Cis-elements required for the demethylation of the mouse M-lysozyme downstream enhancer

The DNA methylation landscape of enhancers in the guinea pig hippocampus

AIM

To determine the state of methylation of DNA molecules in the guinea pig hippocampus that are associated with either poised or active enhancers.

METHODS

We used sequential chromatin immunoprecipitation-bisulfite-sequencing with an antibody to H3K4me1 to map the state of methylation of DNA that is found within enhancers. Actively transcribing transcription start sites were mapped by chromatin immunoprecipitation-sequencing with an antibody to RNApolII-PS5. Total DNA methylation was mapped using reduced representation bisulfite sequencing.

RESULTS

DNA that overlaps with H3K4me1 binding regions in the genome is heavily methylated. However, DNA molecules that are found in H3K4me1 chromatin are hypomethylated, while DNA found in enhancers that are associated with active transcription is further demethylated. Differential methylation in enhancers is spotted in single CGs, bimodal and corresponds to transcription factor binding sites.

CONCLUSION

Our study delineates the DNA methylation status of H3K4 me1-bound regions in the hippocampus in active and inactive genes.

Experimental approaches to the study of epigenomic dysregulation in ageing

In this review, we describe how normal ageing may involve the acquisition of epigenetic errors over time, akin to the accumulation of genetic mutations with ageing. We describe how such experiments are currently performed, their limitations technically and analytically and their application to ageing research.

Methylation-sensitive regulation of TMS1/ASC by the Ets factor, GA-binding protein-alpha

Epigenetic silencing involving the aberrant DNA methylation of promoter-associated CpG islands is one mechanism leading to the inactivation of tumor suppressor genes in human cancers. However, the molecular mechanisms underlying this event remains poorly understood. TMS1/ASC is a novel proapoptotic signaling factor that is subject to epigenetic silencing in human breast and other cancers. The TMS1 promoter is embedded within a CpG island that is unmethylated in normal cells and is spanned by three DNase I-hypersensitive sites (HS). Silencing of TMS1 in cancer cells is accompanied by local alterations in histone modification, remodeling of the HS, and hypermethylation of DNA. In this study, we probed the functional significance of the CpG island-specific HS. We identified a methylation-sensitive complex that bound a 55-bp intronic element corresponding to HS2. Affinity chromatography and mass spectrometry identified a component of this complex to be the GA-binding protein (GABP) alpha. Supershift analysis indicated that the GABPalpha binding partner, GABPbeta1, was also present in the complex. The HS2 element conferred a 3-fold enhancement in TMS1 promoter activity, which was dependent on both intact tandem ets binding sites and the presence of GABPalpha/beta1 in trans. GABPalpha was selectively enriched at HS2 in human cells, and its occupancy was inversely correlated with CpG island methylation. Down-regulation of GABPalpha led to a concomitant decrease in TMS1 expression. These data indicate that the intronic HS2 element acts in cis to maintain transcriptional competency at the TMS1 locus and that this activity is mediated by the ets transcription factor, GABPalpha.

p66alpha and p66beta of the Mi-2/NuRD complex mediate MBD2 and histone interaction

The Mi-2/NuRD complex is a multi-subunit protein complex with enzymatic activities involving chromatin remodeling and histone deacetylation. Targeting of Mi-2/NuRD to methylated CpG sequences mediates gene repression. The function of p66alpha and of p66beta within the multiple subunits has not been addressed. Here, we analyzed the in vivo function and binding of both p66-paralogs. Both factors function in synergy, since knocking-down p66alpha affects the repressive function of p66beta and vice versa. Both proteins interact with MBD2 functionally and biochemically. Mutation of a single amino acid of p66alpha abolishes in vivo binding to MBD2 and interferes with MBD2-mediated repression. This loss of binding results in a diffuse nuclear localization in contrast to wild-type p66alpha that shows a speckled nuclear distribution. Furthermore, wild-type subnuclear distribution of p66alpha and p66beta depends on the presence of MBD2. Both proteins interact with the tails of all octamer histones in vitro, and acetylation of histone tails interferes with p66 binding. The conserved region 2 of p66alpha is required for histone tail interaction as well as for wild-type subnuclear distribution. These results suggest a two-interaction forward feedback binding mode, with a stable chromatin association only after deacetylation of the histones has occurred.

A unique developmental pattern of Oct-3/4 DNA methylation is controlled by a cis-demodification element

Oct-3/4 is the earliest expressed transcription factor that is known to be crucial in murine pre-implantation development. In this report we asked whether methylation participates in controlling changes in Oct-3/4 expression and thus may play an important role in controlling normal embryogenesis. We show that the Oct-3/4 gene is unmethylated from the blastula stage but undergoes de novo methylation at 6.5 days post-coitum and remains modified in all adult somatic tissues analyzed. Oct-3/4 remains unmethylated in 6.25 days post-coitum epiblast cells when other genes, such as apoAI, undergo de novo methylation. We show that methylation of the Oct-3/4 promoter sequence strongly compromises its ability to direct efficient transcription. Moreover, DNA methylation inhibits basal transcription of the endogenous Oct-3/4 gene in vivo. We found that the Oct-3/4 gene harbors a cis-specific demodification element that includes the proximal enhancer sequence. This element leads to demethylation in embryonal carcinoma cells when the sequence is initially methylated and protects the local region from de novo methylation in post-implantation embryos. These results indicate that in the embryo protection from de novo methylation is not a unique feature of imprinted or housekeeping genes that carry a CpG island, but is also applicable to tissue-specific genes expressed during early stages of embryogenesis. Methylation of Oct-3/4 may be analogous to methylation of CpG islands on the inactive X chromosome that also occurs at later stages of development.

Beyond Watson and Crick: DNA methylation and molecular enzymology of DNA methyltransferases

DNA methyltransferases catalyze the transfer of a methyl group from S-adenosyl-L-methionine to cytosine or adenine bases in DNA. These enzymes challenge the Watson/Crick dogma in two instances: 1) They attach inheritable information to the DNA that is not encoded in the nucleotide sequence. This so-called epigenetic information has many important biological functions. In prokaryotes, DNA methylation is used to coordinate DNA replication and the cell cycle, to direct postreplicative mismatch repair, and to distinguish self and nonself DNA. In eukaryotes, DNA methylation contributes to the control of gene expression, the protection of the genome against selfish DNA, maintenance of genome integrity, parental imprinting, X-chromosome inactivation in mammals, and regulation of development. 2) The enzymatic mechanism of DNA methyltransferases is unusual, because these enzymes flip their target base out of the DNA helix and, thereby, locally disrupt the B-DNA helix. This review describes the biological functions of DNA methylation in bacteria, fungi, plants, and mammals. In addition, the structures and mechanisms of the DNA methyltransferases, which enable them to specifically recognize their DNA targets and to induce such large conformational changes of the DNA, are discussed.

Beyond Watson and Crick: DNA methylation and molecular enzymology of DNA methyltransferases

DNA methyltransferases catalyze the transfer of a methyl group from S-adenosyl-L-methionine to cytosine or adenine bases in DNA. These enzymes challenge the Watson/Crick dogma in two instances: 1) They attach inheritable information to the DNA that is not encoded in the nucleotide sequence. This so-called epigenetic information has many important biological functions. In prokaryotes, DNA methylation is used to coordinate DNA replication and the cell cycle, to direct postreplicative mismatch repair, and to distinguish self and nonself DNA. In eukaryotes, DNA methylation contributes to the control of gene expression, the protection of the genome against selfish DNA, maintenance of genome integrity, parental imprinting, X-chromosome inactivation in mammals, and regulation of development. 2) The enzymatic mechanism of DNA methyltransferases is unusual, because these enzymes flip their target base out of the DNA helix and, thereby, locally disrupt the B-DNA helix. This review describes the biological functions of DNA methylation in bacteria, fungi, plants, and mammals. In addition, the structures and mechanisms of the DNA methyltransferases, which enable them to specifically recognize their DNA targets and to induce such large conformational changes of the DNA, are discussed.

Site-specific DNA hypomethylation permits expression of the IRBP gene

Interphotoreceptor retinoid binding protein (IRBP), a putative component of the visual cycle, is expressed selectively in the retina and pineal gland. This study examined whether site-specific DNA hypomethylation plays a role in this expression regulation. Southern blotting of HpaII and MspI digests of DNA from various bovine and murine tissues (whole brain, retina, pineal gland, superior colliculus, cortex, thymus, habenular nucleus, cornea, liver, tail, and kidney) revealed that specific CpG dinucleotides in the IRBP gene promoter are hypomethylated in DNA from retinal photoreceptor cells and pineal gland compared to DNA from other tissues. These sites are methylated in DNA from non-photoreceptor retinal cells. Exogenous methylation of these sites diminished DNA:protein binding in electrophoretic mobility shift assays. HpaII methylation of chloramphenicol acetyltransferase reporter constructs suppressed IRBP but not SV40 promoter activity in transiently transfected primary cultures of embryonic chick retinal cells. These data indicate that specific cytosines in the bovine and murine IRBP promoters are unmethylated in photoreceptive cells but methylated in other tissues. This differential DNA methylation may modulate IRBP gene expression since exogenous methylation of the murine sites suppresses reporter gene transcription, apparently by inhibiting DNA:protein binding events.

The minimal repression domain of MBD2b overlaps with the methyl-CpG-binding domain and binds directly to Sin3A

Different mechanisms mediating methylation-dependent repression have been demonstrated. Two of these mechanisms play a role in the context of the granulocyte/macrophage-specific lysozyme gene: direct interference with DNA binding of the transcription factor GA-binding protein and deacetylation of histones. Besides enhancement in the unmethylated state, and transcriptional repression upon DNA methylation, the lysozyme downstream enhancer confers tissue-specific demethylation. Because both demethylation activity and repression ability have been attributed to the methyl-CpG-binding domain-containing protein MBD2, we analyzed this protein. The short form MBD2b binds to the methylated lysozyme enhancer and mediates transcriptional repression. MBD2b is capable of binding to the transcriptional repressor Sin3A. The interaction domain of Sin3A required for binding to MBD2b contains the paired amphipathic helix 3. We identified a minimal functional domain that confers both transcriptional repression as well as the interaction to Sin3A. In contrast to the functionally related proteins MeCP2 and MBD1, the repression domain of MBD2b overlaps with the methyl-CpG-binding domain.

Methylation of the promoter region may be involved in tissue-specific expression of the mouse terminal deoxynucleotidyl transferase gene

The terminal deoxynucleotidyl transferase gene (TdT) is expressed in mice only in early B and T lymphoid precursors a few days after birth. Transactivating factors have been shown to contribute to the lymphoid specific expression of TdT, but they do not account entirely for the restriction of its expression to early precursors. Since tissue-specific expression can be modulated by other mechanisms such as DNA methylation and DNA accessibility, we evaluated the methylation pattern of the TdT gene in various expressing and non-expressing tissues and cell lines. Lymphoid and non-lymphoid organs differed significantly in their methylation profiles. In the thymus nearly complete demethylation of a Hha I site in the promoter was associated with high levels of TdT transcription. There was similar, but weaker demethylation of the TdT promoter in bone marrow, possibly due to the presence of a few TdT expressing B cell precursors. The same methylation status was also associated with TdT expression in different B and T cell lines. Kinetic studies of TdT gene demethylation and TdT transcription during thymus development showed that changes in methylation status were also involved in the differential expression of TdT in fetal and adult life. Footprinting experiments revealed the existence of three regions specifically protected by nuclear extracts from TdT -expressing cells. Together, these results suggest that promoter demethylation is involved in the control of TdT expression and implicate new promoter regions in this regulation.

A chicken embryo protein related to the mammalian DEAD box protein p68 is tightly associated with the highly purified protein-RNA complex of 5-MeC-DNA glycosylase

We have shown previously that DNA demethylation by chick embryo 5-methylcytosine (5-MeC)-DNA glycosylase needs both protein and RNA. Amino acid sequences of nine peptides derived from a highly purified 5-MeC-DNA glycosylase complex were identified by Nanoelectrospray ionisation mass spectrometry to be identical to the mammalian nuclear DEAD box protein p68 RNA helicase. Antibodies directed against human p68 helicase cross-reacted with the purified 5-MeC-DNA glycosylase complex and immunoprecipitated the glycosylase activity. A 2690 bp cDNA coding for the chicken homologue of mammalian p68 was isolated and sequenced. Its derived amino acid sequence is almost identical to the human p68 DEAD box protein up to amino acid position 473 (from a total of 595). This sequence contains all the essential conserved motifs from the DEAD box proteins which are the ATPase, RNA unwinding and RNA binding motifs. The rest of the 122 amino acids in the C-terminal region rather diverge from the human p68 RNA helicase sequence. The recombinant chicken DEAD box protein expressed in Escherichia coli cross-reacts with the same p68 antibodies as the purified chicken embryo 5-MeC-DNA glycosylase complex. The recombinant protein has an RNA-dependent ATPase and an ATP-dependent helicase activity. However, in the presence or absence of RNA the recombinant protein had no 5-MeC-DNA glycosylase activity. In situ hybridisation of 5 day-old chicken embryos with antisense probes of the chicken DEAD box protein shows a high abundance of its transcripts in differentiating embryonic tissues.

Repression of the mouse M-lysozyme gene involves both hindrance of enhancer factor binding to the methylated enhancer and histone deacetylation

In many cases, gene repression mediated by CpG methylation has been demonstrated. Two different mechanisms have been postulated to explain the repressive effect of methylated CpG DNA: establishment of a repressive chromatin configuration and inhibition of DNA binding of transactivating factors. Using the M-lysozyme gene, we analyzed gene expression, CpG demethylation and the in vivo formation of enhancer/protein complexes after inducing demethylation or inhibiting histone deacetylases. We show that trans-cription of a methylated and silent mouse M-lysozyme gene can be induced upon the inhibition of histone deacetylases in the absence of demethylation or in vivo transactivating factor binding to the enhancer. In contrast, DNA demethylation induces both gene activity as well as enhancer complex formation. Therefore, both mechanisms play a role in lysozyme gene repression mediated by methylated DNA: (i) the enhancer cannot be loaded with transacting factors; and (ii) histone deacetylation inhibits transcription.

DNA demethylation: turning genes on

The regulation of eukaryotic gene expression is a complicated process involving the interaction of a large number of transacting factors with specific cis-regulatory elements. DNA methylation plays a role in this scheme by acting in cis to modulate protein-DNA interactions. Several lines of evidence indicate that methylation serves to silence transcription, mainly through indirect mechanisms involving the assembly of repressive nucleoprotein complexes. DNA demethylation is mostly an active enzymatic process, controlled by cis regulatory elements which provide binding sites for trans demethylation factors. In the immune system DNA methylation plays multiple roles, such as regulating both gene expression and gene rearrangement