virtually any biological or biochemical system.

Development and validation of a gas chromatography/mass spectrometry method for the assessment of genomic DNA methylation

A method for the determination of DNA global methylation, taken as the ratio (%) of 5-methylcytosine (5mCyt) versus the sum of cytosine (Cyt) and 5mCyt, via gas chromatography/mass spectrometry (GC/MS), was developed and validated. DNA (2.5 microg) was hydrolyzed with aqueous formic acid 88%, spiked with cytosine-2,4-(13)C(2),(15)N(3) and 5-methyl-(2)H(3)-cytosine-6-(2)H(1) as internal standards, and derivatized with N-methyl-N-(tert-butyldimethylsilyl)trifluoroacetamide and 1% tert-butyldimethylchlorosilane, in the presence of acetonitrile and pyridine. GC/MS, operating in single ion monitoring mode, separated and specifically detected all nucleobases as tert-butyldimethylsilyl derivatives, without interferences, with the exception of guanosine. The method was linear throughout the range of clinical interest and had good sensitivity, with a limit of quantification of 3.2 pmol for Cyt and 0.056 pmol for 5mCyt, the latter corresponding to a methylation level of 0.41%. Intra- and inter-day precision and accuracy were below 4.0% for both analytes and methylation. The matrix absolute effect, process efficiency and coefficient of variation ranged from 96.5 to 101.2%. The matrix relative effect was below 1%. The method was applied to the analysis of different human DNAs, including: nonmethylated DNA from PCR (methylation 0.00%), hypermethylated DNA prepared using M.SssI CpG methyltransferase (methylation 18.05%), DNA from peripheral blood leukocytes of healthy subjects (N = 6, median methylation 5.45%), DNA from bone marrow of leukemia patients (N = 5, 3.58%) and DNA from myeloma cell lines (N = 4, 2.74%).

Requirement for DNA CpG content in TLR9-dependent dendritic cell activation induced by DNA-containing immune complexes

Although TLR9 was originally thought to specifically recognize microbial DNA, it is now evident that mammalian DNA can be an effective TLR9 ligand. However, the DNA sequence required for TLR9 activation is controversial, as studies have shown conflicting results depending on the nature of the DNA backbone, the route of DNA uptake, and the cell type being studied. In systemic lupus erythematosus, a major route whereby DNA gains access to intracellular TLR9, and thereby activates dendritic cells (DCs), is through uptake as a DNA-containing immune complex. In this report, we used defined dsDNA fragments with a natural (phosphodiester) backbone and show that unmethylated CpG dinucleotides within dsDNA are required for murine DC TLR9 activation induced by a DNA-containing immune complex. The strongest activation is seen with dsDNA fragments containing optimal CpG motifs (purine-purine-CpG-pyrimidine-pyrimidine) that are common in microbial DNA but rare in mammalian DNA. Importantly, however, activation can also be induced by CpG-rich DNA fragments that lack these optimal CpG motifs and that we show are plentiful in CpG islands within mammalian DNA. No activation is induced by DNA fragments lacking CpG dinucleotides, although this CpG-free DNA can induce DC activation if internalized by liposomal transfection instead of as an immune complex. Overall, the data suggest that the release of CpG-rich DNA from mammalian DNA may contribute to the pathogenesis of autoimmune diseases such as systemic lupus erythematosus and psoriasis in which activation of TLR9 in DCs by self DNA has been implicated in disease pathogenesis.

Impact of 7,8-dihydro-8-oxoguanine on methylation of the CpG site by Dnmt3a

7,8-Dihydro-8-oxoguanine (8-oxoG) is a ubiquitous oxidative DNA lesion resulting from injury to DNA via reactive oxygen species. 8-oxoG lesions may play a role in the formation of aberrant DNA methylation patterns during carcinogenesis. In this study, we assessed the effects of 8-oxoG on methylation and complex formation of nine 30-mer oligodeoxynucleotide duplexes by the catalytic domain of murine Dnmt3a DNA methyltransferase (Dnmt3a-CD). The effects of 8-oxoG on the methylation rate of hemimethylated duplexes varied from a 25-fold decrease to a 1.8-fold increase, depending on the position of the lesion relative to the Dnmt3a-CD recognition site (CpG) and target cytosine (C). The most significant effect was observed when 8-oxoG replaced guanine within the recognition site immediately downstream of the target cytosine. Fluorescence polarization experiments with fluorescein-labeled duplexes revealed that two molecules of Dnmt3a-CD bind per duplex, generating sigmoid binding curves. Duplexes exhibiting the highest apparent binding cooperativity formed the least stable 1:2 complexes with Dnmt3a-CD and were methylated at the lowest rate. Kinetic analyses disclosed the formation of very stable nonproductive enzyme-substrate complexes with hemimethylated duplexes that act as suicide substrates of Dnmt3a-CD. The presence of 8-oxoG within the CpG site downstream of the target cytosine markedly diminished productive versus nonproductive binding. We propose that 8-oxoG located adjacent to the target cytosine interferes with methylation by weakening the affinity of DNA for Dnmt3a-CD, thereby favoring a nonproductive binding mode.

Serum insensitive, intranuclear protein delivery by the multipurpose cationic lipid SAINT-2

Cationic liposomal compounds are widely used to introduce DNA and siRNA into viable cells, but none of these compounds are also capable of introducing proteins. Here we describe the use of a cationic amphiphilic lipid SAINT-2:DOPE for the efficient delivery of proteins into cells (profection). Labeling studies demonstrated equal delivery efficiency for protein as for DNA and siRNA. Moreover, proteins complexed with Saint-2:DOPE were successfully delivered, irrespective of the presence of serum, and the profection efficiency was not influenced by the size or the charge of the protein:cationic liposomal complex. Using beta-galactosidase as a reporter protein, enzymatic activity was detected in up to 98% of the adherent cells, up to 83% of the suspension cells and up to 70% of the primary cells after profection. A delivered antibody was detected in the cytoplasm for up to 7 days after profection. Delivery of the methyltransferase M.SssI resulted in DNA methylation, leading to a decrease in E-cadherin expression. The lipid-mediated multipurpose transport system reported here can introduce proteins into the cell with an equal delivery efficiency as for nucleotides. Delivery is irrespective of the presence of serum, and the protein can exert its function both in the cytoplasm and in the nucleus. Furthermore, DNA methylation by M.SssI delivery as a novel tool for gene silencing has potential applications in basic research and therapy.

The stereochemistry of benzo[a]pyrene-2'-deoxyguanosine adducts affects DNA methylation by SssI and HhaI DNA methyltransferases

The biologically most significant genotoxic metabolite of the environmental pollutant benzo[a]pyrene (B[a]P), (+)-7R,8S-diol 9S,10R-epoxide, reacts chemically with guanine in DNA, resulting in the predominant formation of (+)-trans-B[a]P-N(2)-dG and, to a lesser extent, (+)-cis-B[a]P-N(2)-dG adducts. Here, we compare the effects of the adduct stereochemistry and conformation on the methylation of cytosine catalyzed by two purified prokaryotic DNA methyltransferases (MTases), SssI and HhaI, with the lesions positioned within or adjacent to their CG and GCGC recognition sites, respectively. The fluorescence properties of the pyrenyl residues of the (+)-cis-B[a]P-N(2)-dG and (+)-trans-B[a]P-N(2)-dG adducts in complexes with MTases are enhanced, but to different extents, indicating that aromatic B[a]P residues are positioned in different microenvironments in the DNA-protein complexes. We have previously shown that the (+)-trans-isomeric adduct inhibits both the binding and methylating efficiencies (k(cat)) of both MTases [Subach OM, Baskunov VB, Darii MV, Maltseva DV, Alexandrov DA, Kirsanova OV, Kolbanovskiy A, Kolbanovskiy M, Johnson F, Bonala R, et al. (2006) Biochemistry45, 6142-6159]. Here we show that the stereoisomeric (+)-cis-B[a]P-N(2)-dG lesion has only a minimal effect on the binding of these MTases and on k(cat). The minor-groove (+)-trans adduct interferes with the formation of the normal DNA minor-groove contacts with the catalytic loop of the MTases. However, the intercalated base-displaced (+)-cis adduct does not interfere with the minor-groove DNA-catalytic loop contacts, allowing near-normal binding of the MTases and undiminished k(cat) values.

Methyltransferase-directed DNA strand scission

We demonstrate here that MTase-modified DNA can undergo the Staudinger ligation with triarylphosphines derivatized with phenanthroline. Presentation of these duplexes with Cu(II) and 3-mercaptopropionic acid leads to strand scission proximal to the MTase recognition site. By virtue of their ability to use a synthetic azide-bearing cofactor, M.TaqI and M.HhaI produce a DNA lesion that induces scission 5' to the base modified by the enzyme. This chemistry represents a new approach by which regions of DNA methylation can be rapidly identified on the basis of DNA damage.

Spiroplasma as a candidate agent for the transmissible spongiform encephalopathies

The recovery of a novel Spiroplasma sp. from brain tissues from sheep with scrapie, cervids with chronic wasting disease, and from patients with Creutzfeldt-Jakob disease through passage through embryonated eggs has raised the issue of the role of Spiroplasma in the transmissible spongiform encephalopathies (TSE). In this review, we have inserted into an epidemiologic infection model evidence accumulated over the past 30 years showing involvement of Spiroplasma infection in TSE. These data support our hypothesis that a Spiroplasma sp. is the causal agent of TSE, although Koch's postulates must be fulfilled to definitively answer that question.

Synthesis of universal unmethylated control DNA by nested whole genome amplification with phi29 DNA polymerase

Optimization of highly sensitive methods to detect methylation of CpG islands in gene promoter regions requires adequate methylated and unmethylated control DNA. Whereas universal methylated control DNA is available, universal unmethylated control (UUC) DNA has not been made because demethylase is not available to remove methyl groups from all methylated cytosines. On the basis that DNA synthesized by DNA polymerase does not contain methylated cytosines, we developed a method to create UUC DNA by nested whole genome amplification (WGA) with phi29 DNA polymerase. Contamination of the template genomic DNA in UUC was only 3.1 x 10(-7), below the detection limit of sensitive methods used for methylation studies such as methylation-specific PCR. Assessment of microsatellite markers demonstrated that even nested phi29 WGA achieves highly accurate and homogeneous amplification with very low amounts of genomic DNA as an initial template. The UUC DNA created by nested phi29 WGA is practically very useful for methylation analysis.

DNA methylation and Mycoplasma genomes

DNA methylation is one of the many hypotheses proposed to explain the observed deficiency in CpG dinucleotides in a variety of genomes covering a wide taxonomic distribution. Recent studies challenged the methylation hypothesis on empirical grounds. First, it cannot explain why the Mycoplasma genitalium genome exhibits strong CpG deficiency without DNA methylation. Second, it cannot explain the great variation in CpG deficiency between M. genitalium and M. pneumoniae that also does not have CpG-specific methyltransferase genes. I analyzed the genomic sequences of these Mycoplasma species together with the recently sequenced genomes of M. pulmonis, Ureaplasma urealyticum, and Staphylococcus aureus, and found the results fully compatible with the methylation hypothesis. In particular, I present compelling empirical evidence to support the following scenario. The common ancestor of the three Mycoplasma species has CpG-specific methyltransferases, and has evolved strong CpG deficiency as a result of the specific DNA methylation. Subsequently, this ancestral genome diverged into M. pulmonis and the common ancestor of M. pneumoniae and M. genitalium. M. pulmonis has retained methyltransferases and exhibits the strongest CpG deficiency. The common ancestor lost the methyltransferase gene and then diverged into M. genitalium and M. pneumoniae. M. genitalium and M. pneumoniae, after losing methylation activities, began to regain CpG dinucleotides through random mutation. M. genitalium evolved more slowly than M. pneumoniae, gained relatively fewer CpG dinucleotides, and is more CpG-deficient.

The oncoprotein Set/TAF-1beta, an inhibitor of histone acetyltransferase, inhibits active demethylation of DNA, integrating DNA methylation and transcriptional silencing

Histone hypoacetylation and DNA hypermethylation are hallmarks of gene silencing. Although a role for DNA methylation in regulating histone acetylation has been established, it is not clear how and whether epigenetic histone markings influence DNA modifications in transcriptional silencing. We have previously shown that induction of histone acetylation by trichostatin A promotes demethylation of ectopically methylated DNA (Cervoni, N., and Szyf, M. (2001) J. Biol. Chem. 276, 40778-40787). The oncoprotein Set/TAF-Ibeta is a subunit of the recently identified inhibitor of acetyltransferases complex that inhibits histone acetylation by binding to and masking histone acetyltransferase targets (Seo, S. B., McNamara, P., Heo, S., Turner, A., Lane, W. S., and Chakravarti, D. (2001) Cell 104, 119-130). We show here that the overexpression of Set/TAF-Ibeta, whose expression is up-regulated in multiple tumor tissues, inhibits demethylation of ectopically methylated DNA resulting in gene silencing. Overexpression of a mutant Set/TAF-Ibeta that does not inhibit histone acetylation is defective in inhibiting DNA demethylation. Taken together, these results are consistent with a novel regulatory role for Set/TAF-Ibeta, integrating epigenetic states of histones and DNA in gene regulation and provide a new mechanism that can explain how hypermethylation of specific regions might come about by inhibition of demethylation in cancer cells.

Demethylase activity is directed by histone acetylation

Mammalian genomes are compartmentalized into dense inactive chromatin that is hypermethylated and active open chromatin that is hypomethylated. It is generally accepted that this bimodal pattern of methylation is established during development and is then faithfully inherited through subsequent cell divisions by a maintenance DNA methyltransferase (DNMT1). The pattern of methylation is believed to direct local histone acetylation states. In contrast to this well accepted consensus, we show here using a transient transfection model that an active demethylase is involved in shaping patterns of methylation in somatic cells. Demethylase activity is directed by the state of histone acetylation, and therefore, the resulting methylation pattern is determined by local histone acetylation states contrary to the accepted model. Our data support a new model suggesting that the pattern of methylation is maintained by a dynamic balance of methylation and demethylation activities and the local state of histone acetylation. This provides a simple mechanism for explaining why active genes are not methylated.

The effect of C(5) cytosine methylation at CpG sequences on mitomycin-DNA bonding profiles

Recent studies have documented that cytosine C(5) methylation of CpG sequences enhances mitomycin C (1) adduction. The reports differ on the extent and uniformity of 1 modification at the nucleotide level. We have determined the bonding profiles for mitomycin monoalkylation in two DNA restriction fragments where the CpG sequences were methylated. Three mitomycin substrates were used and two different enzymatic assays employed to monitor the extent of drug modification at the individual base sites. Drug DNA modification was accomplished with I and 10-decarbamoylmitomycin C (2) under reductive (Na2S2O4) condilions and with N-methyl-7-methoxyaziridinomitosene (3) under nonreductive conditions. The UvrABC incision assay permitted us to quantitate the sites of drug adduction, and the lambda-exonuclease stop assay provided a qualitative estimation of drug-DNA modification consistent with the UvrABC data. We learned that C(5) cytosine methylation (m5C) enhanced the extent of overall DNA modification. Using the UvrABC endonuclease assay, we found that modification by 1 increased 2.0 and 7.4 times for the two DNA restriction fragments. Analysis of the modification sites at the nucleotide sequence level revealed that guanine (G) was the only base modified and that the overall increased level of DNA adduction was due to enhanced modification of select m5CpG* (G* = mitomycin (mitosene) adduction sites) loci compared with CpG* sites: the largest differences reached two orders of magnitude. Significantly, not all CpG* sites underwent increased drug adduction upon C(5) cytosine methylation. The effect of C(5) cytosine methylation on the drug adduction profiles was less pronounced for G* sites located within dinucleotide sequences other than CpG*. We observed that DNA methylation often led to slightly diminished adduction levels at these sites. The different m5CpG* adduction patterns provided distinctive sequence-selective bonding profiles for 1-3. We have attributed the large differences in guanine reactivity to DNA structural factors created, in part, by C(5) cytosine methylation. The significance of these findings in cancer chemotherapy is briefly discussed.

Mechanistic link between DNA methyltransferases and DNA repair enzymes by base flipping

Rotation of a DNA nucleotide out of the double helix and into a protein binding pocket ("base flipping") was first observed in the structure of a DNA methyltransferase. There is now evidence that a variety of proteins, particularly DNA repair enzymes, use base flipping in their interactions with DNA. Though the mechanisms for base movement into extrahelical positions are still unclear, the focus of this review is how base recognition is modulated by the stringency of binding to the extrahelical base(s) or sugar moiety.

Feedback regulation of DNA methyltransferase gene expression by methylation

This paper tests the hypothesis that expression of the DNA methyltransferase, dnmt1, gene is regulated by a methylation-sensitive DNA element. Methylation of DNA is an attractive system for feedback regulation of DNA methyltransferase as the final product of the reaction, methylated DNA, can regulate gene expression in cis. We show that an AP-1-dependent regulatory element of dnmt1 is heavily methylated in most somatic tissues and in the mouse embryonal cell line, P19, and completely unmethylated in a mouse adrenal carcinoma cell line, Y1. dnmt1 is highly over expressed in Y1 relative to P19 cell lines. Global inhibition of DNA methylation in P19 cells by 5-azadeoxycytidine results in demethylation of the AP-1 regulatory region and induction of dnmt1 expression in P19cells, but not Y1 cells. We propose that this regulatory region of dnmt1 acts as a sensor of the DNA methylation capacity of the cell. These results provide an explanation for the documented coexistence of global hypomethylation and high levels of DNA methyltransferase activity in many cancer cells and for the carcinogenic effect of hypomethylating diets.

DNA demethylase is a processive enzyme

DNA methylation patterns are generated during development by a sequence of methylation and demethylation events. We have recently demonstrated that mammals bear a bona fide demethylase enzyme that removes methyl groups from methylated cytosines. A general genome wide demethylation occurs early in development and in differentiating cell lines. This manuscript tests the hypothesis that the demethylase enzyme is a processive enzyme. Using bisulfite mapping, this report demonstrates that demethylase is a processive enzyme and that the rate-limiting step in demethylation is the initiation of demethylation. Initiation of demethylation is determined by the properties of the sequence. Once initiated, demethylation progresses processively. We suggest that these data provide a molecular explanation for global hypomethylation.

A mammalian protein with specific demethylase activity for mCpG DNA

DNA-methylation patterns are important for regulating genome functions, and are determined by the enzymatic processes of methylation and demethylation. The demethylating enzyme has now been identified: a mammalian complementary DNA encodes a methyl-CpG-binding domain, bears a demethylase activity that transforms methylated cytosine bases to cytosine, and demethylates a plasmid when the cDNA is translated or transiently transfected into human embryonal kidney cells in vitro. The discovery of this DNA demethylase should provide a basis for the molecular and developmental analysis of the role of DNA methylation and demethylation.

Sonication-dependent electroporation of the erythromycin-producing bacterium Saccharopolyspora erythraea

We report the development of an electrotransformation method applicable to all strains of Saccharopolyspora erythraea examined to date. Vegetatively grown mycelia were rendered electrocompetent by subjecting mycelial suspensions to ultrasound pulses. The protocol provides an alternative route for the introduction of DNA into filamentous microorganisms otherwise recalcitrant to transformation techniques.

Methylation of expanded CCG triplet repeat DNA from fragile X syndrome patients enhances nucleosome exclusion

Long tracts of CCG trinucleotide or CCGNN pentanucleotide repeats in DNA have previously been shown to resist assembly into nucleosomes. This may provide a molecular explanation for the nature of certain rare, folate-sensitive fragile sites in human chromosomes that contain expanded CCG triplet tracts. Further, it is known that methylation of CpG dinucleotides at or near these fragile sites enhances the fragile phenotype. Here DNAs containing 76 tandem CCG triplets or 48 CCGNN pentanucleotide repeats were methylated with SssI methylase at three different levels of methylation. Using competitive nucleosome reconstitution/gel shift assays, the ability of these DNAs and a mixed sequence DNA from the pUC19 plasmid were compared in their ability to assemble into nucleosomes. DNA methylation had no significant effect on nucleosome formation over the pUC 19 fragment. However, the highly methylated DNAs containing 76 CCG triplets or 48 CCGNN pentanucleotide repeats were 2.0 +/- 0. 2-fold and 2.1 +/- 0.3-fold less efficient in nucleosome assembly than the respective unmethylated forms, and 4.4 +/- 0.4-fold and 12. 6 +/- 1.6-fold less efficient than a pUC19 fragment of similar length.

The DNA methylation machinery as a target for anticancer therapy

DNA methylation is now recognized as an important mechanism regulating different functions of the genome; gene expression, replication, and cancer. Different factors control the formation and maintenance of DNA methylation patterns. The level of activity of DNA methyltransferase (MeTase) is one factor. Recent data suggest that some oncogenic pathways can induce DNA MeTase expression, that DNA MeTase activity is elevated in cancer, and that inhibition of DNA MeTase can reverse the transformed state. What are the pharmacological consequences of our current understanding of DNA methylation patterns formation? This review will discuss the possibility that DNA MeTase inhibitors can serve as important pharmacological and therapeutic tools in cancer and other genetic diseases.

Effects of 5-azacytidine on physiological differentiation of Streptomyces antibioticus

We studied the specificity of the effect of 5-azacytidine, a DNA-methylase inhibitor that impairs Streptomyces differentiation. We showed that this compound did not affect global DNA, RNA or protein biosynthesis in submerged cultures of S. antibioticus ETHZ 7451. Among individual proteins, enzymes such as alkaline phosphatase and intracellular protease were produced in similar amounts in the presence and absence of this compound. However, the production of extracellular protease was significantly inhibited. Also DNA-methyltransferases were inhibited, indicating that DNA methylation might be involved in the regulation of differentiation. By contrast, elevated levels of the antibiotic rhodomycin resulted when 5-azacytidine was added to the culture medium. In order to determine whether there was a correlation between sporulation and altered enzymatic activities, these activities were analysed in S. antibioticus submerged cultures. Among them, alkaline phosphatase and intracellular protease activities did not show a clear correlation with sporulation. However, high levels of extracellular protease were produced during septation of hyphae. This association between extracellular protease and sporulation suggests a specific inhibitory effect of 5-azacytidine, not only on spore formation, but also on physiological differentiation.

Studies on the influence of cytosine methylation on DNA recombination and end-joining in mammalian cells

To test the influence of cytosine methylation on homologous recombination and the rejoining of DNA double strand breaks in mammalian cells, we developed a sensitive and quantitative assay system using extrachromosomal substrates. First, methylation was introduced into substrates in vitro with the prokaryotic SssI methylase, which specifically methylates the C-5 position of cytosine bases within CpG dinucleotides, mimicking the mammalian DNA methyltransferase. Next, methylated substrates were incubated in mammalian cells for a sufficient length of time to recombine or rejoin prior to substrate recovery. Results from bacterial transformation of the substrates and from direct Southern analysis demonstrate that cytosine methylation has no detectable effect on either DNA end-joining or homologous recombination. Thus, the components of the protein machinery involved in these complex processes are unaffected by the major DNA modification in mammalian cells. These results leave open the possibility that methylation may modulate the accessibility of these components to chromosomal DNA by altering local chromatin structure.

Sse8387I, a useful eight base cutter for mammalian genome analysis (influence of methylation on the activity of Sse8387I)

To develop restriction enzymes that are useful for genome analysis, we previously performed screening and isolated Sse8387I from Streptomyces sp. strain 8387. Sse8387I is a restriction enzyme that recognizes 5'-CCTGCA/GG-3' and cleaves DNA at the site shown by the diagonal (Nucleic Acid Res., 18, 5637-5640). The present study evaluated the effects of methylation that is important when Sse8387I is used for genome analysis. Sse8387I lost cleavage activity after methylation of adenine or methylation of cytosine at any site in the recognition sequence. However, the recognition sequence of Sse8387I contains no CG sequence, which is the mammalian methylation sequence. In addition, we evaluated the effects of methylation of CG at sites other than the recognition sequence. The cleavage activity of Sse8387I was maintained even when CG sequences were present immediately before or after, or near the recognition sequence, and cytosine was methylated. These results suggest that CG methylation does not affect the cleavage activity of Sse8387I. Therefore, Sse8387I seems to be very useful for mammalian genome analysis.

Ras induces a general DNA demethylation activity in mouse embryonal P19 cells

We demonstrate that expression of v-Ha-ras in mouse embryonal P19 cells results in genome-wide demethylation. Analysis of the pattern of methylation of specific genes reveals that different types of genes are demethylated in the ras transfectants: skeletal muscle specific genes, a gene specifically expressed in the adrenal cortex (c21), ubiquitous genes, and exogenously introduced sequences. Transient transfection and in vitro demethylation assays reveal that the ras transfectants express high levels of a general DNA demethylation activity. This demonstrates that the general DNA demethylation activity in mouse embryonal cells is controlled by an important cellular signal transducer and that DNA demethylase is a potential downstream effector of Ras.

Interaction of M.SssI and M.HhaI with single-base mismatched oligodeoxynucleotide duplexes

As part of an attempt to elucidate the mode of interaction of the CpG methyltransferase M.SssI with its substrate, we have prepared a series of double-stranded oligodeoxyribonucleotides containing one mismatch in the CpG recognition site. The mismatched duplexes were used to analyze the binding capabilities and enzymatic activity of M.SssI and M.HhaI (recognizes GCGC). We demonstrate here that M.SssI binds specifically to substrates containing either a C/A or G/T mismatch in the recognition sequence, i.e., 5'-GCGC/CACG-5' or 5'-GCGC/CGTG-5', respectively. The enzyme also shows significant enzymatic activity with these mismatched substrates. These results suggest that site recognition and methylation by M.SssI take place on the same strand. M.HhaI bound and methylated the C/A mismatch very efficiently, but recognition of the G/T mismatch was scarcely detectable.

CpG methylation has differential effects on the binding of YY1 and ETS proteins to the bi-directional promoter of the Surf-1 and Surf-2 genes

The divergently transcribed Surf-1 and Surf-2 housekeeping genes are separated by a bi-directional, TATA-less promoter which lies within a CpG-rich island. Here we show that CpG methylation severely reduces transcription in the direction of both Surf-1 and Surf-2. Previous work has identified three promoter elements (Su1, Su2 and Su3) which are conserved between the human and mouse Surf-1/Surf-2 promoters. These elements bind transcription factors present in human and mouse cell nuclear extracts in vitro and mutations which prevent factor binding also reduce promoter activity in vivo. Transcription initiation factor YY1 binds to the Su1 site and stimulates transcription in the direction of Surf-1 and, to a lesser extent, Surf-2. Here we show that members of the ETS family of transcription factors bind to the Su2 site. Although the Su1 factor binding site contains three CpG dinucleotides, the binding of YY1 is not affected by CpG methylation. In contrast, CpG methylation abolishes the binding of ETS proteins to the Su2 site; methylation of a single cytosine, at position 3 of the consensus ETS site, is sufficient to prevent factor binding. This direct effect on the binding of ETS proteins is, however, not in itself sufficient to explain the repression of this promoter by CpG methylation. A mutation of the Su2 site which removes the sequence CpG, but which does not prevent ETS factor binding, fails to relieve this promoter from repression by CpG methylation.