Effect of site-specific methylation on DNA modification methyltransferases and restriction endonucleases

An alternative approach to study the enzymatic specificities of the CfrBI restriction-modification system

Restriction–modification systems (RMS) are the main gene-engineering tools and a suitable model to study the molecular mechanisms of catalysis and DNA–protein interactions. Research into the catalytic properties of these enzymes, determination of hydrolysis and DNA-methylation sites remain topical. In our previous work we have cloned and sequenced the CfrBI restriction–modification system (strain Citrobacter freundii), which recognizes the nucleotide sequence 5′-CCWWGG-3′.

In this article we describe the cloning of the methyltransferase and restriction endonuclease genes (gene encoding CfrBI DNA methyltransferase (cfrBIM) and gene encoding CfrBI restriction endonuclease (cfrBIR)) separately to obtain strains overproducing the enzymes of this system. His₆-CfrBI, which had been purified to homogeneity, was used to establish the DNA-hydrolysis point in its recognition site. CfrBI was shown to cleave DNA after just the first 5′C within the recognition site and then to generate 4-nt 3′ cohesive ends (5′-C/CWWGG-3′).

To map the site of methylation by M.CfrBI, we exploited the fact that the CfrBI site partially overlaps with the recognition sites of the well-documented enzymes KpnI and ApaI. The M.CfrBI- induced hemimethylation of the internal C residue of the ApaI recognition sequence (GGGC^N4mCC) was observed to block cleavage by ApaI. In contrast, KpnI was able to digest its M.CfrBI-hemimethylated site (GGTA^N4mCC).

KpnI was used to restrict a fragment of DNA harbouring the CfrBI and KpnI sites, in which the CfrBI site was methylated in vitro by His₆-M.CfrBI using [³H]-SAM.

The subsequent separation of hydrolysis products by electrophoresis and the enumeration of incorporated [H3]-methyl groups in each of the fragments made it possible to determine that external cytosine undergoes modification in the recognition site.

Long-read single-molecule maps of the functional methylome

We report on the development of a methylation analysis workflow for optical detection of fluorescent methylation profiles along chromosomal DNA molecules. In combination with Bionano Genomics genome mapping technology, these profiles provide a hybrid genetic/epigenetic genome-wide map composed of DNA molecules spanning hundreds of kilobase pairs. The method provides kilobase pair–scale genomic methylation patterns comparable to whole-genome bisulfite sequencing (WGBS) along genes and regulatory elements. These long single-molecule reads allow for methylation variation calling and analysis of large structural aberrations such as pathogenic macrosatellite arrays not accessible to single-cell second-generation sequencing. The method is applied here to study facioscapulohumeral muscular dystrophy (FSHD), simultaneously recording the haplotype, copy number, and methylation status of the disease-associated, highly repetitive locus on Chromosome 4q.

Design of sequence-specific DNA binding molecules for DNA methyltransferase inhibition

The CpG dyad, an important genomic feature in DNA methylation and transcriptional regulation, is an attractive target for small molecules. To assess the utility of minor groove binding oligomers for CpG recognition, we screened a small library of hairpin pyrrole-imidazole polyamides targeting the sequence 5'-CGCG-3' and assessed their sequence specificity using an unbiased next-generation sequencing assay. Our findings indicate that hairpin polyamide of sequence PyImβIm-γ-PyImβIm (1), previously identified as a high affinity 5'-CGCG-3' binder, favors 5'-GCGC-3' in an unanticipated reverse binding orientation. Replacement of one β alanine with Py to afford PyImPyIm-γ-PyImβIm (3) restores the preference for 5'-CGCG-3' binding in a forward orientation. The minor groove binding hairpin 3 inhibits DNA methyltransferase activity in the major groove at its target site more effectively than 1, providing a molecular basis for design of sequence-specific antagonists of CpG methylation.

Transcriptome analyses of inhibitor-treated schistosome females provide evidence for cooperating Src-kinase and TGFβ receptor pathways controlling mitosis and eggshell formation

Schistosome parasites cause schistosomiasis, one of the most prevalent parasitemias worldwide affecting humans and animals. Constant pairing of schistosomes is essential for female sexual maturation and egg production, which causes pathogenesis. Female maturation involves signaling pathways controlling mitosis and differentiation within the gonads. In vitro studies had shown before that a Src-specific inhibitor, Herbimycin A (Herb A), and a TGFβ receptor (TβR) inhibitor (TRIKI) have physiological effects such as suppressed mitoses and egg production in paired females. As one Herb A target, the gonad-specifically expressed Src kinase SmTK3 was identified. Here, we comparatively analyzed the transcriptome profiles of Herb A- and TRIKI-treated females identifying transcriptional targets of Src-kinase and TβRI pathways. After demonstrating that TRIKI inhibits the schistosome TGFβreceptor SmTβRI by kinase assays in Xenopus oocytes, couples were treated with Herb A, TRIKI, or both inhibitors simultaneously in vitro. RNA was isolated from females for microarray hybridizations and transcription analyses. The obtained data were evaluated by Gene Ontology (GO) and Ingenuity Pathway Analysis (IPA), but also by manual classification and intersection analyses. Finally, extensive qPCR experiments were done to verify differential transcription of candidate genes under inhibitor influence but also to functionally reinforce specific physiological effects. A number of genes found to be differentially regulated are associated with mitosis and differentiation. Among these were calcium-associated genes and eggshell-forming genes. In situ hybridization confirmed transcription of genes coding for the calcium sensor hippocalcin, the calcium transporter ORAI-1, and the calcium-binding protein calmodulin-4 in the reproductive system pointing to a role of calcium in parasite reproduction. Functional qPCR results confirmed an inhibitor-influenced, varying dependence of the transcriptional activities of Smp14, Smp48, fs800, a predicted eggshell precursor protein and SmTYR1. The results show that eggshell-formation is regulated by at least two pathways cooperatively operating in a balanced manner to control egg production.

As one of the most prevalent parasitic infections worldwide, schistosomiasis is caused by blood-flukes of the genus Schistosoma. Pathology coincides with egg production, which is started upon pairing of the dioeciously living adults. A constant pairing contact is required to induce mitoses and differentiation processes in the female leading to the development of the gonads. Although long known, the molecular processes controlling gonad development or egg-production in schistosomes or other platyhelminths are largely unknown. Using an established in vitro-culture system and specific, chemical inhibitors we have obtained first evidence in previous studies for the participation of signal transduction processes playing essential roles in controlling mitoses, differentiation and egg production. In the present study we applied combinatory inhibitor treatments combined with subsequent microarray and qPCR analyses and demonstrate for the first time that cooperating Src-Kinase- und TGFβ-signaling pathways control mitoses and egg formation processes. Besides direct evidence for managing transcription of eggshell-forming genes, new target molecules of these pathways were identified. Among these are calcium-associated genes providing a first hint towards a role of this ion for reproduction. Our finding shed first light on the signaling mechanisms controlling egg formation, which is important for life-cycling and pathology.

Nucleosome mobilization by ISW2 requires the concerted action of the ATPase and SLIDE domains

The ISWI family of ATP-dependent chromatin remodelers represses transcription by changing nucleosome positioning. The interactions with extranucleosomal DNA and the requirement of a minimal length of extranucleosomal DNA by ISWI mediate the spacing of nucleosomes. ISW2 from Saccharomyces cerevisiae, a member of the ISWI family, has a conserved domain called SLIDE (SANT-like ISWI domain), whose binding to extranucleosomal DNA ~19 bp from the edge of nucleosomes is required for efficiently pushing DNA into nucleosomes and maintaining the unidirectional movement of nucleosomes, as reported here. Loss of SLIDE binding does not perturb ATPase domain binding to the SHL2 site of nucleosomes or its initial movement of DNA inside of nucleosomes. ISW2 has therefore two distinct roles in mobilizing nucleosomes, with the ATPase domain translocating and moving DNA inside nucleosomes, and the SLIDE domain facilitating the entry of linker DNA into nucleosomes.

MEGAWHOP cloning: a method of creating random mutagenesis libraries via megaprimer PCR of whole plasmids

MEGAWHOP allows for the cloning of DNA fragments into a vector and is used for conventional restriction digestion/ligation-based procedures. In MEGAWHOP, the DNA fragment to be cloned is used as a set of complementary primers that replace a homologous region in a template vector through whole-plasmid PCR. After synthesis of a nicked circular plasmid, the mixture is treated with DpnI, a dam-methylated DNA-specific restriction enzyme, to digest the template plasmid. The DpnI-treated mixture is then introduced into competent Escherichia coli cells to yield plasmids carrying replaced insert fragments. Plasmids produced by the MEGAWHOP method are virtually free of contamination by species without any inserts or with multiple inserts, and also the parent. Because the fragment is usually long enough to not interfere with hybridization to the template, various types of fragments can be used with mutations at any site (either known or unknown, random, or specific). By using fragments having homologous sequences at the ends (e.g., adaptor sequence), MEGAWHOP can also be used to recombine nonhomologous sequences mediated by the adaptors, allowing rapid creation of novel constructs and chimeric genes.

Stringent programming of DNA methylation in humans

We describe a PCR-based method called Amplified Methylation Polymorphism (AMP) for scanning genomes for DNA methylation changes. AMP detects tissue-specific DNA methylation signatures often representing junctions between methylated and unmethylated DNA close to intronexon junctions and/or associated with CpG islands. Identical AMP profiles are detected for healthy, young, monozygotic twins.

Mass spectrometric characterization of the covalent modification of the nitrogenase Fe-protein in Azoarcus sp. BH72

Nitrogenase Fe-protein modification was analyzed in the endophytic beta-proteobacterium Azoarcus sp. BH72. Application of modern MS techniques localized the modification in the peptide sequence and revealed it to be an ADP-ribosylation on Arg102 of one subunit of nitrogenase Fe-protein. A double digest with trypsin and endoproteinase Asp-N was necessary to obtain an analyzable peptide because the modification blocked the trypsin cleavage site at this residue. Furthermore, a peptide extraction protocol without trifluoroacetic acid was crucial to acquire the modified peptide, indicating an acid lability of the ADP-ribosylation. This finding was supported by the presence of a truncated version of the original peptide with Arg102 exchanged by ornithine. Site-directed mutagenesis verified that the ADP-ribosylation occurred on Arg102. With our approach, we were able to localize a labile modification within a large peptide of 31 amino acid residues. The present study provides a method suitable for the identification of so far unknown protein modifications on nitrogenases or other proteins. It represents a new tool for the MS analysis of protein mono-ADP-ribosylations.

Experimental validation of predicted mammalian erythroid cis-regulatory modules

Multiple alignments of genome sequences are helpful guides to functional analysis, but predicting cis-regulatory modules (CRMs) accurately from such alignments remains an elusive goal. We predict CRMs for mammalian genes expressed in red blood cells by combining two properties gleaned from aligned, noncoding genome sequences: a positive regulatory potential (RP) score, which detects similarity to patterns in alignments distinctive for regulatory regions, and conservation of a binding site motif for the essential erythroid transcription factor GATA-1. Within eight target loci, we tested 75 noncoding segments by reporter gene assays in transiently transfected human K562 cells and/or after site-directed integration into murine erythroleukemia cells. Segments with a high RP score and a conserved exact match to the binding site consensus are validated at a good rate (50%-100%, with rates increasing at higher RP), whereas segments with lower RP scores or nonconsensus binding motifs tend to be inactive. Active DNA segments were shown to be occupied by GATA-1 protein by chromatin immunoprecipitation, whereas sites predicted to be inactive were not occupied. We verify four previously known erythroid CRMs and identify 28 novel ones. Thus, high RP in combination with another feature of a CRM, such as a conserved transcription factor binding site, is a good predictor of functional CRMs. Genome-wide predictions based on RP and a large set of well-defined transcription factor binding sites are available through servers at http://www.bx.psu.edu/.

Flexible genetic engineering using RecA protein

With the explosion in genetic information and almost complete sequencing of the human genome, a shift in the experimental goals of molecular biologists is occurring. Instead of focusing on single genes, current attempts seek to divine the interactions of several genes and sequences. This requires increasingly complex genetic constructs and manipulations, often of very large DNA constructs, and these can be made with RecA protein-based techniques. When RecA protein combined with an oligonucleotide acts as a sequence-specific "masking tape" to block DNA from the action of DNA modifying enzymes, and can be used to direct the cleavage of DNA at single predetermined restriction endonuclease sites. This reaction is called RecA-Assisted Restriction Endonuclease (RARE) Cleavage. The reverse reaction, known as RecA-Assisted Ligation, can be used to join any two desired fragments. When one of those fragments is a vector, a desired fragment can be cloned directly without constructing a genomic library. The reagents and equipment needed are relatively inexpensive, and almost any desired genetic construct up to about 300 kb in size can be made in a straightforward manner.

Accelerated methylation of ribosomal RNA genes during the cellular senescence of Werner syndrome fibroblasts

Ribosomal DNA (rDNA) metabolism has been implicated in cellular and organismal aging. The role of rDNA in premature and normal human aging was investigated by measuring rDNA gene copy number, the level of rDNA methylation, and rRNA expression during the in vitro senescence of primary fibroblasts from normal (young and old) donors and from Werner syndrome (WS) patients. In comparison to their normal counterparts, WS fibroblasts grew slowly and reached senescence after fewer doublings. The rDNA copy number did not change significantly throughout the life span of both normal and WS fibroblasts. However, in senescent WS and normal old fibroblasts, we detected rDNA species with unusually slow electrophoretic mobility. Cellular aging in Saccharomyces cerevisiae is accompanied by the formation and accumulation of rDNA circles. Our analysis revealed that the rDNA species observed in this study were longer, linear rDNA molecules attributable to the inhibition of ECO:RI cleavage by methylation. Furthermore, isoschizomeric restriction analysis confirmed that in vitro senescence of fibroblasts is accompanied by significant increases in cytosine methylation within rDNA genes. This increased methylation is maximal during the abbreviated life span of WS fibroblasts. Despite increased methylation of rDNA in senescent cells, the steady-state levels of 28S rRNA remained constant over the life span of both normal and WS fibroblasts.

The HaeIV restriction modification system of Haemophilus aegyptius is encoded by a single polypeptide

The HaeIV restriction endonuclease (ENase) belongs to a distinct class of ENases, characterized by its ability to cleave double-stranded DNA on both sides of its recognition sequence, excising a short DNA fragment that includes the recognition sequence. The gene encoding the HaeIV ENase was cloned from Haemophilus aegyptius into pUC19 using a previously described system that does not need the knowledge that a particular ENase is produced by a bacterial strain. DNA sequence analysis of the insert contained on this plasmid identified a single open reading frame (ORF), with the predicted protein having an apparent molecular mass of approximately 110 kDa. The protein encoded by this ORF was purified to homogeneity from Escherichia coli strain ER1944 carrying the haeIVRM gene on a recombinant plasmid under the control of the inducible ara promoter. The protein possessed both ENase and methyltransferase (MTase) activities. Amino acid sequence analysis was able to identify several conserved motifs found in DNA MTases, located in the middle of the protein. The enzyme recognizes the interrupted palindromic sequence 5' GAPyNNNNNPuTC 3', cleaving double-stranded DNA on both strands upstream and downstream of the recognition sequence, releasing an approximately 33 bp fragment. The ENase possessed an absolute requirement only for Mg(+2). ATP had no influence on ENase or MTase activities. The ENase made the first strand cleavage randomly on either side of the recognition sequence, but the second cleavage occurred more slowly. The MTase activity modified symmetrically located adenine residues on both strands within the recognition sequence yielding N6-methyl adenine. Furthermore, the MTase was active as a dimer.

Molecular analysis of the P97 cilium adhesin operon of Mycoplasma hyopneumoniae

Mycoplasma hyopneumoniae causes an economically significant respiratory disease of swine called Enzootic Pneumonia. The disease process is initiated by adherence of M. hyopneumoniae to the cilia of swine respiratory epithelium through an interaction involving P97, a surface-associated protein, and cilia-specific receptors. Binding specificity is associated with a repeat region located near the C-terminus of the P97 protein. Further analysis of the DNA sequences surrounding the P97 structural gene revealed an operon composed of two ORFs, P97 and one coding for a 102.3-kDa protein designated P102. Hybridization analysis and subcloning experiments showed that the P97 adhesin-encoding gene was present as a single copy in the M. hyopneumoniae chromosome. P102 sequences, however, were found on four distinct chromosomal fragments, suggesting that multiple copies of P102 were present in the chromosome. One of these clones was identified by screening the genomic library with swine convalescent sera showing that P102 is expressed in vivo during M. hyopneumoniae infections. All copies of P102 were mapped to a single chromosomal region comprising approximately 13% of the genome (140kb), although the exact distance between the copies is not known. The function of P102 is also not known, but the translated sequence shows a prominent transmembrane domain, suggesting that it may be a surface protein.

Construction of a MluI-YAC library from barley (Hordeum vulgare L.) and analysis of YAC insert terminal regions

We describe the construction of a specific yeast artificial chromosome (YAC) library from barley (Hordeum vulgare L.) using the vector pYAC-RC. The library was generated by total digestion of high molecular weight DNA with the infrequently cutting restriction enzyme MluI. Only 10–30% of the colonies were recombinant, as visualized by red–white selection and subsequent pulsed-field gel electrophoresis analysis. About 17 000 individual recombinant YAC clones with insert sizes ranging from 50 to 700 kb, with a mean of 170 kb, were selected. No chloroplast sequences were detected and the proportion of YAC clones containing BARE–1 copia–like retroelements is about 5%. Screening of the library with a single-copy RFLP marker closely linked to the Mla locus yielded three identical clones of the same size. Insert termini of randomly chosen YAC clones were investigated with respect to their redundancy in the barley genome and compared with termini of YAC clones from an EcoRI-based YAC library, resulting in a fourfold enrichment of single-copy sequences at the MluI vector–insert junctions.Key words: yeast artificial chromosomes, YAC, Hordeum vulgare, pulsed-field gel electrophoresis.

5-methylcytosine is present in the 5' flanking region of Ha-ras in mouse liver and increases with ageing

Modifications to DNA-5-methylcytosine (5MeC) content (i.e., alterations in the level of 5MeC) constitute epigenetic events. In general, hypomethylation of a gene is necessary but not sufficient for expression, while methylated genes typically are quiescent. Ha-ras is an oncogene commonly implicated in murine liver tumorigenesis, often, though not always, involving mutation. A PCR-based approach using pre-PCR digestion with methylation-sensitive enzymes was employed to determine the 5MeC content of the 5' flanking region of this gene in (i) B6C3F1 and C57BL/6 mouse liver from young animals (4 months old) and (ii) B6C3F1 mouse liver from aged animals (24 months old). Two segments of the 5' flanking region of Ha-ras were examined. We demonstrate the presence of 5MeC in a portion of the 5' flanking region of Ha-ras that does not share characteristics of a CpG island, while a region that shares CpG island characteristics is primarily unmethylated. Differences in methylation status in these areas of Ha-ras were not observed between B6C3F1 and C57BL/6 mouse livers. Increases in methylation status were observed with ageing in B6C3F1 mouse liver. These data provide a role for methylation in regulating Ha-ras expression in mouse liver. Ha-ras in human liver has been reported to be unmethylated. There are substantial sequence differences in a key region of the 5' flanking region of Ha-ras in mice as compared to humans. These differences in DNA methylation and sequence may, in part, provide a basis for the frequent involvement of Ha-ras in mouse liver tumors and its virtual lack of involvement in human tumors.

Expansion and methylation status at FRAXE can be detected on EcoRI blots used for FRAXA diagnosis: analysis of four FRAXE families with mild mental retardation in males

The original test for the analysis of the CCG expansion at the FRAXE locus involves Southern blot analysis of HindIII digests. We show that, by using a different probe, the FRAXE mutation can be detected easily on the same EcoRI or EagI+EcoRI blots as are used for detection of FRAXA. Unexpectedly, we found that both the expansion and methylation status can be determined on a single EcoRI digest, because of the presence of a methylation-sensitive EcoRI site very close to the CCG repeat. We thus detected in a series of mentally retarded individuals previously tested for FRAXA expansion a FRAXE proband who led to the identification of a large sibship (7 of 10 children carrying a mutation). We also show that two fragile X families without FRAXA mutation that previously have been described by Oberlé et al. have the FRAXE expansion. In another family also ascertained initially by cytogenetic finding of a fragile X site, we performed the combined cytogenetic and molecular prenatal diagnosis of a mutated male fetus. All nine males (>3 years old) in whom we found a methylated mutation had mild mental retardation. Our results suggest that the threshold of repeat length for abnormal methylation and fragile-site expression may be smaller at FRAXE than at FRAXA.

Germ line-specific expression of intracisternal A-particle retrotransposons in transgenic mice

Intracisternal A-particle (IAP) sequences are endogenous retrovirus-like mobile elements, or retrotransposons, present at 1,000 copies in the mouse genome. These elements transpose in a replicative manner via an RNA intermediate and its reverse transcription, and their transposition should therefore be tightly controlled by their transcription level. To analyze the in vivo pattern of expression of these retrovirus-like elements, we constructed several independent transgenic mice with either a complete IAP element marked with an intron or with the IAP promoter, or long terminal repeat (LTR), alone controlling the expression of a lacZ reporter gene with a nuclear localization signal. For all transgenic lines analyzed, IAP expression as determined by reverse transcription-PCR analysis was found to be essentially restricted to the male germ line. Furthermore, in situ 5-bromo-4-chloro-3-indolyl-beta-D-galactopyranoside (X-Gal) staining of all organs disclosed specific beta-galactosidase-positive blue cells only within the testis, found as patches along the seminiferous tubules and often organized as assemblies of 2, 4, 8, or 16 cells. Histochemical analyses of tissues from 13.5-day-old embryos to adults demonstrated that this LTR activity is restricted to gonocytes and premeiotic undifferentiated spermatogonia. Finally, analysis of the methylation status of both transgenes and endogenous IAP LTRs demonstrated identical patterns, with methylation in somatic tissues and hypomethylation in the testis. Transgenic mice therefore reveal an intrinsic, highly restricted IAP expression which had escaped detection in previous global Northern (RNA) blot analyses and with possible strong biological relevance, as IAP activation specifically within the germ line might be a way to generate diversity at the evolutionary level without being deleterious to individuals.

Binding of histone H1 to DNA is indifferent to methylation at CpG sequences

The possibility that histone H1 binds preferentially to DNA containing 5-methylcytosine in the dinucleotide CpG is appealing, as it could help to explain the repressive effects of methylation on gene activity. In this study, the affinity of purified H1 for methylated and non-methylated DNA sequences has been tested using both naked DNA and chromatin. Based on a variety of assays (bandshifts, filter-binding assays, Southwestern blots, and nuclease sensitivity assays), we conclude that H1 has no significant preference for binding to naked methylated DNA. Similarly, H1 showed the same affinities for methylated and non-methylated DNA when assembled into chromatin in a Xenopus oocyte extract. Thus potential cooperative interaction of H1 with polynucleosomal complexes is not enhanced by the presence of DNA methylation.

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

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

Interaction of the MvaI and SsoII methyltransferases with DNAs altered at the central base pair of the recognition sequence

The interaction of the MvaI and SsoII DNA methyltransferases (MTases; M.MVaI and M.SsoII, respectively) with a set of synthetic DNA duplexes, containing a M.MvaI and M.SsoII recognition site (CCWGG), was investigated. In these DNA duplexes dA or dT of the recognition site was replaced by nucleoside analogs with modified sugar moieties and heterocyclic bases (2'-deoxy-2'-fluorouridine (flU), 1-(beta-D-2'-deoxy-threo-pentofuranosyl)thymine (xT), 1-(beta-D-3'-deoxy-threo-pentofuranosyl)uracil (tU)), or by 1,3-propanediol (Prd). A new approach for monitoring methylation of each strand of DNA duplexes by MTases was developed. It allowed the determination of the influence of the modification in one DNA strand on the methylation of the other. In most cases, for both M.MvaI and M.SsoII, sugar analog-containing duplexes showed inhibition of methylation of only the modified strand. Prd-containing DNA duplexes were not substrates for M.MvaI. M.SsoII did not methylate DNA duplexes in which the dT residue was replaced by Prd.

Sequence motifs characteristic for DNA [cytosine-N4] and DNA [adenine-N6] methyltransferases. Classification of all DNA methyltransferases

Two additional conserved motifs (CM), CM Is and CM III, have been found in addition to well-known CM I and CM II within the primary amino acid sequences of almost all m6A- and m4C-methyltransferases (MTases). The boundaries of all four CM were defined and their consensus sequences characteristic both for different classes, as well as for all N-MTases, were derived. Some regular deviations at fixed positions of the consensus sequences CM Is, CM I and CM II, typical for separate classes of N-MTases, were presumed to correlate. A possible structural basis for the supposed interregional correlations is discussed and experiments for verification of the assumed interactions between CM are suggested. A classification scheme for all N-MTases is provided.

Partial purification and characterisation of Bfi57I and Bfi89I, restriction endonucleases from different strains of Butyrivibrio fibrisolvens

Two class-II restriction endonucleases (ENases), Bfi57I and Bfi89I, were partially purified from Butyrivibrio fibrisolvens OB157 and OB189, respectively. Bfi57I (isoschizomer Sau3AI) had the DNA recognition/cleavage sequence 5'-/GATC-3'; it is not inhibited by Dam methylation, but is partially inhibited by M.BamHI methylation. Bfi89I (isoschizomer EaeI) had the recognition/cleavage sequence 5'-Y/GGCCR-3'; unlike the EaeI isoschizomer it is not fully inhibited by M.HaeIII methylation.

DNA binding mode of class-IIS restriction endonuclease FokI revealed by DNA footprinting analysis

We investigate the interaction of FokI with its DNA recognition sequence by several footprinting techniques. Methylation of three guanine bases in the recognition sequence 5'-GGATG-3' is strongly protected by FokI binding, whereas other guanine bases are not masked from the modification. In footprinting using the methidiumpropyl-EDTA-Fe(II) complex, binding of FokI strongly inhibits cleavage by the footprinting reagent at and near the recognition sequence. In high-resolution footprinting techniques using hydroxyl radical and the bleomycin-Fe(II) complex, all footprints in each binding site clearly face one side of the DNA helix. Interference analysis with FokI digestion by preethylation of phosphate groups suggests that essential phosphates for FokI digestion are located at and near the recognition sequence and the cleavage site. Evidently, the results indicate that (i) the sequence-recognition of FokI occurs in the major groove and that (ii) the enzyme interacts with its target DNA from one side of the DNA helix.

Ectopic expression of a viral adenine methyltransferase gene in tobacco

Plant genomes contain both methylated adenine and cytosine residues although the roles of these methylations are not well understood. A chlorella virus adenine methyltransferase gene under the control of cauliflower mosaic virus 35S promoter in a binary plant transformation vector was expressed both in transgenic tobacco plants and transformed tobacco calli. The transgenic plants as well as transformed calli produced functional adenine methyltransferase enzyme, but the level of expression was higher in tobacco calli. A transgenic tobacco cell line that expressed the methyltransferase enzyme and carried an Arabidopsis cab3 gene containing a single target site for the adenine methyltransferase enzyme showed that the adenine residue was not methylated. HPLC analysis of genomic DNA from transgenic calli also showed no detectable levels of methylated adenine residues.

Human breast and colon cancers exhibit alterations of DNA methylation patterns at several DNA segments on chromosomes 11p and 17p

In breast and colon adenocarcinomas methylation patterns at CCGG sites of several loci located on the short arm of chromosome 11 were determined by Southern blot analysis. Results obtained indicate that all tumor samples (20/20) exhibit DNA methylation changes when compared to their normal counterparts. In colon tumors, gamma-globin gene is usually hypomethylated (9/10), whereas Ha-ras gene, which is located in the same region, retains an unmodified DNA methylation pattern. Hypomethylation of parathyroid hormone (5/10) and catalase genes (4/10) are also frequently detected in colon tumor specimens. For the catalase gene the region around exon 2 is the only one which is affected by these changes. In breast adenocarcinoma, modifications of the methylation patterns are less frequently observed. However, hypomethylation of the gamma-globin gene is a very common event in these tumors (8/10), and it is also detected (2/2) in lobular carcinoma in situ which is an early step in breast tumorigenesis. In addition, hypermethylation of a CpG island is also observed at the locus 17p13.3 in both colon (5/5) and breast (4/9) adenocarcinomas. In the tumoral tissues analyzed these hypermethylations are not associated with the hypermethylation of the 5' flanking sequences which contain a limited amount of CpG. Some of these alterations seem, therefore, to be tumor and sequence specific.

Identification of the XorII methyltransferase gene and a vsr homolog from Xanthomonas oryzae pv. oryzae

The gene encoding the XorII methyltransferase (M.XorII) was cloned from Xanthomonas oryzae pv. oryzae and characterized in Escherichia coli. The M.XorII activity was localized to a 3.1 kb BamHI-BstXI fragment, which contained two open reading frames (ORFs) of 1272 nucleotides (424 amino acids) and 408 nucleotides (136 amino acids). Ten polypeptide domains conserved in other M5 cytosine methyltransferases (MTases) were identified in the deduced amino acid sequence of the 1272 ORF. E. coli Mrr+ strains were transformed poorly by plasmids containing the XorII MTase gene, indicating the presence of at least one MCG in the recognition sequence for M.XorII (CGATCG). The 408 nucleotide ORF was 36% identical at the amino acid level to sequences of the E. coli dem-vsr gene, which is required for very short patch repair. X. oryzae pv. oryzae genomic DNA that is resistant to digestion by PvuI and XorII hybridizes with a 7.0 kb fragment containing the XorII MTase gene and vsr homolog, whereas DNA from strains that lack M.XorII activity do not hybridize with the fragment.

The dam and dcm strains of Escherichia coli--a review

The construction of a variety of strains deficient in the methylation of adenine and cytosine residues in DNA by the methyltransferases (MTases) Dam and Dcm has allowed the study of the role of these enzymes in the biology of Escherichia coli. Dam methylation has been shown to play a role in coordinating DNA replication initiation, DNA mismatch repair and the regulation of expression of some genes. The regulation of expression of dam has been found to be complex and influenced by five promoters. A role for Dcm methylation in the cell remains elusive and dcm- cells have no obvious phenotype. dam- and dcm- strains have a range of uses in molecular biology and bacterial genetics, including preparation of DNA for restriction by some restriction endonucleases, for transformation into other bacterial species, nucleotide sequencing and site-directed mutagenesis. A variety of assays are available for rapid detection of both the Dam and Dcm phenotypes. A number of restriction systems in E. coli have been described which recognise foreign DNA methylation, but ignore Dam and Dcm methylation. Here, we describe the most commonly used mutant alleles of dam and dcm and the characteristics of a variety of the strains that carry these genes. A description of several plasmids that carry dam gene constructs is also included.

Paramutation, an allelic interaction, is associated with a stable and heritable reduction of transcription of the maize b regulatory gene

The b gene of maize encodes a transcriptional activator of anthocyanin pigment biosynthetic genes. Certain b alleles undergo paramutation: a unidirectional, heritable alteration of one allele caused by the presence of another allele. B-I (intensely pigmented plant) is always changed to B' (weakly pigmented plant) in the B'/B-I heterozygote, such that all progeny receive the B' allele. The "new" B', which was B-I in the previous generation, is weakly pigmented and fully capable of changing another B-I allele into B'. It was not previously known whether paramutation is associated with altered b expression, altered B protein function or both. Our results show that B' acts in trans to suppress the transcription of B-I, with transcription remaining low in subsequent generations, even when the original B' allele segregates away. The products of B-I and B' are equally capable of activating the transcription of their target genes, indicating they are functionally equivalent. Genomic restriction maps, DNA sequence and methylation of B' and B-I were compared. Despite dramatic differences in phenotype and transcription of B' and B-I, no evidence for rearrangements, changes in sequence or changes in methylation was found. These results provide no support for models involving "dominant negative" proteins, gene conversion or transposable element interactions. We suggest that b paramutation involves a physical interaction between the alleles that suppresses transcription and promotes a change in chromatin structure that is heritable.

Isolation and characterization of the modification methylase M.SauLPI from Streptomyces aureofaciens B-96

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Hypomethylation of classical satellite DNA and chromosome instability in lymphoblastoid cell lines

To determine possible relationships between DNA hypomethylation and chromosome instability, human lymphoblastoid cell lines from different genetic constitutions were studied with regard to 1) uncoiling and rearrangements, which preferentially affect the heterochromatic segments of chromosomes 1 and 16; 2) the methylation status of the tandemly repetitive sequences (classical satellite and alphoid DNAs) from chromosomes 1 and 16, and of the L1Hs interspersed repetitive sequences. The methylation status largely varied from cell line to cell line, but for a given cell line, the degree of methylation was similar for all the repetitive DNAs studied. Two cell lines, one obtained from a Fanconi anemia patient and the other from an ataxia telangiectasia patient were found to be heavily hypomethylated. The heterochromatic segments of their chromosomes 1 and 16 were more frequently elongated and rearranged than those from other cell lines, which were found to be less hypomethylated. Thus, in these lymphoblastoid cell lines, alterations characterized by uncoiling and rearrangements of heterochromatic segments from chromosomes 1 and 16 seem to correlate with the hypomethylation of their repetitive DNAs. Two-color in situ hybridizations demonstrated that these elongations and rearrangements involved only classical satellite-DNA-containing heterochromatin. This specificity may be related to the excess of breakages affecting the chromosomes carrying these structures in a variety of pathological conditions.

Leptospira genomes are modified at 5'-GTAC

Genomic DNAs of 14 strains from seven species of the spirochete Leptospira were resistant to cleavage by the restriction endonuclease RsaI (5'-GTAC). A modified base comigrating with m4C was detected by chromatography. Genomic DNAs from other spirochetes, Borrelia group VS461, and Serpulina strains were not resistant to RsaI digestion. Modification at 5'-GTAm4C may occur in most or all strains of all species of Leptospira but not in all genera of spirochetes. Genus-wide DNA modification has rarely been observed in bacteria.

De novo methylation causes a tissue-specific polymorphic EcoRI pattern at the human epidermal growth factor receptor gene

A novel restriction polymorphism, probably due to tissue-specific methylation, has been identified at the human epidermal-growth-factor-receptor (EGF-R) gene. DNA isolated from smooth muscle showed altered EcoRI restriction bands when hybridized with different fragments of the EGF-R cDNA. These bands were absent in brain or leucocyte DNA samples from the same individuals. Three restriction sites, partly resistant to cleavage by EcoRI, were characterized in muscle DNA which were not clustered but instead were scattered along the gene. The flanking sequences of one of these resistant EcoRI sites were determined. This specific EcoRI site was followed by a 3'-guanosine generating a methylatable EcoRI sequence. This suggests that the failure to digest to completion these EcoRI sites was due to modification by methylation. In addition, we noted that EcoRI sites were affected at both alleles, indicating that de novo methylation changes, and not methylation events related to genomic imprinting, would cause the muscle-specific EcoRI pattern. Also abnormal restriction fragments with XbaI were observed in muscle DNA. A large number of unrelated muscle DNA samples have been analysed, and all of them displayed an identical EcoRI polymorphic pattern, suggesting that DNA modification by de novo methylation events could be functionally relevant.

Sensitivity of HincII to CpG methylation

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Comprehensive restriction enzyme lists to update any DNA sequence computer program

Restriction enzyme lists are presented for the practical working geneticist to update any DNA computer program. These lists combine formerly scattered information and contain all presently known restriction enzymes with a unique recognition sequence, a cut site, or methylation (in)sensitivity. The lists are in the shortest possible form to also be functional with small DNA computer programs, and will produce clear restriction maps without any redundancy or loss of information. The lists discern between commercial and noncommercial enzymes, and prototype enzymes and different isoschizomers are cross-referenced. Differences in general methylation sensitivities and (in)sensitivities against Dam and Dcm methylases of Escherichia coli are indicated. Commercial methylases and intron-encoded endonucleases are included. An address list is presented to contact commercial suppliers. The lists are constantly updated and available in electronic form as pure US ASCII files, and in formats for the DNA computer programs DNA-Strider for Apple Macintosh, and DNAsis for IBM personal computers or compatibles via e-mail from the internet address: NETSERV@EMBL-HEIDELBERG.DE by sending only the message HELP RELIBRARY.

Restriction endonuclease cleavage of 5-methyl-deoxycytosine hemimethylated DNA at high enzyme-to-substrate ratios

We have investigated the ability of a large number of restriction enzymes to digest non-canonically hemimethylated DNA at high enzyme-to-substrate ratios. A single-stranded unmethylated phagemid was used as a template to complete synthesis of the second strand using 5-methyl-dCTP to substitute for all the deoxycytosine residues. A fragment of this double-stranded hemimethylated DNA which contains the multiple cloning site region was used as a substrate. For all the enzymes tested, at least some degree of protection from digestion is observed. Sites completely protected from digestion by their cognate enzymes are SalI, BstXI, SacI, SacII, SmaI, SstI, XhoI, PstI, HinfI, BamHI and AccI. Sites partially protected from digestion by their cognate enzymes are XbaI, HindIII, KpnI, SpeI, ClaI, EcoRI and PvuII. Knowledge of the sensitivity of commonly used restriction enzymes to hemimethylated substrates is useful for several applications, which will be discussed.

Characterization of Chlorella virus PBCV-1 CviAII restriction and modification system

A second DNA site-specific (restriction) endonuclease (R.CviAII) and its cognate adenine DNA methyltransferase (M.CviAII) were isolated from virus PBCV-1 infected Chlorella strain NC64A cells. R.CviAII, a heteroschizomer of the bacterial restriction endonuclease NlaIII, recognizes the sequence CATG, and does not cleave CmATG sequences. However, unlike NlaIII, which cleaves after the G and does not cleave either CmATG or mCATG sequences, CviAII cleaves between the C and A and is unaffected by mCATG methylation. The M.CviAII and R.CviAII genes were cloned and their DNA sequences were determined. These genes are tandemly arranged head-to-tail such that the TAA termination codon of the M.CviAII methyltransferase gene overlaps the ATG translational start site of R.CviAII endonuclease. R.CviAII is the first chlorella virus site-specific endonuclease gene to be cloned and sequenced.

Identification of the CTAG-recognizing restriction-modification systems MthZI and MthFI from Methanobacterium thermoformicicum and characterization of the plasmid-encoded mthZIM gene

Two CTAG-recognizing restriction and modification (R/M) systems, designated MthZI and MthFI, were identified in the thermophilic archaeon Methanobacterium thermoformicicum strains Z-245 and FTF, respectively. Further analysis revealed that the methyltransferase (MTase) genes are plasmid-located in both strains. The plasmid pFZ1-encoded mthZIM gene of strain Z-245 was further characterized by subcloning and expression studies in Escherichia coli followed by nucleotide sequence analysis. The mthZIM gene is 1065 bp in size and may code for a protein of 355 amino acids (M(r) 42,476 Da). The deduced amino acid sequence of the M.MthZI enzyme shares substantial similarity with four distinct regions from several m4C- and m6A-MTases, and contains the TSPPY motif that is so far only found in m4C-MTases. Partially overlapping with the mthZIM gene and in reverse orientation, an additional ORF was identified with a size of 606 bp potentially coding for a protein of 202 amino acids (M(r) 23.710 Da). This ORF is suggested to encode the corresponding endonuclease R.MthZI.

Cloning and sequence analysis of the StsI restriction-modification gene: presence of homology to FokI restriction-modification enzymes

StsI endonuclease (R.StsI), a type IIs restriction endonuclease found in Streptococcus sanguis 54, recognizes the same sequence as FokI but cleaves at different positions. A DNA fragment that carried the genes for R.StsI and StsI methylase (M.StsI) was cloned from the chromosomal DNA of S.sanguis 54, and its nucleotide sequence was analyzed. The endonuclease gene was 1,806 bp long, corresponding to a protein of 602 amino acid residues (M(r) = 68,388), and the methylase gene was 1,959 bp long, corresponding to a protein of 653 amino acid residues (M(r) = 76,064). The assignment of the endonuclease gene was confirmed by analysis of the N-terminal amino acid sequence. Genes for the two proteins were in a tail-to-tail orientation, separated by a 131-nucleotide intercistronic region. The predicted amino acid sequences between the StsI system and the FokI system showed a 49% identity between the methylases and a 30% identity between the endonucleases. The sequence comparison of M.StsI with various methylases showed that the N-terminal half of M.StsI matches M.NIaIII, and the C-terminal half matches adenine methylases that recognize GATC and GATATC.