Effect of DNA methylation on the binding of vertebrate and plant proteins to DNA

Methylation status and expression patterns of myomaker gene play important roles in postnatal development in the Japanese flounder (Paralichthys olivaceus)

Myomaker is a membrane protein that plays a crucial role in the fusion of myoblasts during muscle growth. DNA methylation, a significant factor, regulates gene expression. The aim of this study was to examine the methylation and mRNA expression patterns of the myomaker gene during 8 different postnatal developmental stages in the Japanese flounder (L: 7 days post hatch (dph); M1: 21 dph; M2: 28 dph; M3: 35 dph; J1: 90 dph; J2: 180 dph; A1: 24 months; A2: 36 months). Muscle tissue samples were taken from Japanese flounder at different postnatal development stages to measure the extent of DNA methylation and gene expression. Methylation level in the promoter and exon 1 of myomaker was measured using bisulfite sequencing, and the relative expression of myomaker during each developmental stage was measured by quantitative PCR. The relative expression levels of myomaker were up-regulated from stages L to M2, M3 to J2, and methylation of myomaker was negatively correlated with mRNA expression. Furthermore, the CpG site located at -26 bp in the promoter was the lowest methylated region in all developmental stages. These results offer a basis for understanding the mechanism by which myomaker regulates muscle formation during postnatal development.

Investigating Pathogenic and Hepatocarcinogenic Mechanisms from Normal Liver to HCC by Constructing Genetic and Epigenetic Networks via Big Genetic and Epigenetic Data Mining and Genome-Wide NGS Data Identification

The prevalence of hepatocellular carcinoma (HCC) is still high worldwide because liver diseases could develop into HCC. Recent reports indicate nonalcoholic fatty liver disease and nonalcoholic steatohepatitis (NAFLD&NASH) and primary biliary cirrhosis and primary sclerosing cholangitis (PBC&PSC) are significant of HCC. Therefore, understanding the cellular mechanisms of the pathogenesis and hepatocarcinogenesis from normal liver cells to HCC through NAFLD&NASH or PBC&PSC is a priority to prevent the progression of liver damage and reduce the risk of further complications. By the genetic and epigenetic data mining and the system identification through next-generation sequencing data and its corresponding DNA methylation profiles of liver cells in normal, NAFLD&NASH, PBC&PSC, and HCC patients, we identified the genome-wide real genetic and epigenetic networks (GENs) of normal, NAFLD&NASH, PBC&PSC, and HCC patients. In order to get valuable insight into these identified genome-wide GENs, we then applied a principal network projection method to extract the corresponding core GENs for normal liver cells, NAFLD&NASH, PBC&PSC, and HCC. By comparing the signal transduction pathways involved in the identified core GENs, we found that the hepatocarcinogenesis through NAFLD&NASH was induced through DNA methylation of HIST2H2BE, HSPB1, RPL30, and ALDOB and the regulation of miR-21 and miR-122, and the hepatocarcinogenesis through PBC&PSC was induced through DNA methylation of RPL23A, HIST2H2BE, TIMP1, IGF2, RPL30, and ALDOB and the regulation of miR-29a, miR-21, and miR-122. The genetic and epigenetic changes in the pathogenesis and hepatocarcinogenesis potentially serve as potential diagnostic biomarkers and/or therapeutic targets.

DNA methylation and differentiation: silencing, upregulation and modulation of gene expression

Differentiation-related DNA methylation is receiving increasing attention, partly owing to new, whole-genome analyses. These revealed that cell type-specific differential methylation in gene bodies is more frequent than in promoters. We review new insights into the functionality of DNA methylation during differentiation, with emphasis on the methylomes of myoblasts, myotubes and skeletal muscle versus non-muscle samples. Biostatistical analyses of data from reduced representation bisulfite sequencing are discussed. Lastly, a model is presented for how promoter and intragenic DNA hypermethylation affect gene expression, including increasing the efficiency of polycomb silencing at some promoters, downmodulating other promoters rather than silencing them, counteracting enhancers with heterologous specificity, altering chromatin conformation by inhibiting the binding of CTCF, modulating mRNA transcript levels by inhibiting overlapping promoters of noncoding RNA genes or by regulating the use of alternative mRNA promoters, modulating transcription termination, regulating alternative splicing and acting as barriers to the spread of activating chromatin.

A multi-tissue analysis identifies HLA complex group 9 gene methylation differences in bipolar disorder

Epigenetic studies of DNA and histone modifications represent a new and important activity in molecular investigations of human disease. Our previous epigenome-wide scan identified numerous DNA methylation differences in post-mortem brain samples from individuals affected with major psychosis. In this article, we present the results of fine mapping DNA methylation differences at the human leukocyte antigen (HLA) complex group 9 gene (HCG9) in bipolar disorder (BPD). Sodium bisulfite conversion coupled with pyrosequencing was used to interrogate 28 CpGs spanning ∼700 bp region of HCG9 in 1402 DNA samples from post-mortem brains, peripheral blood cells and germline (sperm) of bipolar disease patients and controls. The analysis of nearly 40 000 CpGs revealed complex relationships between DNA methylation and age, medication as well as DNA sequence variation (rs1128306). Two brain tissue cohorts exhibited lower DNA methylation in bipolar disease patients compared with controls at an extended HCG9 region (P=0.026). Logistic regression modeling of BPD as a function of rs1128306 genotype, age and DNA methylation uncovered an independent effect of DNA methylation in white blood cells (odds ratio (OR)=1.08, P=0.0077) and the overall sample (OR=1.24, P=0.0011). Receiver operating characteristic curve A prime statistics estimated a 69-72% probability of correct BPD prediction from a case vs control pool. Finally, sperm DNA demonstrated a significant association (P=0.018) with BPD at one of the regions demonstrating epigenetic changes in the post-mortem brain and peripheral blood samples. The consistent multi-tissue epigenetic differences at HCG9 argue for a causal association with BPD.

DNA hypomethylation in cancer cells

DNA hypomethylation was the initial epigenetic abnormality recognized in human tumors. However, for several decades after its independent discovery by two laboratories in 1983, it was often ignored as an unwelcome complication, with almost all of the attention on the hypermethylation of promoters of genes that are silenced in cancers (e.g., tumor-suppressor genes). Because it was subsequently shown that global hypomethylation of DNA in cancer was most closely associated with repeated DNA elements, cancer linked-DNA hypomethylation continued to receive rather little attention. DNA hypomethylation in cancer can no longer be considered an oddity, because recent high-resolution genome-wide studies confirm that DNA hypomethylation is the almost constant companion to hypermethylation of the genome in cancer, just usually (but not always) in different sequences. Methylation changes at individual CpG dyads in cancer can have a high degree of dependence not only on the regional context, but also on neighboring sites. DNA demethylation during carcinogenesis may involve hemimethylated dyads as intermediates, followed by spreading of the loss of methylation on both strands. In this review, active demethylation of DNA and the relationship of cancer-associated DNA hypomethylation to cancer stem cells are discussed. Evidence is accumulating for the biological significance and clinical relevance of DNA hypomethylation in cancer, and for cancer-linked demethylation and de novo methylation being highly dynamic processes.

Environmental studies of schizophrenia through the prism of epigenetics

Traditionally, etiological research of schizophrenia has been focused on elucidating predisposing genes and environmental risk factors. While numerous putative environmental hazards have been suggested, inconsistencies and methodological limitations of epidemiological studies have made it difficult to identify even a single exogenous cause of schizophrenia. Furthermore, there is increasing evidence that environmental risk factors may not play as much of a significant role in schizophrenia as previously suspected. In this article, we argue that molecular epigenetic studies can overcome the complexities of traditional epidemiological studies and may become a productive line of research in understanding the nongenetic mechanisms of schizophrenia.

ICF, an immunodeficiency syndrome: DNA methyltransferase 3B involvement, chromosome anomalies, and gene dysregulation

The immunodeficiency, centromeric region instability, and facial anomalies syndrome (ICF) is the only disease known to result from a mutated DNA methyltransferase gene, namely, DNMT3B. Characteristic of this recessive disease are decreases in serum immunoglobulins despite the presence of B cells and, in the juxtacentromeric heterochromatin of chromosomes 1 and 16, chromatin decondensation, distinctive rearrangements, and satellite DNA hypomethylation. Although DNMT3B is involved in specific associations with histone deacetylases, HP1, other DNMTs, chromatin remodelling proteins, condensin, and other nuclear proteins, it is probably the partial loss of catalytic activity that is responsible for the disease. In microarray experiments and real-time RT-PCR assays, we observed significant differences in RNA levels from ICF vs. control lymphoblasts for pro- and anti-apoptotic genes (BCL2L10, CASP1, and PTPN13); nitrous oxide, carbon monoxide, NF-kappaB, and TNFalpha signalling pathway genes (PRKCH, GUCY1A3, GUCY1B3, MAPK13; HMOX1, and MAP4K4); and transcription control genes (NR2F2 and SMARCA2). This gene dysregulation could contribute to the immunodeficiency and other symptoms of ICF and might result from the limited losses of DNA methylation although ICF-related promoter hypomethylation was not observed for six of the above examined genes. We propose that hypomethylation of satellite 2 at 1qh and 16qh might provoke this dysregulation gene expression by trans effects from altered sequestration of transcription factors, changes in nuclear architecture, or expression of noncoding RNAs.

Epigenetics of Complex Diseases: From General Theory to Laboratory Experiments

Despite significant effort, understanding the causes and mechanisms of complex non-Mendelian diseases remains a key challenge. Although numerous molecular genetic linkage and association studies have been conducted in order to explain the heritable predisposition to complex diseases, the resulting data are quite often inconsistent and even controversial. In a similar way, identification of environmental factors causal to a disease is difficult. In this article, a new interpretation of the paradigm of "genes plus environment" is presented in which the emphasis is shifted to epigenetic misregulation as a major etiopathogenic factor. Epigenetic mechanisms are consistent with various non-Mendelian irregularities of complex diseases, such as the existence of clinically indistinguishable sporadic and familial cases, sexual dimorphism, relatively late age of onset and peaks of susceptibility to some diseases, discordance of monozygotic twins and major fluctuations on the course of disease severity. It is also suggested that a substantial portion of phenotypic variance that traditionally has been attributed to environmental effects may result from stochastic epigenetic events in the cell. It is argued that epigenetic strategies, when applied in parallel with the traditional genetic ones, may significantly advance the discovery of etiopathogenic mechanisms of complex diseases. The second part of this chapter is dedicated to a review of laboratory methods for DNA methylation analysis, which may be useful in the study of complex diseases. In this context, epigenetic microarray technologies are emphasized, as it is evident that such technologies will significantly advance epigenetic analyses in complex diseases.

Cancer-linked DNA hypomethylation and its relationship to hypermethylation

It is not surprising that cancer, a kind of derangement of development, hijacks DNA methylation, which is necessary for normal mammalian embryogenesis. Both decreases and increases in DNA methylation are a frequent characteristic of a wide variety of cancers. There is often more hypomethylation than hypermethylation of DNA during carcinogenesis, leading to a net decrease in the genomic 5-methylcytosine content. Although the exact methylation changes between different cancers of the same type are not the same, there are cancer type-specific differences in the frequency of hypermethylation or hypomethylation of certain genomic sequences. These opposite types of DNA methylation changes appear to be mostly independent of one another, although they may arise because of a similar abnormality leading to long-lasting epigenetic instability in cancers. Both tandem and interspersed DNA repeats often exhibit cancer-associated hypomethylation. However, one of these repeated sequences (NBL2) displayed predominant increases in methylation in some ovarian carcinomas and Wilms tumors and decreases in others. Furthermore, decreases and increases in CpG methylation can be interspersed within a small subregion of the 1.4-kb repeat unit of these tandem arrays. While the transcription-silencing role of DNA hypermethylation at promoters of many tumor-suppressor genes is clear, the biological effects of cancer-linked hypomethylation of genomic DNA are less well understood. Evidence suggests that DNA hypomethylation functions in direct or indirect control of transcription and in destabilizing chromosomal integrity. Recent studies of cancer-linked DNA hypomethylation indicate that changes to DNA methylation during tumorigenesis and tumor progression have a previously underestimated plasticity and dynamic nature.

Complex disease, gender and epigenetics

Gender differences in susceptibility to complex disease such as asthma, diabetes, lupus, autism and major depression, among numerous other disorders, represent one of the hallmarks of non-Mendelian biology. It has been generally accepted that endocrinological differences are involved in the sexual dimorphism of complex disease; however, specific molecular mechanisms of such hormonal effects have not been elucidated yet. This paper will review evidence that sex hormone action may be mediated via gene-specific epigenetic modifications of DNA and histones. The epigenetic modifications can explain sex effects at DNA sequence polymorphisms and haplotypes identified in gender-stratified genetic linkage and association studies. Hormone-induced DNA methylation and histone modification changes at specific gene regulatory regions may increase or reduce the risk of a disease. The epigenetic interpretation of sexual dimorphism fits well into the epigenetic theory of complex disease, which argues for the primary pathogenic role of inherited and/or acquired epigenetic misregulation rather than DNA sequence variation. The new experimental strategies, especially the high throughput microarray-based epigenetic profiling, can be used for testing the epigenetic hypothesis of gender effects in complex diseases.

Methylation of the asparagine synthetase promoter in human leukemic cell lines is associated with a specific methyl binding protein

We have examined the methylation profiles of the asparagine synthetase (ASY) promoter in a number of human leukemic cell lines in relation to their asparagine (ASN) requirements in vitro. Cells in which the promoter is highly methylated are auxotrophs and express ASY at very low levels. Electromobility shift assays (EMSA) of nuclear extracts with oligomers from the promoting region show, in addition to recognized transcription factor binding, a novel methyl binding protein specific for a 12 base consensus sequence, which includes a single methylated CpG. This sequence overlaps that of the amino-acid response unit of the ASY promoter, which is activated byATF4 and C/EBP. Competition by the methyl binding protein could account for the observed failure of the methylated promoter to bind these transcription factors and consequently, although other mechanisms can also be operative, for the specific repression of the gene. The ASY methyl binding protein (ASMB) is present in leukemic lymphoid and myeloid cells irrespective of their methylation status, and in normal lymphocytes after phytohemagglutinin stimulation. It has been purified by affinity chromatography and has a molecular size of 40 kDa in 10% SDS-polyacrylamide gels.

DNA methylation has a local effect on transcription and histone acetylation

DNA methylation is commonly associated with gene silencing, and a link between histone deacetylation and DNA methylation has been established. However, the transcriptional impact of the position and length of methylated zones relative to the promoter and the coding region of a gene remains quite unclear. This study investigates the impact of regional methylation on transcription and the relationship between DNA methylation and histone acetylation. Using patch-methylated stable episomes in human cells, we establish the pivotal importance of the location of DNA methylation in the regulation of transcription. We further demonstrate that the size of the methylated patch is not a key determinant for transcriptional suppression. The impact of DNA methylation on transcription is greater when it is in the transcription unit, and it is primarily a local effect. However, methylation outside of the transcription unit may potentiate the effect of methylation within the transcription unit. Acetylated histones are associated with unmethylated DNA and are nearly absent from methylated DNA regions. This association appears to be local and does not propagate along the DNA.

Rapid quantification of DNA methylation by high performance capillary electrophoresis

The actual methods to evaluate total DNA methylation based on high performance liquid chromatography (HPLC) are long and tedious due to the specific running buffers required. In this work, a new open-tube capillary electrophoresis system has been applied to the separation of acid hydrolyzed genomic DNA and so, to the evaluation of genomic DNA methylation. Several running conditions were tested but separation of cytosine and 5-methyl-cytosine was only possible by sodium dodecyl sulfate (SDS) micelle system. The importance of sample dissolution preparation has also been demonstrated. The results of this study open up the possibility of quantification of the relative methylation degree of rapid genomic DNA by a simple method based on high performance capillary electrophoresis (HPCE).

DNA METHYLATION IN PLANTS

Methylation of cytosine residues in DNA provides a mechanism of gene control. There are two classes of methyltransferase in Arabidopsis; one has a carboxy-terminal methyltransferase domain fused to an amino-terminal regulatory domain and is similar to mammalian methyltransferases. The second class apparently lacks an amino-terminal domain and is less well conserved. Methylcytosine can occur at any cytosine residue, but it is likely that clonal transmission of methylation patterns only occurs for cytosines in strand-symmetrical sequences CpG and CpNpG. In plants, as in mammals, DNA methylation has dual roles in defense against invading DNA and transposable elements and in gene regulation. Although originally reported as having no phenotypic consequence, reduced DNA methylation disrupts normal plant development.

Gene silencing by DNA methylation and dual inheritance in Chinese hamster ovary cells

Chinese hamster ovary (CHO) cells strain D422, which has one copy of the adenine phosphoribosyl transferase (APRT) gene, were permeabilized by electroporation and treated with 5-methyl deoxycytidine triphosphate. Cells with a silenced APRT gene were selected on 2, 6-diaminopurine. Colonies were isolated and shown to be reactivated to APRT+ by 5-aza-cytidine and by selection in medium containing adenine, aminopterin and thymidine. Genomic DNA was prepared from eight isolates of independent origin and subjected to bisulphite treatment. This deaminates cytosine to uracil in single-stranded DNA but does not deaminate 5-methyl cytosine. PCR, cloning and sequencing revealed the methylation pattern of CpG doublets in the promoter region of the APRT- gene, whereas the active APRT gene had nonmethylated DNA. CHO strain K1, which has two copies of the APRT+ gene, could also be silenced by the same procedure but at a lower frequency. The availability of the 5-methyl dCTP-induced silencing, 5-aza-CR and a standard mutagen, ethyl methane sulphonate, makes it possible to follow concomitantly the inheritance of active, mutant or silenced gene copies. This analysis demonstrates "dual inheritance" at the APRT locus in CHO cells.

Structural characterization of myelin-associated glycoprotein gene core promoter

Myelin-associated glycoprotein (MAG) is emerging as an important molecule involved in the plasticity and regeneration of the central nervous system. In this study, the structure of MAG gene promoter was characterized in cultured rat oligodendrocyte lineage cells. Heterogeneous transcription initiation with five major and eight minor start sites scattered within 72 bp was shown by primer extension analysis. This TATA-less core promoter contains no prominent initiator (Inr) elements associated with the transcription initiation sites, and hence, appears to utilize novel positioning mechanisms. Genomic footprinting analysis revealed several putative protein-binding regions overlapping the initiation sites and containing a multitude of CG-rich sequences. However, no conspicuous alterations in the protein-binding pattern were evident between O2A progenitors in which the gene is inactive, and mature oligodendrocytes with fully upregulated gene. The core promoter DNA features a differentiation-dependent demethylation as shown by genomic sequencing analysis. Three of eight cytosines are totally demethylated in oligodendrocyte chromosomes, indicating that these unmodified bases may be critical for full activation of the promoter. The core promoter is located within an internucleosomal linker, and the upstream regulatory region appears to be organized into an array of nucleosomes with hypersensitive linkers.

Methylation sensitive protein binding to an intragenic active X-specific methylated region in the M. robustus Hprt gene

An intragenic region of the wallaroo (Macropus robustus) hypoxanthine phosphoribosyltransferase gene which contains three active X-specific methylated cytosines was examined for protein(s) binding. In vitro DNase I footprinting of unmethylated DNA identified three footprints, one of which (footprint I) contained two of the known differentially methylated sites (a HpaII and a HhaI site). Methylation of the footprint I HpaII site only, abolished the formation of several, specific DNA-protein complexes in mobility shift assays. UV cross-linking experiments indicated that polypeptides involved in the methylation sensitive interactions with footprint I had molecular weights ranging from 72 to 48 kDa. Analogous results were obtained with nuclear extracts from both eutherian and metatherian cells, indicating that these proteins are conserved. We suggest that the binding of these proteins to the inactive X may play some role in gene silencing, with the active gene being protected from this effect by methylation of the binding site.

Site-specific methylation of the rat prolactin and growth hormone promoters correlates with gene expression

The methylation patterns of the rat prolactin (rPRL) (positions -440 to -20) and growth hormone (rGH) (positions -360 to -110) promoters were analyzed by bisulfite genomic sequencing. Two normal tissues, the anterior pituitary and the liver, and three rat pituitary GH3 cell lines that differ considerably in their abilities to express both genes were tested. High levels of rPRL gene expression were correlated with hypomethylation of the CpG dinucleotides located at positions -277 and -97, near or within positive cis-acting regulatory elements. For the nine CpG sites analyzed in the rGH promoter, an overall hypomethylation-expression coupling was also observed for the anterior pituitary, the liver, and two of the cell lines. The effect of DNA methylation was tested by measuring the transient expression of the chloramphenicol acetyltransferase reporter gene driven by a regionally methylated rPRL promoter. CpG methylation resulted in a decrease in the activity of the rPRL promoter which was proportional to the number of modified CpG sites. The extent of the inhibition was also found to be dependent on the position of methylated sites. Taken together, these data suggest that site-specific methylation may modulate the action of transcription factors that dictate the tissue-specific expression of the rPRL and rGH genes in vivo.

Hypomethylation of the interferon-gamma gene correlates with its expression by primary T-lineage cells

To determine the potential role of methylation in the regulation of interferon-gamma (IFN-gamma) gene transcription by T cells, primary T-lineage cell populations were analyzed for the extent of methylation of three CpG sites within or near transcriptional activator elements in the 5' flank and first intron of the human IFN-gamma gene. A striking correlation was observed between the capacity of the IFN-gamma gene to be expressed and the degree of hypomethylation. The IFN-gamma gene was virtually completely methylated at all sites in thymocytes, neonatal T cells, and adult CD45RAhiCD45R0lo (antigenically naive) CD4 T cells, cell types that all have a low or undetectable capacity to express the IFN-gamma gene. In contrast, there was substantial hypomethylation in T-lineage cell types with relatively high capacities to express the IFN-gamma gene, including adult CD8 T cells and adult CD45RAloCD45R0hi (memory/effector) CD4 T cells. These results suggest that hypomethylation of the IFN-gamma genetic locus may be an important determinant of IFN-gamma gene expression in vivo by T-lineage cells.

The effect of histone H1 and DNA methylation on transcription

We have previously shown that DNA methylation acts as a focus for the formation of inactive chromatin in vivo. We have investigated the mechanism further by in vitro transcription of a template containing two tRNA genes and an extensive (G+C)-rich sequence characteristic of a CpG island. The extent of transcription from the unmethylated or fully methylated template was assayed in the presence of varied levels of histone H1. The transcriptional activity of both templates was inhibited by increasing amounts of histone H1, although inhibition with the methylated template occurs at a lower H1:DNA ratio. The H1c variant shows the greatest preferential inhibition of the methylated template. We demonstrated that histone H1 complexed to DNA is one of the factors that inhibits transcription by preventing the formation of initiation complexes, particularly on methylated template, rather than the formation of disordered H1.DNA aggregates.

Methylation of single sites within the herpes simplex virus tk coding region and the simian virus 40 T-antigen intron causes gene inactivation

In order to determine whether partial methylation of the herpes simplex virus (HSV) tk gene prevents tk gene expression, the HSV tk gene was cloned as single-stranded DNA. By in vitro second-strand DNA synthesis, specific HSV tk gene segments were methylated, and the hemimethylated DNA molecules were microinjected into thymidine kinase-negative rat2 cells. Conversion of the hemimethylated DNA into symmetrical methylated DNA and integration into the host genome occurred early after gene transfer, before the cells entered into the S phase. HSV tk gene expression was inhibited either by promoter methylation or by methylation of the coding region. Using the HindIII-SphI HSV tk DNA fragment as a primer for in vitro DNA synthesis, all cytosine residues within the coding region, from +499 to +1309, were selectively methylated. This specific methylation pattern caused inactivation of the HSV tk gene, while methylation of the cytosine residues within the nucleotide sequence from +811 to +1309 had no effect on HSV tk gene activity. We also methylated single HpaII sites within the HSV tk gene using a specific methylated primer for in vitro DNA synthesis. We found that of the 16 HSV tk HpaII sites, methylation of 6 single sites caused HSV tk inactivation. All six of these "methylation-sensitive" sites are within the coding region, including the HpaII-6 site, which is 571 bp downstream from the transcription start site. The sites HpaII-7 to HpaII-16 were all methylation insensitive. We further inserted separately the methylation-sensitive HSV tk HpaII-6 site and the methylation-insensitive HpaII-13 site as DNA segments (32-mer) into the intron region of the simian virus 40 T antigen (TaqI site). Methylation of these HpaII sites caused inhibition of simian virus 40 T-antigen synthesis.

Methylation of single sites within the herpes simplex virus tk coding region and the simian virus 40 T-antigen intron causes gene inactivation

In order to determine whether partial methylation of the herpes simplex virus (HSV) tk gene prevents tk gene expression, the HSV tk gene was cloned as single-stranded DNA. By in vitro second-strand DNA synthesis, specific HSV tk gene segments were methylated, and the hemimethylated DNA molecules were microinjected into thymidine kinase-negative rat2 cells. Conversion of the hemimethylated DNA into symmetrical methylated DNA and integration into the host genome occurred early after gene transfer, before the cells entered into the S phase. HSV tk gene expression was inhibited either by promoter methylation or by methylation of the coding region. Using the HindIII-SphI HSV tk DNA fragment as a primer for in vitro DNA synthesis, all cytosine residues within the coding region, from +499 to +1309, were selectively methylated. This specific methylation pattern caused inactivation of the HSV tk gene, while methylation of the cytosine residues within the nucleotide sequence from +811 to +1309 had no effect on HSV tk gene activity. We also methylated single HpaII sites within the HSV tk gene using a specific methylated primer for in vitro DNA synthesis. We found that of the 16 HSV tk HpaII sites, methylation of 6 single sites caused HSV tk inactivation. All six of these "methylation-sensitive" sites are within the coding region, including the HpaII-6 site, which is 571 bp downstream from the transcription start site. The sites HpaII-7 to HpaII-16 were all methylation insensitive. We further inserted separately the methylation-sensitive HSV tk HpaII-6 site and the methylation-insensitive HpaII-13 site as DNA segments (32-mer) into the intron region of the simian virus 40 T antigen (TaqI site). Methylation of these HpaII sites caused inhibition of simian virus 40 T-antigen synthesis.

The major histocompatibility complex class II promoter-binding protein RFX (NF-X) is a methylated DNA-binding protein

A mammalian protein called RFX or NF-X binds to the X box (or X1 box) in the promoters of a number of major histocompatibility (MHC) class II genes. In this study, RFX was shown to have the same DNA-binding specificity as methylated DNA-binding protein (MDBP), and its own cDNA was found to contain a binding site for MDBP in the leader region. MDBP is a ubiquitous mammalian protein that binds to certain DNA sequences preferentially when they are CpG methylated and to other related sequences, like the X box, irrespective of DNA methylation. MDBP from HeLa and Raji cells formed DNA-protein complexes with X-box oligonucleotides that coelectrophoresed with those containing standard MDBP sites. Furthermore, MDBP and X-box oligonucleotides cross-competed for the formation of these DNA-protein complexes. DNA-protein complexes obtained with MDBP sites displayed the same partial supershifting with an antiserum directed to the N terminus of RFX seen for complexes containing an X-box oligonucleotide. Also, the in vitro-transcribed-translated product of a recombinant RFX cDNA bound specifically to MDBP ligands and displayed the DNA methylation-dependent binding of MDBP. RFX therefore contains MDBP activity and thereby also EF-C, EP, and MIF activities that are indistinguishable from MDBP and that bind to methylation-independent sites in the transcriptional enhancers of polyomavirus and hepatitis B virus and to an intron of c-myc.

Methylation analysis by genomic sequencing of 5' region of mouse Pgk-1 gene and a cautionary note concerning the method

We have used genomic sequencing aided by ligation-mediated PCR (LMPCR) to assay for 5-methylcytosine in the CpG-rich promoter region of the mouse X-linked phosphoglycerate kinase gene (Pgk-1). Earlier studies showed that there was very heavy methylation of CpG dinucleotides in the CpG-rich promoter of the human PGK1 gene on the inactive X chromosome (the Xi), but that these same sites were completely unmethylated on the active X chromosome (the Xa). For mouse Pgk-1, previous restriction enzyme analysis had shown apparently complete methylation of only one cytosine in the promoter region on the Xi, at HpaII site H7, which is located in the untranslated region, 28 nucleotides upstream of the translation start site. We analyzed this potentially critical region by combining the use of HpaII with LMPCR, and find that the CpG dinucleotides near H7 are either unmethylated or only partially methylated on the Xi. LMPCR analysis of male and female DNA over a 490-bp sequence including the promoter and enhancer extend the finding of relative hypomethylation on the mouse Xi to include all CpG dinucleotides in this region. These results are relevant to the role of DNA methylation in stabilizing the inactive state of chromatin. In addition, we find that caution must be exercised in using LMPCR for methylation analysis of some sequences. A DNA concentration-dependent band-suppression artifact can incorrectly suggest methylation of both CpG and nonCpG dinucleotides.

The major histocompatibility complex class II promoter-binding protein RFX (NF-X) is a methylated DNA-binding protein

A mammalian protein called RFX or NF-X binds to the X box (or X1 box) in the promoters of a number of major histocompatibility (MHC) class II genes. In this study, RFX was shown to have the same DNA-binding specificity as methylated DNA-binding protein (MDBP), and its own cDNA was found to contain a binding site for MDBP in the leader region. MDBP is a ubiquitous mammalian protein that binds to certain DNA sequences preferentially when they are CpG methylated and to other related sequences, like the X box, irrespective of DNA methylation. MDBP from HeLa and Raji cells formed DNA-protein complexes with X-box oligonucleotides that coelectrophoresed with those containing standard MDBP sites. Furthermore, MDBP and X-box oligonucleotides cross-competed for the formation of these DNA-protein complexes. DNA-protein complexes obtained with MDBP sites displayed the same partial supershifting with an antiserum directed to the N terminus of RFX seen for complexes containing an X-box oligonucleotide. Also, the in vitro-transcribed-translated product of a recombinant RFX cDNA bound specifically to MDBP ligands and displayed the DNA methylation-dependent binding of MDBP. RFX therefore contains MDBP activity and thereby also EF-C, EP, and MIF activities that are indistinguishable from MDBP and that bind to methylation-independent sites in the transcriptional enhancers of polyomavirus and hepatitis B virus and to an intron of c-myc.