An avian 40 KDa nucleoprotein binds preferentially to a promoter sequence containing one single pair of methylated CpG

Methylation status of CpG sites and methyl-CpG binding proteins are involved in the promoter regulation of the mouse Xist gene

The mouse Xist gene is expressed exclusively from the inactive X chromosome and is involved in the initiation of X inactivation. We previously reported that the -1157/+917 region of the Xist promoter was ubiquitously functional in mammalian cells and that experiments in a transient expression system revealed no trans-acting element responsible for the inactive X specific expression of Xist. In somatic tissues, the 5' end of the silent Xist allele on the active X is known to be fully methylated whereas the expressed allele on the inactive X is unmethylated. In the present study we have used a bisulphite genomic sequencing method to evaluate DNA methylation at all cytosines including CpG dinucleotides within the Xist promoter. We report and confirm that methylation of specific sites plays a key role in Xist gene expression. In vitro DNA methylation of the 5'-region drastically reduced transcriptional activity in transiently transfected fibroblasts. Mobility shift assays showed that methylation does not inhibit Xist promoter activity by preventing the binding of transcription factors and that two distinct nuclear proteins bind in a sequence methyl-CpG-specific manner. Therefore, we suggest that Xist repression involves its promoter methylation and two distinct methylated DNA binding proteins.

Molecular organization of the rat glia-derived nexin/protease nexin-1 promoter

The first three exons and the promoter of rat glia-derived nexin, also called protease nexin-1 (GDN/PN-1), have been identified through analysis of rat genomic clones. A 1.6 kilobase (kb) fragment containing 105 base pairs of the first exon and 5'-flanking sequences was sequenced. The 5'-flanking sequence and the first exon were found to be GC-rich, indicating that the 5' region of the rat GDN/PN-1 gene resides within a CpG island. A TATA box-like sequence, but no CAAT box, was found. The rat GDN/PN-1 promoter contains five SP1 consensus sites, four consensus sites for the MyoD1 transcription factor, and one binding site for the transcription factors NGFI-A, NGFI-C, Krox-20, and Wilms tumor factor. The presence of these consensus sequences is consistent with the known expression pattern of GDN/PN-1. Primer extension and RNase protection assays identified one transcriptional start site. The 1.6 kb promoter fragment cloned in a reporter plasmid was found to induce firefly luciferase expression in a cell-specific manner. A positive regulatory element is localized in the region -1545 to -389. In vitro CpG methylation blocked transcription from the GDN/PN-1 promoter in rat hepatoma cells but not in C6 rat glioma cells.

DNA methylation induced changes in chromatin conformation of the promoter of the vitellogenin II gene of Japanese quail during aging

One approach to the understanding of the molecular basis of aging in higher organisms may be to use genes whose timing and rate of expression during the life span run parallel with specific functions that can be monitored. The genes for egg proteins, such as vitellogenin (VTG), which is expressed in the liver, and ovalbumin, lysozyme etc. that are expressed in the oviduct of birds, meet these requirements. Egg laying function is dependent on the production of these proteins, which, in turn, depends on the expression of their genes. In this communication we present the age-related studies on the VTG II gene of the bird, Japanese quail. The gene is expressed only in the liver and its expression is considerably lower in old birds that do not lay eggs. Comparison of the promoter region of the gene carrying the two important cis-acting elements, estrogen responsive element (ERE) and progesterone responsive element (PRE), shows it to be 100% homologous to the corresponding region of the chicken VTG II gene. Methylation of DNA and conformation of chromatin of this region were studied, as they are known to be important for regulation of expression of genes. Our studies show that in the liver of adult female quails which lay eggs, a -CCGG- sequence located in this region is hypomethylated, and the chromatin encompassing this region of the gene is relaxed. In the old, the -CCGG- sequence is hypermethylated and the chromatin is compact. This is correlated with a decrease in the expression of the gene and decrease in egg production. Further, electrophoretic mobility shift assay (EMSA) shows that the levels/affinity of specific trans-acting factors that bind to ERE and PRE present in the region, are not different in adult and old birds. Hence the methylation status of the -CCGG- sequence that is located in-between the ERE and the PRE may be crucial for the conformation of chromatin and availability of these two important cis-acting elements for the binding of the trans-acting factors. This, in turn, may downregulate the expression of the gene in old birds.

Hypermethylation of the spleen tyrosine kinase promoter in T-lineage acute lymphoblastic leukemia

Sequence analysis of the noncoding first exon (exon 1) of the Syk gene demonstrated the presence of a previously cloned CpG island (GenBank #Z 65706). Transient transfection analysis in Daudi cells demonstrated promoter activity (18-fold increase over parental luciferase plasmid) for a 348 bp BstXI-BsrBI fragment containing this island. This region exhibits a high GC content (approximately 75%), contains several SP1 binding sites and a potential initiator sequence, but lacks a strong TATA consensus. Bisulfite sequencing and methylation-specific PCR (MSP) of this region demonstrated that the Syk promoter CpG island was largely unmethylated in B-lineage leukemia cell lines, control peripheral blood cells, human thymocytes and CD3(+) T lymphocytes. However, dense methylation was seen in four T-lineage leukemia cell lines, Jurkat, H9, Molt 3 and HUT 78. MSP screening of leukemia cells from six T-lineage acute lymphoblastic leukemia (ALL) patients demonstrated methylation of the Syk promoter CpG island in one T-lineage ALL patient. Promoter methylation was correlated with reduced to absent expression of Syk mRNA and SYK protein in the T-lineage leukemia cell lines. Treatment of the leukemia lines Ha and Molt 3, with the methylation inhibitor, 5-aza-2'-deoxycytidine (5-aza-CdR) resulted in increased Syk mRNA expression. The presence of a methylated promoter sequence in these T-lineage leukemia cell lines and in one T-lineage patient suggests a potential role for SYK as a tumor suppressor in T-ALL.

Cloning and molecular characterization of the cDNA encoding histone H1 from Leishmania braziliensis

The isolation and molecular characterization of the histone H1-encoding gene from Leishmania braziliensis was carried out. The gene is present in the genome as a single copy and transcribed as a polyadenylated transcript of 830 nucleotides. The deduced amino acid sequence has in its central region the DNA binding K-[K/R]-A-A-[A/P] motif, which is repeated in tandem 9 times.

Inhibition of poly(ADP-ribosyl)ation introduces an anomalous methylation pattern in transfected foreign DNA

The aim of this paper is to verify whether the control played by poly(ADP-ribosyl)ation on genomic DNA methylation, and in particular on CpG islands, can also be seen on foreign DNA transfected in cells where inhibition of the poly(ADP-ribosyl)ation process was obtained by treating them with 2 mM 3-aminobenzamide for 24 h. The CpG island-like pVHCk plasmid containing the bacterial chloramphenicol acyltransferase (CAT) gene under the control of SV40 early promoter was transfected in L929 mouse fibroblast cells. The bisulfite reaction, which is capable of immortalizing the methylation state of cytosine on DNA, was performed before amplification of the plasmid DNA fragment, then used for sequence analysis. Our results have shown that 1) when transfected in control cells, the plasmid maintains its characteristic unmethylated pattern, whereas this pattern is lost when the plasmid is transfected in cells treated with 3-aminobenzamide; and 2) the presence of new methyl groups on plasmid DNA is paralleled by a decrease of CAT reporter gene expression. These data confirm that poly(ADP-ribosyl)ation is a process tightly involved in protecting genomic DNA from full methylation and suggest the use of 3-aminobenzamide as a possible experimental strategy to mime other conditions of DNA hypermethylation in cells.

Reduced levels of poly(ADP-ribosyl)ation result in chromatin compaction and hypermethylation as shown by cell-by-cell computer-assisted quantitative analysis

The unmethylated status of the CpG islands is important for gene expression of correlated housekeeping genes since it is well known that their methylation inhibits transcription process. An interesting question that has been discussed but not solved is how the CpG islands maintain their characteristic unmethylated status even though they are rich in CpG dinucleotides. Our previous in vitro and in vivo research has shown that poly(ADP-ribosyl)ation is involved in protecting CpG dinucleotides from full methylation in genomic DNA and that a block of poly(ADP-ribosyl)ation is also involved in modifying the methylation pattern in the promoter region of Htf9 housekeeping gene. In this study we locked for cytological evidence that in the absence of an active poly(ADP-ribosyl)ation the DNA methylation pattern in L929 and NIH/3T3 mouse fibroblast cell lines is altered. For this purpose, differences in the methylation levels of interphase nuclei from control and treated cultures of two murine cell lines preincubated with 2 mM 3-aminobenzamide, an inhibitor of poly(ADP-ribosyl)ation, were measured in individual cells after indirect immunolabeling with anti-5MeC antibodies. The quantitative analysis allowed us to demonstrate that blocking of the poly(ADP-ribosyl)ation results in a higher number, size, and density of antibody binding regions in treated cells when compared to the controls. Analogously, sequential Giemsa staining and indirect immunolabeling of the same slides showed the heterochromatic regions colocalized with the extended methyl-rich domains.

The unmethylated state of CpG islands in mouse fibroblasts depends on the poly(ADP-ribosyl)ation process

In vivo and in vitro experiments carried out on L929 mouse fibroblasts suggested that the poly(ADP-ribosyl) ation process acts somehow as a protecting agent against full methylation of CpG dinucleotides in genomic DNA. Since CpG islands, which are found almost exclusively at the 5'-end of housekeeping genes, are rich in CpG dinucleotides, which are the target of mammalian DNA methyltransferase, we examined the possibility that the poly(ADP-ribosyl)ation reaction is involved in maintaining the unmethylated state of these DNA sequences. Experiments were conducted by two different strategies, using either methylation-dependent restriction enzymes on purified genomic DNA or a sequence-dependent restriction enzyme on an aliquot of the same DNA, previously modified by a bisulfite reaction. With the methylation-dependent restriction enzymes, it was observed that the "HpaII tiny fragments" greatly decreased when the cells were preincubated with 3-aminobenzamide, a well known inhibitor of poly(ADP-ribose) polymerase. The other experimental approach allowed us to prove that, as a consequence of the inhibition of the poly(ADP-ribosyl)ation process, an anomalous methylation pattern could be evidenced in the CpG island of the promoter fragment of the Htf9 gene, amplified from DNA obtained from fibroblasts preincubated with 3-aminobenzamide. These data confirm the hypothesis that, at least for the Htf9 promoter region, an active poly(ADP-ribosyl)ation protects the unmethylated state of the CpG island.

Regulation of X-chromosome inactivation in development in mice and humans

Dosage compensation for X-linked genes in mammals is accomplished by inactivating one of the two X chromosomes in females. X-chromosome inactivation (XCI) occurs during development, coupled with cell differentiation. In somatic cells, XCI is random, whereas in extraembryonic tissues, XCI is imprinted in that the paternally inherited X chromosome is preferentially inactivated. Inactivation is initiated from an X-linked locus, the X-inactivation center (Xic), and inactivity spreads along the chromosome toward both ends. XCI is established by complex mechanisms, including DNA methylation, heterochromatinization, and late replication. Once established, inactivity is stably maintained in subsequent cell generations. The function of an X-linked regulatory gene, Xist, is critically involved in XCI. The Xist gene maps to the Xic, it is transcribed only from the inactive X chromosome, and the Xist RNA associates with the inactive X chromosome in the nucleus. Investigations with Xist-containing transgenes and with deletions of the Xist gene have shown that the Xist gene is required in cis for XCI. Regulation of XCI is therefore accomplished through regulation of Xist. Transcription of the Xist gene is itself regulated by DNA methylation. Hence, the differential methylation of the Xist gene observed in sperm and eggs and its recognition by protein binding constitute the most likely mechanism regulating imprinted preferential expression of the paternal allele in preimplantation embryos and imprinted paternal XCI in extraembryonic tissues. This article reviews the mechanisms underlying XCI and recent advances elucidating the functions of the Xist gene in mice and humans.

The estrogen responsive element of the pS2 gene is recognized by a methylation sensitive DNA binding protein

The human pS2 gene is specifically expressed is a subclass of estrogen receptor containing human breast cancer cells. In the MCF7 cell line, its induction by estradiol is a primary transcriptional event. The exact location of its estrogen responsive element has been determined using a chimeric recombinant transfected into HeLa cells and a transient expression assay. In this study we found, using electrophoretic mobility shift experiments, that in HeLa cells the estrogen responsive element (ERE) of the pS2 gene is recognized by a methylation sensitive DNA binding protein (MSDBP) different from the estrogen receptor. Competition experiments have shown that the binding of this protein requires at least one CpG in the center of the palindromic sequence and that imperfect palindromic sequences are also recognized. Although the presence of CpG is necessary, CpG-rich oligonucleotides, containing consensus sequences for Sp1 or AP2, do not interfere with its binding to the pS2 oligonucleotide, indicating that the ERE sequence itself participates in the specificity of its binding. This protein binds the pS2 sequence with a relatively high affinity (apparent Kd = 10(-10) M) and its binding is strongly reduced by the methylation of the cytosines at CpG sites. UV cross-linking experiments and peptide mapping indicate that this protein has an apparent molecular weight of 46 kDa and is present in several cell lines, including non-human cell lines. Taken together, these data suggest that this protein might have a potential role in regulating gene activity or in chromatin structure of some genes possessing an ERE.

Isolation of an Alu repetitive DNA binding protein and effect of CpG methylation on binding to its recognition sequence

The structure, expression, and evolution of Alu repetitive DNA elements have been extensively studied, but the role of these sequences in the function of primate genomes has yet to be elucidated. The contribution of Alu repetitive sequences (ARS) to the structure, maintenance, or expression of the human genome is undoubtedly mediated by one or more DNA binding proteins. As part of a larger study in this laboratory to define the molecular mechanisms that result in de-repression of the glycoprotein hormone alpha-subunit (GPH alpha) gene in a variety of tumor cell types, it was found that the gene was hypermethylated in a variety of cell lines that produce alpha-subunit at high levels and significantly less methylated in cell lines where the gene is unexpressed or expressed at low levels. This is in sharp contrast to the majority of genes examined in this regard, which show an inverse correlation between methylation and expression. The analysis was extended to a group of clones isolated from a single cell line (HeLa) that were differentially methylated over the GPH alpha gene and exhibited a 400-fold range in its expression. These analyses demonstrated that methylation of a small number of CpG dinucleotides correlated with high level expression of the gene. Two of these sites are imbedded in oppositely oriented Alu repeats located in the 5'-flanking DNA and second intron. The upstream site was examined in some detail. DNase I footprint analysis demonstrated that the protein protects a region encompassing the sequence 5'-TTGAACCCGGGAG-3', and electrophoretic gel mobility shift analysis demonstrated specific binding of a protein to an oligonucleotide containing the DNase footprint sequence. Chromatography of nuclear extracts on Sephacryl S-200, heparin--agarose, and oligonucleotide--Sepharose produced an apparently homogeneous preparation of the 50-53 kDa DNA-binding protein as judged by silver staining of sodium dodecylsulfate polyacrylamide gels. The affinity-purified material was enriched 15- to 18,000-fold over crude nuclear extracts. Binding of this protein to an oligonucleotide containing the DNase-protected sequence was severely inhibited when CpG dinucleotide in the Msp I recognition site was methylated on either the sense or antisense strands. Based on its properties, this protein has been termed MeSABp50 for methylation-sensitive Alu binding protein of 50 kDa.

The methylated DNA binding protein-2-H1 (MDBP-2-H1) consists of histone H1 subtypes which are truncated at the C-terminus

The methylated DNA binding protein-2-H1 (MDBP-2-H1), present in rooster liver, is a member of the histone H1 family which inhibits transcription by binding selectively to methylated promoters. Here we have determined the primary structure of MDBP-2-H1. A comparison between histone H1 and MDBP-2-H1 was achieved by analyzing reversed phase HPLC-purified and V8-digested proteins by mass spectrometry and/or microsequencing. In rooster liver the most abundant histone H1 subtypes are H1 01 and H1 11L. Similarly, MDBP-2-H1 contains the same subtypes of histone H1. The histone H1 subtype H1 01 in MDBP-2-H1 has 150 amino acids, whereas the full-size histone H1 01 is 218 amino acids. The difference in mass between the two proteins is explained by C-terminal truncation of histone H1 01.

Methylation of the minimal promoter of an embryonic globin gene silences transcription in primary erythroid cells

Methylation of cytosines in the dinucleotide CpG has been shown to suppress transcription of a number of tissue-specific genes, yet the precise mechanism is not fully understood. The vertebrate globin genes were among the first examples in which an inverse correlation was shown between CpG methylation and transcription. We studied the methylation pattern of the 235-bp rho-globin gene promoter in genomic DNA from primary chicken erythroid cells using the sodium bisulfite conversion technique and found all CpGs in the promoter to be methylated in erythroid cells from adult chickens in which the rho-globin gene is silent but unmethylated in 5-day (primitive) embryonic red cells in which the gene is transcribed. To elucidate further the mechanism of methylation-induced silencing, an expression construct consisting of 235 bp of 5' promoter sequence of the rho-globin gene along with a strong 5' erythroid enhancer driving a chloramphenicol acetyltransferase reporter gene, rho-CAT, was transfected into primary avian erythroid cells derived from 5-day embryos. Methylation of just the 235-bp rho-globin gene promoter fragment at every CpG resulted in a 20- to 30-fold inhibition of transcription, and this effect was not overridden by the presence of potent erythroid-specific enhancers. The ability of the 235-bp rho-globin gene promoter to bind to a DNA Methyl Cytosine binding Protein Complex (MeCPC) was tested in electrophoretic mobility shift assays utilizing primary avian erythroid cell nuclear extract. The results were that fully methylated but not unmethylated 235-bp rho-globin gene promoter fragment could compete efficiently for MeCPC binding. These results are a direct demonstration that site-specific methylation of a globin gene promoter at the exact CpGs that are methylated in vivo can silence transcription in homologous primary erythroid cells. Further, these data implicate binding of MeCPC to the promoter in the mechanism of silencing.

Characterization of HMBP-2, a DNA-Binding Protein That Binds to HIV-1 LTR When only One of the Three Sp1 Sites Is Methylated

HIV-1 methylation binding protein-1 (HMBP-1) (formerly called HMBP) is a protein found in human cell nuclei that binds with enhanced affinity to a fragment of the HIV-1 long terminal repeat sequence (LTR) containing three Sp1 sites when all three sites are methylated. HMBP-2 is another protein present in the nuclei of human T helper lymphocytes and HeLa cells that binds to the HIV-1 LTR. HMBP-2 binds preferentially to the same region of the HIV-1 LTR as does HMBP-1, but HMBP-2 binds best when only one of the three Sp1 sites is methylated. HMBP-2 can be separated from HMBP-1 chromatographically, and dimethyl sulftate (DMS) methylation interference analysis indicates that their binding sites are not identical. HMBP-2 represents a novel protein factor capable of binding to a partially methylated region of the HIV-1 LTR. Copyright 1997 S. Karger AG, Basel

Phosphorylation/dephosphorylation of the repressor MDBP-2-H1 selectively affects the level of transcription from a methylated promoter in vitro

We have previously shown that in vivo estradiol-dependent dephosphorylation of MDBP-2-H1 (a member of the histone H1 family) correlates with the loss of in vitro preferential binding to methylated DNA. To study the effects of the phosphorylation/dephosphorylation of MDBP-2-H1 on the expression of the avian vitellogenin II gene, we optimised an in vitro transcription system using HeLa nuclear extracts. We show that in the absence of the phosphorylated form of MDBP-2-H1 from rooster, methylation of the vitellogenin II promoter does not affect the transcription. Addition of purified MDBP-2-H1 from rooster to the in vitro transcription system inhibits transcription more efficiently from a methylated than an unmethylated DNA template. Dephosphorylation of rooster MDBP-2-H1 by phosphatase treatment or estradiol treatment of rooster lead to the loss of inhibitory activity of the protein when added to the in vitro transcription assays. These findings indicate that the phosphorylation of MDBP-2-H1 is essential for the repression of the transcription. Taken together these results establish the relationship between the dephosphorylation of MDBP-2-H1 caused by estradiol, the down regulation of its binding activity to methylated DNA and the derepression of vitellogenin II transcription.

Inactivation of the very strong HCMV immediate early promoter by DNA CpG methylation in vitro

The influence of DNA methylation in vitro on the activity of the very strong human cytomegalovirus (HCMV) major immediate early (IE) modulator/enhancer/promoter region was investigated by transient transfection experiments of premonocytic HL-60 cells. While sequence-specific methylation of the major IE enhancer and/or modulator with the cytosine methyl-transferases FnuDII, HhaI and HaeIII had no significant effect, the promoter activity was completely repressed by methylation of the cytosine in 5'-CpG sites with the Spiroplasma methyltransferase SssI. Addition of TNF-alpha or PMA which are strong stimulators of HCMV major IE enhancer/promoter activity in premonocytic HL-60 cells had no effect on repression. Inactivation of the IE enhancer/promoter via methylation by M.SssI could be partially alleviated by co-transfection with an excess of untranscribable highly methylated DNA. These results indicate that a methyl-CpG binding factor is involved as mediator in the inhibitory effect of HCMV enhancer/promoter methylation. Taken together, the HCMV major IE enhancer/ promoter has been shown to be susceptible to transcriptional inactivation by methylation of the cytosines in CpG dinucleotides, a process that is proposed to play a modulatory role in viral latency.

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.

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.

Overexpression of DNA methyltransferase in myoblast cells accelerates myotube formation

We overexpressed mouse DNA methyltransferase in murine C2C12 myoblast cells and tested the isolated clones for their ability to differentiate. Significant numbers of the clones showed distinct myotubes 24 h after the isolated transformants had been induced to differentiate, whereas the parent C2C12 cells did not form myotubes at this time point. Transfection of the vacant vector or the plasmid containing the reverse-oriented DNA methyltransferase cDNA did not provide significant numbers of transformants with the accelerated differentiation phenotype, suggesting that the effect is caused by the expression of DNA methyltransferase. The expressions of skeletal muscle myosin and creatine kinase in clones that showed the accelerated differentiation-phenotype were also induced about 24 h earlier and at higher levels relative to the parent C2C12 or the control cells, indicating that the entire process of myogenesis had been accelerated. All the methyltransferase-transfected clones, regardless of their phenotypes, demonstrated about threefold higher DNA methyltransferase activity and higher methylation levels than those of the clones transfected with vector alone or the reverse-oriented plasmid. At the early stage of transfection of the sense-oriented plasmid, high de novo methylation activities were detected. We consider it likely that this high de novo methylation activity is the reason for the high methylation levels and the accelerated myotube formation of the clones transfected with the sense-oriented plasmid. In some transformants which showed the accelerated differentiation phenotype, MyoD1 was already fully expressed under the growth conditions while, in control cells, MyoD1 was expressed at low levels. This elevated level of MyoD1 transcription could account for the accelerated myotube formation observed in the transformants. The methylation state of the HpaII sites in exon 1 through exon 2 of the MyoD1 gene and the expression of the MyoD1 transcript are positively correlated.

In vivo estradiol-dependent dephosphorylation of the repressor MDBP-2-H1 correlates with the loss of in vitro preferential binding to methylated DNA

We have previously shown that estradiol treatment of roosters resulted in a rapid loss of binding activity of the repressor MDBP-2-H1 (a member of the histone H1 family) to methylated DNA that was not due to a decrease in MDBP-2-H1 concentration. Here we demonstrate that MDBP-2-H1 from rooster liver nuclear extracts is a phosphoprotein. Phosphoamino acid analysis reveals that the phosphorylation occurs exclusively on serine residues. Two-dimensional gel electrophoresis and tryptic phosphopeptide analysis show that MDBP-2-H1 is phosphorylated at several sites. Treatment of roosters with estradiol triggers a dephosphorylation of at least two sites in the protein. Phosphatase treatment of purified rooster MDBP-2-H1 combined with gel mobility shift assay indicates that phosphorylation of MDBP-2-H1 is essential for the binding to methylated DNA and that the dephosphorylation can occur on the protein bound to methylated DNA causing its release from DNA. Thus, these results suggest that in vivo modification of the phosphorylation status of MDBP-2-H1 caused by estradiol treatment may be a key step for the down regulation of its binding to methylated DNA.

DNA methylation represses the murine alpha 1(I) collagen promoter by an indirect mechanism

Several lines of evidence indicate that DNA methylation plays a role in the transcriptional regulation of the murine alpha 1(I) collagen gene. To study the molecular mechanisms involved, a reporter gene construct containing the alpha 1(I) promoter and part of the first exon linked to the luciferase gene (Col3luc) was methylated in vitro and transfected into murine fibroblasts and embryonal carcinoma cells. Methylation resulted in repression of the alpha 1(I) promoter in both cell types, although it was less pronounced in embryonal carcinoma cells than in fibroblasts. The extent of repression depended on the density of methylation. DNase footprint and mobility shift assays indicated that the trans-acting factors binding to the alpha 1(I) promoter and first exon are ubiquitous factors and that their DNA binding is not inhibited by methylation. Transfection of Col3luc into Drosophila SL2 cells together with expression vectors for the transcription factors Sp1 and NF-1 showed that DNA methylation also inhibits the alpha 1(I) promoter in nonvertebrate cells, although to a much lesser extent than in murine cells. However, Sp1 and NF-1 transactivated the unmethylated and methylated reporter gene in SL2 cells equally well, confirming that these factors can bind and transactivate methylated DNA and indicating that DNA methylation represses the alpha 1(I) promoter by an indirect mechanism. This was further confirmed by cotransfection experiments with unspecific methylated competitor DNA which partially restored the activity of the methylated alpha 1(I) promoter. Our results suggest that DNA methylation can inhibit promoter activity by an indirect mechanism independent of methyl-C-binding proteins and that in vertebrate cells, chromatin structure and methyl-C-binding proteins cooperatively mediate the transcriptional inhibitory effect of DNA methylation.

DNA methylation represses the murine alpha 1(I) collagen promoter by an indirect mechanism

Several lines of evidence indicate that DNA methylation plays a role in the transcriptional regulation of the murine alpha 1(I) collagen gene. To study the molecular mechanisms involved, a reporter gene construct containing the alpha 1(I) promoter and part of the first exon linked to the luciferase gene (Col3luc) was methylated in vitro and transfected into murine fibroblasts and embryonal carcinoma cells. Methylation resulted in repression of the alpha 1(I) promoter in both cell types, although it was less pronounced in embryonal carcinoma cells than in fibroblasts. The extent of repression depended on the density of methylation. DNase footprint and mobility shift assays indicated that the trans-acting factors binding to the alpha 1(I) promoter and first exon are ubiquitous factors and that their DNA binding is not inhibited by methylation. Transfection of Col3luc into Drosophila SL2 cells together with expression vectors for the transcription factors Sp1 and NF-1 showed that DNA methylation also inhibits the alpha 1(I) promoter in nonvertebrate cells, although to a much lesser extent than in murine cells. However, Sp1 and NF-1 transactivated the unmethylated and methylated reporter gene in SL2 cells equally well, confirming that these factors can bind and transactivate methylated DNA and indicating that DNA methylation represses the alpha 1(I) promoter by an indirect mechanism. This was further confirmed by cotransfection experiments with unspecific methylated competitor DNA which partially restored the activity of the methylated alpha 1(I) promoter. Our results suggest that DNA methylation can inhibit promoter activity by an indirect mechanism independent of methyl-C-binding proteins and that in vertebrate cells, chromatin structure and methyl-C-binding proteins cooperatively mediate the transcriptional inhibitory effect of DNA methylation.

Inactive chromatin spreads from a focus of methylation

The detailed mechanisms of inhibition of transcription by DNA methylation are still unknown, but it has become obvious that the formation of chromatin plays an important role in this process. Using an approach enabling us to methylate, in vitro, chosen regions in a plasmid, we now show that specific methylation of nonpromoter sequences results in transcriptional inhibition of a reporter gene construct and that this inhibition is independent of the position of the methylated region within the plasmid. In plasmid minichromosomes containing a short region of methylated DNA, both methylated and unmethylated sequences are protected from limited MspI digestion. Our results show that inactive chromatin is present at unmethylated regions in partially methylated minichromosomes and can thereby inhibit gene expression. Spreading of the inactive chromatin is not inhibited by the presence of active promoters, nor is it a consequence of transcriptional inactivity.

A nuclear protein with enhanced binding to methylated Sp1 sites in the AIDS virus promoter

We report here the discovery of HMBP, a protein in nuclei of human T-helper lymphocytes and other human cell types, which binds with enhanced affinity to a promoter element in the HIV-1 long terminal repeat when that element is methylated at CpGs, the target site of the human DNA methyltransferase. This promoter element contains three (degenerate) binding sites for Sp1, a general activator of transcription. Gel shift assays and footprinting experiments indicate that HMBP binding overlaps two of these methylated Sp1 sites. Although HMBP binds these methylated Sp1 sites, it does not bind consensus Sp1 sites. Competition studies, differences in binding site specificities, binding conditions, and, in some cases, chromatographic separation further distinguish HMBP from Sp1 and from each of four previously identified methylated-DNA binding proteins. HMBP binds hemimethylated DNA in a strand dependent manner. These binding characteristics suggest that HMBP may recognize newly replicated DNA and thereby play a role in differentiation. If HMBP is able to compete with Sp1 for binding at methylated, non-consensus Sp1 sites in vivo and repress transcription, it may play a role in AIDS latency.

Inactive chromatin spreads from a focus of methylation

The detailed mechanisms of inhibition of transcription by DNA methylation are still unknown, but it has become obvious that the formation of chromatin plays an important role in this process. Using an approach enabling us to methylate, in vitro, chosen regions in a plasmid, we now show that specific methylation of nonpromoter sequences results in transcriptional inhibition of a reporter gene construct and that this inhibition is independent of the position of the methylated region within the plasmid. In plasmid minichromosomes containing a short region of methylated DNA, both methylated and unmethylated sequences are protected from limited MspI digestion. Our results show that inactive chromatin is present at unmethylated regions in partially methylated minichromosomes and can thereby inhibit gene expression. Spreading of the inactive chromatin is not inhibited by the presence of active promoters, nor is it a consequence of transcriptional inactivity.

Partial purification of a pea seed DNA-binding protein that specifically recognizes 5-methylcytosine

Previously, a DNA-binding protein (DBPm) was identified in plant nuclei that may mediate the effects of DNA methylation on chromatin structure and transcription. In the present report, DBPm was partially purified from germinated pea (Pisum sativum) seed nuclear extracts by DEAE-cellulose, phenylsepharose, heparin-sepharose chromatography, and preparative mobility shift on polyacrylamide gels. The purified activity showed a band at approximately 50 kD by sodium dodecyl sulfate-polyacrylamide gel electrophoresis as well as by Sephadex G100 chromatography, suggesting that DBPm is present as a monomer.

Identification of two novel mouse nuclear proteins that bind selectively to a methylated c-Myc recognizing sequence

The c-Myc recognizes the sequence CACGTG (Blackwell, T. K., Kretzner, L., Blackwood, E.M., Eisenman, R. N., and Weintraub, H. (1990) Science 250, 1149-1151), and its binding is inhibited by methylation of the core CpG (Prendergast, G. C. and Ziff, E. B. (1991) Science 251, 186-189). We identified two novel nuclear proteins, MMBP-1 and MMBP-2, that bound specifically and under physiological salt condition to the c-Myc binding motif of which cytidine in the CpG sequence was methylated. MMBP-1 was about 42 kD and MMBP-2 was about 63 kD. MMBP-1 was found in specific cells, while MMBP-2 was found in all the cell lines tested, suggesting that MMBP-1 may modulate the role of MMBP-2 in tissue specific manner. We propose that the two proteins play a role in the regulation of c-Myc function through stabilizing or destabilizing the methylation state of the c-Myc binding motif.

Effects of DNA methylation on DNA-binding proteins and gene expression

DNA methyltransferase is needed for normal development, perhaps because DNA methylation plays a part in the control of gene activity. It is clear that the methylation of promoters often leads to repression of transcription. Studies of the mechanism suggest that repression may either result from the direct effects of methylation on transcription factors, or may be indirectly caused by repressor proteins that bind to methylated DNA. Current evidence suggests that both mechanisms can be involved.

Characterization of DBPm, a plant protein that binds to DNA containing 5-methylcytosine

A protein (DBPm) has been isolated from nuclear extracts of soybean seeds, cauliflower florets, corn seed, wheat germ, and pea hypocotyl, seeds, apices, roots, and leaves that specifically binds to double-strand DNA containing 5-methylcytosine residues. In electrophoretic mobility shift assays, non-methylated duplex DNAs competed only slightly, while methylated DNAs were strong competitors. Specific binding still occurred after partial proteolysis of DBPm, but not after heating at 45 degrees C. By ultraviolet light-crosslinking and sodium dodecyl sulfate polyacrylamide gel electrophoresis and gel filtration, the size of pea seed DBPm was estimated to be in the range 70-90 kDa. From equilibrium binding studies the equilibrium constant for binding of pea seed DBPm to a 34 bp duplex deoxyoligonucleotide containing 12 5-methylcytosine residues was 1.2 x 10(9) M-1. The binding properties of DBPm make it a good candidate for a plant protein capable of mediating the effects of DNA methylation on the activity of some plant genes.

The repressor MDBP-2 is a member of the histone H1 family that binds preferentially in vitro and in vivo to methylated nonspecific DNA sequences

MDBP-2 is a repressor that binds preferentially to methylated DNA. Peptides derived from MDBP-2 were sequenced. The sequences of the two peptides, KPAGPS-VTELITK and ALAAGGYDVEK, are identical to those found in the chicken histone H1 core protein. In SDS/polyacrylamide gels MDBP-2 has an apparent molecular mass of 21 kDa, and antibodies directed against calf thymus total histone H1 cross-react with MDBP-2. The preferential binding of affinity-purified MDBP-2 to methylated DNA is not sequence-specific but requires a minimum length of 30 base pairs and one pair of symmetrically methylated (i.e., methylated on both strands) CpG dinucleotides. As previously shown, there is a decrease in the binding activity of MDBP-2 to methylated DNA upon estradiol treatment. Immunoblots show that upon estradiol treatment the amount of immunocrossreacting MDBP-2 protein remains unchanged. MDBP-2 enables another protein to bind DNA which by itself does not bind methylated DNA. Ultraviolet crosslinking and selective immunoadsorption assays with anti-histone H1 antibodies show that in vivo MDBP-2 preferentially binds to the methylated repressed vitellogenin gene. It is concluded that MDBP-2 may participate in the long-term silencing of genes (formation of heterochromatin) through selective binding to methylated DNA.

Characterization of MeCP2, a vertebrate DNA binding protein with affinity for methylated DNA

Methylated DNA in vertebrates is associated with transcriptional repression and inactive chromatin. Two activities have been identified, MeCP1 and MeCP2, which bind specifically to DNA containing methyl-CpG pairs. In this report we characterize MeCP2. We show that it is more abundant than MeCP1, is more tightly bound in the nucleus, and is distinguishable chromatographically. The two proteins share widespread expression in somatic mammalian cells, and barely detectable expression in early embryonic cells. DNAs containing thymidine which has a methyl group at position 5 are not ligands for the MeCPs. The possible role of MeCP2 in methylation-associated gene inactivation was tested in in vitro transcription extracts. Purified MeCP2 inhibited transcription from both methylated and nonmethylated DNA templates in vitro, probably due to the presence of nonspecific DNA binding domains within the protein. We hypothesise that MeCP2 normally binds methylated DNA in the context of chromatin, contributing to the long-term repression and nuclease-resistance of methyl-CpGs.

Purification, sequence, and cellular localization of a novel chromosomal protein that binds to methylated DNA

Methylation of mammalian DNA can lead to repression of transcription and alteration of chromatin structure. Recent evidence suggests that both effects are the result of an interaction between the methylated sites and methyl-CpG-binding proteins (MeCPs). MeCP1 has previously been detected in crude nuclear extracts. Here we report the identification, purification, and cDNA cloning of a novel MeCP called MeCP2. Unlike MeCP1, the new protein is able to bind to DNA that contains a single methyl-CpG pair. By staining with an antibody, we show that the distribution of MeCP2 along the chromosomes parallels that of methyl-CpG. In mouse, for example, MeCP2 is concentrated in pericentromeric heterochromatin, which contains a large fraction (about 40%) of all genomic 5-methylcytosine.

Characterisation of a genomic clone covering the structural mouse MyoD1 gene and its promoter region

We have isolated the mouse MyoD1 gene flanked by its promoter region by screening a genomic library with synthetic oligonucleotides. The structural gene is interrupted by two G + C rich introns. Transfection of the cloned gene inserted into an expression vector converts fibroblasts to myoblasts. Sequence analysis of about 650 bp of the 5' upstream region revealed the presence of several potential regulatory elements such as a TATA-box, an AP2-box, two SP1-boxes and a CAAT-box. In addition, there are three half palindromic estrogen response elements, a potential cAMP response element and various muscle specific elements such as a muscle-specific CAAT-box (MCAT) and four potential binding sites for MyoD1. Using S1 protection analysis the major start site of transcription in muscle and myoblast cells was mapped 3 bp upstream of the published cDNA 5' end. Promoter activity of the 650 bp upstream fragment was tested by in vitro transcription and by transfection analysis of myoblasts and fibroblasts. In all promoter test systems used, MyoD1 promoter activity was detected in myoblasts as well as in fibroblasts. Furthermore, DNA methylation was found to turn off MyoD1 promoter activity both in myoblasts and in fibroblasts.

Biological aspects of cytosine methylation in eukaryotic cells

The existence in eukaryotes of a fifth base, 5-methylcytosine, and of tissue-specific methylation patterns have been known for many years, but except for a general association with inactive genes and chromatin the exact function of this DNA modification has remained elusive. The different hypotheses regarding the role of DNA methylation in regulation of gene expression, chromatin structure, development, and diseases, including cancer are summarized, and the experimental evidence for them is discussed. Structural and functional properties of the eukaryotic DNA cytosine methyltransferase are also reviewed.

Estradiol down regulates the binding activity of an avian vitellogenin gene repressor (MDBP-2) and triggers a gradual demethylation of the mCpG pair of its DNA binding site

A negative regulating protein (MDBP-2) from rooster liver nuclear extracts binds preferentially to a methylated promoter region 5'TTCACCTTmCGCTATGAGGGGGATCATACTGG3' of the avian vitellogenin II gene (Nucleic Acids Res. 19, 1029-1034, 1991). Treatment of adult and immature roosters with estradiol results in a 90% decrease in the binding activity of MDBP-2 within three days. This corresponds to the level found in egg laying hens. The decrease in the binding activity of MDBP-2 precedes the onset of vitellogenin gene transcription. At the same time, there is a two-fold increase in the binding activity of NHP-1 (tested with the same oligonucleotide as for MDBP-2), a protein thought to be involved in the active demethylation of DNA. The methylated oligonucleotide binds either MDBP-2 or NHP-1 and there is no complex formation between the two proteins and DNA. Estradiol treatment does not change the equilibrium binding constant of MDBP-2 which is about 10(-9)M for the methylated oligonucleotide. The early kinetics of demethylation of the mCpG pair in the binding site of MDBP-2 was studied by means of genomic sequencing. A low level of demethylation of mCpG starts gradually on both DNA strands already 4 hours after estradiol treatment during the lag phase of vitellogenin mRNA synthesis. It is concluded that the lowering of the binding activity of MDBP-2 may have a stronger effect on the derepression of the gene than the slow demethylation of MDBP-2 DNA binding site. The role of the methylated CpG is to assure a high binding affinity of the repressor to DNA.