The many faces of histone lysine methylation

Epigenetics in human disease and prospects for epigenetic therapy

Epigenetic mechanisms, which involve DNA and histone modifications, result in the heritable silencing of genes without a change in their coding sequence. The study of human disease has focused on genetic mechanisms, but disruption of the balance of epigenetic networks can cause several major pathologies, including cancer, syndromes involving chromosomal instabilities, and mental retardation. The development of new diagnostic tools might reveal other diseases that are caused by epigenetic alterations. Great potential lies in the development of 'epigenetic therapies'--several inhibitors of enzymes controlling epigenetic modifications, specifically DNA methyltransferases and histone deacetylases, have shown promising anti-tumorigenic effects for some malignancies.

Trypanosomatid histones

The histones are responsible for packaging and regulating access to eukaryotic genomes. Trypanosomatids are flagellated protists that diverged early from the eukaryotic lineage and include parasites that cause disease in humans and other mammals. Here, we review the properties of histones in parasitic trypanosomatids, from gene organization and sequence to expression, post-translational modification and function within chromatin. Phylogenetic and experimental analysis indicates that certain specifically conserved histone sequence motifs, particularly within the N-terminal 'tail' domains, possibly represent functionally important modification substrates conserved throughout the eukaryotic lineage. For example, histone H3 contains a highly conserved methylation substrate. Trypanosomatids also possess at least three variant histones. Among these is an orthologue of H2A.Z, a histone involved in protecting 'active' chromatin from silencing in yeast. Histones provide docking platforms for a variety of regulatory factors. The presence of histone modification and variant histones in trypanosomatids therefore represents evidence for a network that provides the discrimination required to regulate transcription, recombination, repair and chromosome replication and segregation.

The ubiquitin-conjugating DNA repair enzyme HR6A is a maternal factor essential for early embryonic development in mice

The Saccharomyces cerevisiae RAD6 protein is required for a surprising diversity of cellular processes, including sporulation and replicational damage bypass of DNA lesions. In mammals, two RAD6-related genes, HR6A and HR6B, encode highly homologous proteins. Here, we describe the phenotype of cells and mice deficient for the mHR6A gene. Just like mHR6B knockout mouse embryonic fibroblasts, mHR6A-deficient cells appear to have normal DNA damage resistance properties, but mHR6A knockout male and female mice display a small decrease in body weight. The necessity for at least one functional mHR6A (X-chromosomal) or mHR6B (autosomal) allele in all somatic cell types is supported by the fact that neither animals lacking both proteins nor females with only one intact mHR6A allele are viable. In striking contrast to mHR6B knockout males, which show a severe spermatogenic defect, mHR6A knockout males are normally fertile. However, mHR6A knockout females fail to produce offspring despite a normal ovarian histology and ovulation. The absence of mHR6A in oocytes prevents development beyond the embryonic two-cell stage but does not result in an aberrant methylation pattern of histone H3 at this early stage of mouse embryonic development. These observations support redundant but dose-dependent roles for HR6A and HR6B in somatic cell types and germ line cells in mammals.

Essential Role of GATA3 for the Maintenance of Type 2 Helper T (Th2) Cytokine Production and Chromatin Remodeling at the Th2 Cytokine Gene Loci

GATA3 expression is essential for type-2 helper T (Th2) cell differentiation. GATA3-mediated chromatin remodeling at the Th2 cytokine gene loci, including Th2-specific long range histone hyperacetylation of the interleukin (IL)-13/IL-4 gene loci, occurs in developing Th2 cells. However, little is known about the role of GATA3, if any, in the maintenance of established remodeled chromatin at the Th2 cytokine gene loci. Here, we established a Cre/LoxP-based site-specific recombination system in cultured CD4 T cells using a unique adenovirus-mediated gene transfer technique. This system allowed us to investigate the effect of loss of GATA3 expression in in vitro differentiated Th2 cells. After ablation of GATA3, we detected reduced production of all Th2 cytokines, increased DNA methylation at the IL-4 gene locus, and decreased histone hyperacetylation at the IL-5 gene locus but not significantly so at the IL-13/IL-4 gene loci. Thus, GATA3 plays important roles in the maintenance of the Th2 phenotype and continuous chromatin remodeling of the specific Th2 cytokine gene locus through cell division.

A silencing pathway to induce H3-K9 and H4-K20 trimethylation at constitutive heterochromatin

Histone lysine methylation is a central modification to mark functionally distinct chromatin regions. In particular, H3-K9 trimethylation has emerged as a hallmark of pericentric heterochromatin in mammals. Here we show that H4-K20 trimethylation is also focally enriched at pericentric heterochromatin. Intriguingly, H3-K9 trimethylation by the Suv39h HMTases is required for the induction of H4-K20 trimethylation, although the H4 Lys 20 position is not an intrinsic substrate for these enzymes. By using a candidate approach, we identified Suv4-20h1 and Suv4-20h2 as two novel SET domain HMTases that localize to pericentric heterochromatin and specifically act as nucleosomal H4-K20 trimethylating enzymes. Interaction of the Suv4-20h enzymes with HP1 isoforms suggests a sequential mechanism to establish H3-K9 and H4-K20 trimethylation at pericentric heterochromatin. Heterochromatic H4-K20 trimethylation is evolutionarily conserved, and in Drosophila, the Suv4-20 homolog is a novel PEV modifier to regulate position-effect variegation. Together, our data indicate a function for H4-K20 trimethylation in gene silencing and further suggest H3-K9 and H4-K20 trimethylation as important components of a repressive pathway that can index pericentric heterochromatin.

Different EZH2-containing complexes target methylation of histone H1 or nucleosomal histone H3

Human Enhancer of Zeste homolog (Ezh2) is a histone lysine methyltransferase (HKMT) associated with transcriptional repression. Ezh2 is present in several distinct complexes, one of which, PRC2, we characterized previously. Here we report an additional Ezh2 complex, PRC3. We show that the Ezh2 complexes exhibit differential targeting of specific histones for lysine methylation dependent upon the context of the histone substrates. This differential targeting is a function of the associated Eed protein within each complex. We found that Eed protein is present in four isoforms, which represent alternate translation start site usage from the same mRNA. These Eed isoforms selectively associate with distinct Ezh2-containing complexes with resultant differential targeting of their associated HKMT activity toward histone H3-K27 or histone H1-K26. Our data provide evidence for a novel mechanism regulating the substrate specificity of a chromatin-modifying enzyme through disparate translational products of a regulatory subunit.

Chromatin immunoprecipitation microarrays for identification of genes silenced by histone H3 lysine 9 methylation

Switching from acetylation to methylation at histone H3 lysine 9 (K9) has recently been shown to contribute to euchromatin gene silencing. To identify genes silenced by K9 modifications, we probed a human CpG island microarray with DNA obtained by chromatin immunoprecipitation (ChIP) in a cancer cell line using an anti-H3-K9 methylated antibody or an anti-H3-K9 acetylated antibody. Of the 27 clones with the highest signal ratio of K9 methylation over acetylation (Me/Ac), 13 contained repetitive sequences. Among 14 nonrepetitive clones, we identified 11 genes (seven known and four previously undescribed), one EST, and two unknown fragments. Using ChIP-PCR, all 18 examined clones showed higher ratios of H3-K9 Me/Ac than the active gene control, P21, thus confirming the microarray data. In addition, we found a strong correlation between the K9 Me/Ac ratio and CpG island DNA methylation (R = 0.92, P < 0.01), and five of seven genes examined (megalin, thrombospondin-4, KR18, latrophilin-3, and phosphatidylinositol-3-OH kinase P101 subunit) showed lack of expression by RT-PCR and reactivation by DNA methylation and/or histone deacetylase inhibition, suggesting that these genes are true targets of silencing through histone modifications. All five genes also showed significant DNA methylation in a cell line panel and in primary colon cancers. Our data suggest that CpG island microarray coupled with ChIP can identify novel targets of gene silencing in cancer. This unbiased approach confirms the tight coupling between DNA methylation and histone modifications in cancer and could be used to probe gene silencing in nonneoplastic conditions as well.

Deletion of the Pemt gene increases progenitor cell mitosis, DNA and protein methylation and decreases calretinin expression in embryonic day 17 mouse hippocampus

Choline is a required nutrient and is derived from the diet as well as from de novo synthesis catalyzed by phosphatidylethanolamine N-methyltransferase (PEMT). We previously reported that choline availability during pregnancy alters mitosis and neuronal protein expression during fetal brain development in wild-type mice and rats, and that Pemt-/- mice become choline deficient. In this study, we examined brain development in these knockout mice. Pregnant Pemt-/- and wild-type mice were fed AIN-76A diet until gestation day 17 (E17) when the fetal brains were harvested. Phosphorylation of histone H3 (a measure of mitosis) and calretinin (a GABAergic neuronal marker) were assessed in hippocampal regions. We observed increased numbers of phosphorylated histone H3 positive cells in the Pemt-/- mice (up 54% compared to wild-type mice; p<0.01). We also found decreased calretinin labeling in Pemt-/- (down to 43% compared to wild-type mice; p<0.01). Thus, there was increased stem cell proliferation in the neuroepithelium and decreased GABAergic neuronal differentiation of these animals on E17. These results are opposite to what would have been expected in choline-deficient mice. The concentrations of S-adenosylmethionine (up 21%; p<0.05) and methylation of DNA (up 46%) and proteins (up 12%; p<0.01) in hippocampus were significantly increased in Pemt-/- mice, suggesting that increased S-adenosylmethionine availability may mediate the observed developmental changes. This is the first report of altered brain development in Pemt-/- mice.

Dynamic assembly of silent chromatin during thymocyte maturation

Considerable knowledge has been gained from temporal analyses of molecular events culminating in gene activation, but technical hurdles have hindered comparable studies of gene silencing. Here we describe the temporal assembly of silent chromatin at the mouse terminal transferase gene (Dntt), which is silenced and repositioned to pericentromeric heterochromatin during thymocyte maturation. Silencing was nucleated at the Dntt promoter by the ordered deacetylation of histone H3 at Lys9 (H3-Lys9), loss of methylation at H3-Lys4 and acquisition of methylation at H3-Lys9, followed by bidirectional spreading of each event. Deacetylation at H3-Lys9 coincided with pericentromeric repositioning, and neither of these early events required de novo protein synthesis. CpG methylation increased primarily in mature T cells that had left the thymus. A transformed thymocyte line supported reversible inactivation of Dntt without repositioning. In these cells, histone modification changes were nucleated at the promoter but did not spread. These results provide a foundation for elucidating the mechanisms of silent chromatin assembly during development.

The C. elegans Tousled-like kinase (TLK-1) has an essential role in transcription

BACKGROUND

The Tousled kinases comprise an evolutionarily conserved family of proteins that have been previously implicated in chromatin remodeling, DNA replication, and DNA repair. Here, we used RNA mediated interference (RNAi) to determine the function of the C. elegans Tousled kinase (TLK-1) during embryonic development.

RESULTS

TLK-1-deficient embryos arrested with a phenotype reminiscent of embryos that are broadly defective in transcription, and the expression of several reporter genes was dramatically reduced in tlk-1(RNAi) embryos. Furthermore, posttranslational modifications of RNA polymerase II (RNAPII) and histone H3 that have been correlated with transcription elongation, phosphorylation of the RNAPII CTD at Serine 2, and methylation of histone H3 at Lysine 36 were found at significantly reduced levels in tlk-1(RNAi) embryos as compared to wild-type.

CONCLUSIONS

These results reveal a surprising requirement for a Tousled-like kinase in transcriptional regulation during development, likely during the elongation phase. In addition, our results confirm that the link between RNAPII phosphorylation and histone H3 methylation previously observed in budding yeast is functionally conserved in metazoans.

Epigenetic Control of Mouse Oct-4 Gene Expression in Embryonic Stem Cells and Trophoblast Stem Cells

The first cell differentiation event in mammalian embryogenesis segregates inner cell mass lineage from the trophectoderm at the blastocyst stage. Oct-4, a member of the POU family of transcription factors, is necessary for the pluripotency of the inner cell mass lineage. Embryonic stem (ES) cells, which contribute to all of embryonic lineages, express the Oct-4 gene. Trophoblast stem (TS) cells, which have the ability to differentiate into trophoblast lineage in vitro, never contribute to embryonic proper tissues in chimeras and differentiate only into trophoblastic cells in the placenta. Expression of the Oct-4 gene was undetectable and severely repressed in trophoblastic lineage, including the stem cells. We found that the culture of TS cells with 5-aza-2'-deoxycytidine or trichostatin A caused the activation of the Oct-4 gene. Analysis of the DNA methylation status of mouse Oct-4 gene upstream region revealed that Oct-4 enhancer/promoter region was hypomethylated in ES cells but hypermethylated in TS cells. Furthermore, in vitro methylation suppressed Oct-4 enhancer/promoter activity in reporter assay. In the placenta of Dnmt1(n/n) mutant mice, most of the CpGs in the enhancer/promoter region were unmethylated, and Oct-4 gene expression was aberrantly detected. Chromatin immunoprecipitation assay revealed that Oct-4 enhancer/promoter region was hyperacetylated in ES cells compared with TS cells, thus demonstrating that DNA methylation status is closely linked to the chromatin structure of the Oct-4 gene. Here we propose that the epigenetic mechanism, consisting of DNA methylation and chromatin remodeling, underlies the developmental stage- and cell type-specific mechanism of Oct-4 gene expression.

REST and Peace for the Neuronal-Specific Transcriptional Program

Despite a genetic homogeneity, cells in multicellular organisms are structurally and functionally heterogeneous. The diversity of cell phenotypes exists due to differential transcriptional programs precisely regulated by specific nuclear factors and induced upon differentiation. The differences in gene expression programs arise during development and become heritable during cell proliferation. Over the last few years, research has focused on three molecular mechanisms that mediate epigenetic phenomena: DNA methylation, histone modification, and formation of specialized nuclear domains or territories. All of these processes are dynamic and tightly linked to the organism's development. Here we review advances in understanding the significance of epigenetic mechanisms in the establishment and maintenance of the specialized transcriptional program. We project the accumulated knowledge onto the delineation of the molecular mechanisms by which central nervous system-specific genes are expressed in the nervous system and repressed in other tissues.

PRDI-BF1 recruits the histone H3 methyltransferase G9a in transcriptional silencing

PRDI-BF1, the human ortholog of mouse Blimp-1, is a DNA-binding protein involved in postinduction repression of interferon-beta gene transcription in response to viral infection. PRDI-BF1 also has an essential function in driving terminal differentiation of B lymphocytes and therein silences multiple genes. Here we show PRDI-BF1 assembles silent chromatin over the interferon-beta promoter in the osteosarcoma cell line U2OS through recruitment of the histone H3 lysine methyltransferase G9a. G9a is recruited only when in a complex with PRDI-BF1. G9a catalytic activity is required for the accumulation of methylated histone H3 and transcriptional silencing mediated by PRDI-BF1 in vivo. This establishes a mechanism for the recruitment of G9a, the main mammalian euchromatic methyltransferase, and defines nonembryonic targets of G9a.

Partitioning and plasticity of repressive histone methylation states in mammalian chromatin

Methylation of position-specific lysine residues in histone N termini is a central modification for regulating epigenetic transitions in chromatin. Each methylatable lysine residue can exist in a mono-, di-, or trimethylated state, thereby extending the indexing potential of this particular modification. Here, we examine all possible methylation states for histone H3 lysine 9 (H3-K9) and lysine 27 (H3-K27) in mammalian chromatin. Using highly specific antibodies together with quantitative mass spectrometry, we demonstrate that pericentric heterochromatin is selectively enriched for H3-K27 monomethylation and H3-K9 trimethylation. This heterochromatic methylation profile is dependent on the Suv39h histone methyltransferases (HMTases) but independent of the euchromatic G9a HMTase. In Suv39h double null cells, pericentric heterochromatin is converted to alternative methylation imprints and accumulates H3-K27 trimethylation and H3-K9 monomethylation. Our data underscore the selective presence of distinct histone lysine methylation states in partitioning chromosomal subdomains but also reveal a surprising plasticity in propagating methylation patterns in eukaryotic chromatin.

A Distal Enhancer in the Interferon-γ (IFN-γ) Locus Revealed by Genome Sequence Comparison

Large-scale cross-species DNA sequence comparison has become a powerful tool to identify conserved cis-regulatory modules of genes. However, bioinformatic analysis alone cannot reveal how an evolutionarily conserved region regulates gene expression: whether it functions as an enhancer, silencer, or insulator; whether its function is cell-type restricted; and whether biologically relevant transcription factors bind to the element. Here we combine bioinformatics with wet-lab techniques to illustrate a general and systematic method of identifying functional conserved regulatory regions of genes. We applied this approach to the interferon-gamma (IFN-gamma) gene. Comparison of human and mouse IFN-gamma reveals a highly conserved non-coding sequence located approximately 5 kb 5' of the transcription start site. This region coincides with constitutive and inducible DNase I hypersensitivity sites present in IFN-gamma-producing Th1 cells but not in Th2 cells that do not produce IFN-gamma. Histone methylation at the 5' conserved non-coding sequences indicates a more accessible chromatin structure in Th1 cells compared with Th2 cells. This element binds two transcription factors known to be essential for IFN-gamma expression: nuclear factor of activated T cells, an inducible transcription factor, and T-box protein expressed in T cells, a cell lineage-restricted transcription factor. Together, these findings identify a highly conserved distal enhancer in the IFN-gamma cytokine locus and validate our approach as a successful method to detect cis-regulatory elements.

Histone H3 lysine 9 methylation is required for DNA elimination in developing macronuclei in Tetrahymena

Genome-wide DNA elimination accompanies development of the somatic macronucleus from the germ-line micronucleus during the sexual process of conjugation in the ciliated protozoan Tetrahymena thermophila. Small RNAs, referred to as "scan RNAs" (scnRNAs), that accumulate only during conjugation are highly enriched in the eliminated sequences, and mutations that prevent DNA elimination also affect the accumulation of scnRNAs, suggesting that an RNA interference (RNAi)-like mechanism is involved in DNA elimination. Histone H3 that is methylated at lysine 9 (K9) is a hallmark of heterochromatin and, in Tetrahymena, is found only in developing macronuclei (anlagen) in association with chromatin containing the sequences undergoing elimination. In this article, we demonstrate that a mutation in the TWI1 gene that eliminates the accumulation of scnRNAs also abolishes H3 methylation at K9. We created mutant strains of Tetrahymena in which the only major H3 contained a K9Q mutation. These mutants accumulated scnRNAs normally during conjugation but showed dramatically reduced efficiency of DNA elimination. These results provide strong genetic evidence linking an RNAi-like pathway, H3 K9 methylation, and DNA elimination in Tetrahymena.

Snail mediates E-cadherin repression by the recruitment of the Sin3A/histone deacetylase 1 (HDAC1)/HDAC2 complex

The transcription factor Snail has been described as a direct repressor of E-cadherin expression during development and carcinogenesis; however, the specific mechanisms involved in this process remain largely unknown. Here we show that mammalian Snail requires histone deacetylase (HDAC) activity to repress E-cadherin promoter and that treatment with trichostatin A (TSA) is sufficient to block the repressor effect of Snail. Moreover, overexpression of Snail is correlated with deacetylation of histones H3 and H4 at the E-cadherin promoter, and TSA treatment in Snail-expressing cells reverses the acetylation status of histones. Additionally, we demonstrate that Snail interacts in vivo with the E-cadherin promoter and recruits HDAC activity. Most importantly, we demonstrate an interaction between Snail, histone deacetylase 1 (HDAC1) and HDAC2, and the corepressor mSin3A. This interaction is dependent on the SNAG domain of Snail, indicating that the Snail transcription factor mediates the repression by recruitment of chromatin-modifying activities, forming a multimolecular complex to repress E-cadherin expression. Our results establish a direct causal relationship between Snail-dependent repression of E-cadherin and the modification of chromatin at its promoter.

Prospects and implications of using chromatin insulators in gene therapy and transgenesis

Gene therapy has emerged from the idea of inserting a wild-type copy of a gene in order to restore the proper expression and function of a damaged gene. Initial efforts have focused on finding the proper vector and delivery method to introduce a corrected gene to the affected tissue or cell type. Even though these first attempts are clearly promising, several problems remain unsolved. A major problem is the influence of chromatin structure on transgene expression. To overcome chromatin-dependent repressive transgenic states, researchers have begun to use chromatin regulatory elements to drive transgene expression. Insulators or chromatin boundaries are able to protect a transgene against chromatin position effects at their genomic integration sites, and they are able to maintain transgene expression for long periods of time. Therefore, these elements may be very useful tools in gene therapy applications for ensuring high-level and stable expression of transgenes.

Visualizing chromosome structure/organization

With the rapid development of sequencing technologies in the past decade, many eukaryotic genomes have been resolved at the primary sequence level. However, organization of the genome within nuclei and the principles that govern such properties remain largely unclear. Optimization of fluorescence probe-based hybridization technologies combined with new advances in the instrumentation for microscopy has steadily yielded more structural information on chromosome organization in eukaryote model systems. These studies provide static snapshots of the detailed organization of chromatin. More recently, the successful application of a chromatin tagging strategy utilizing auto fluorescent fusion proteins opened a new era of chromatin studies in which the dynamic organization of the genome can be tracked in near real time. This review focuses on these new approaches to studying chromatin organization and dynamics in plants, and on future prospects in unraveling the basic principle of chromosome organization.

A conserved chromatin architecture marks and maintains the restricted germ cell lineage in worms and flies

In C. elegans, mRNA production is initially repressed in the embryonic germline by a protein unique to C. elegans germ cells, PIE-1. PIE-1 is degraded upon the birth of the germ cell precursors, Z2 and Z3. We have identified a chromatin-based mechanism that succeeds PIE-1 repression in these cells. A subset of nucleosomal histone modifications, methylated lysine 4 on histone H3 (H3meK4) and acetylated lysine 8 on histone H4 (H4acetylK8), are globally lost and the DNA appears more condensed. This coincides with PIE-1 degradation and requires that germline identity is not disrupted. Drosophila pole cell chromatin also lacks H3meK4, indicating that a unique chromatin architecture is a conserved feature of embryonic germ cells. Regulation of the germline-specific chromatin architecture requires functional nanos activity in both organisms. These results indicate that genome-wide repression via a nanos-regulated, germ cell-specific chromatin organization is a conserved feature of germline maintenance during embryogenesis.

Derepression of BDNF transcription involves calcium-dependent phosphorylation of MeCP2

Mutations in MeCP2, which encodes a protein that has been proposed to function as a global transcriptional repressor, are the cause of Rett syndrome (RT T), an X-linked progressive neurological disorder. Although the selective inactivation of MeCP2 in neurons is sufficient to confer a Rett-like phenotype in mice, the specific functions of MeCP2 in postmitotic neurons are not known. We find that MeCP2 binds selectively to BDNF promoter III and functions to repress expression of the BDNF gene. Membrane depolarization triggers the calcium-dependent phosphorylation and release of MeCP2 from BDNF promoter III, thereby facilitating transcription. These studies indicate that MeCP2 plays a key role in the control of neuronal activity-dependent gene regulation and suggest that the deregulation of this process may underlie the pathology of RT T.

Paternal imprints can be established on the maternal Igf2-H19 locus without altering replication timing of DNA

Genomic imprinting in mammals marks the parental alleles in gametes, resulting in differential gene expression in offspring. A number of epigenetic features are associated with imprinted genes. These include differential DNA methylation, histone acetylation and methylation, subnuclear localization and DNA replication timing. While DNA methylation has been shown to be necessary both for establishment and maintenance of imprinting, the connections with the other types of epigenetic marking systems are not clear. Specifically, it is not known whether the other marking systems, either on their own or in conjunction with DNA methylation, are required for imprinting. Here we show that in the mouse mutant Minute (Mnt) the Igf2-H19 locus acquires a paternal methylation imprint in the maternal germline. DNA methylation of the H19 DMR is established in oogenesis, maintained during postzygotic development on the maternal allele, and erased in primordial germ cells. The fact that a paternal type methylation imprint can also be established in the maternal germline indicates that trans-acting factors that target methylation to this imprinted region are likely to be the same in both germlines. Surprisingly, however, asynchrony of DNA replication of the locus is maintained despite the altered expression and methylation imprint of Igf2 and H19. These results show clearly that replication asynchrony of this region is neither the determinant factor for, nor a consequence of, epigenetic modifications that are critical for genomic imprinting. Replication asynchrony may thus be regulated differently from methylation imprints and have a separate function.

SET domains and histone methylation

The realisation that SET domains, which are found in numerous proteins involved in chromatin regulation, catalyse the methylation of lysine residues has led to intense interest in their cellular, biochemical and structural properties. The structures of five SET domain proteins have been reported over the past year. SET domains possess a novel fold, and use adjacent domains for both structural stabilisation and the completion of their active sites. The cofactor S-adenosyl-L-methionine and peptide substrates bind on opposite faces of the SET domain. Remarkably, the sidechain of the target lysine approaches the transferred methyl group through a narrow channel that passes through the middle of the domain.

mAM facilitates conversion by ESET of dimethyl to trimethyl lysine 9 of histone H3 to cause transcriptional repression

Methylation of histone tails plays an important role in chromatin structure and function. Previously, we reported that ESET/SETDB1 is a histone methyltransferase (HMTase). Here, we show that SETDB1 tightly associates with the human homolog of mAM, a murine ATFa-associated factor. Although recombinant ESET can methylate lysine 9 of histone H3 (H3-K9), its activity is severely compromised when compared to that of the ESET/mAM complex. mAM stimulates ESET enzymatic activity by increasing the Vmax and decreasing the Km. Importantly, mAM facilitates the ESET-dependent conversion of dimethyl H3-K9 to the trimethyl state both in vitro and in vivo. Chromatin-based transcription and ChIP analyses demonstrate that mAM enhances ESET-mediated transcriptional repression in a SAM-dependent manner, and this repression correlates with H3-K9 trimethylation at the promoter. Thus, our studies establish that promoter H3-K9 trimethylation is the cause of transcriptional repression and that mAM/hAM facilitates conversion of H3-K9 dimethyl to trimethyl by ESET/SETDB1.

The rise and fall of genomic methylation in cancer

Changes in genomic methylation and its significance in carcinogenesis is in the spotlight once again, though the focus is not on the usual suspects, DNA hypermethylation and tumour suppressor gene (TSG) silencing. Several recent reports provide compelling evidence of the relevance of genomic hypomethylation in cancer. These findings provide the best evidence so far that links the loss of DNA methylation and chromosomal instability with cancer development. This review article discusses these recent findings and reflects on the antithetical association between DNA methylation and carcinogenesis and the re-examination of studies performed almost two decades ago.

DNMT cooperativity--the developing links between methylation, chromatin structure and cancer

Controversy has reigned for some time over the biological connection between DNA methylation and cancer. For this reason, the methylation mechanism responsible for increased cancer risk has received greater attention in recent years. Tumor suppressor genes are often hypermethylated resulting in gene silencing. Although some have questioned this interpretation of the link between methylation and cancer, it appears that both hypermethylation and hypomethylation events can create epigenetic changes that can contribute to cancer development. Recent studies have shown that the methyltransferases DNMT1 and DNMT3b cooperatively maintain DNA methylation and gene silencing in human cancer cells. Disruption of the human DNMT3b only slightly reduces the overall global DNA methylation; however, demethylation was markedly potentiated when both DNMT1 and DNMT3b were simultaneously deleted. The results to these experiments provide compelling evidence towards a role for DNA methylation in cancer. This review discusses the current understanding of cancer-epigenetic information and highlights recent studies that connect the methylation machinery and chromatin remodelling with cancer susceptibility.

Randomly inserted and targeted Hox/reporter fusions transcriptionally silenced in Polycomb mutants

Polycomb-group (Pc-G) proteins ensure late maintenance of transcriptional repression outside the expression domain of target genes in flies and vertebrates. They act in complexes, presumably by modulating chromatin structure. In Drosophila, they have been found to be associated with transcriptionally inactive loci but seem to be present in association with actively transcribed promoters as well, a feature which is not yet understood. In the mouse, mutations in several Pc-G genes result in an often subtle, local derepression of only a subset of the Hox genes rostral to their expression domains. We report here that Hox/reporter fusion genes, either randomly integrated as transgenes or as insertions within endogenous loci, are transcriptionally silenced in two mouse Pc-G-null mutants, Mel18 and rae28. Transcriptional silencing of Hox/reporter transgenes in Pc-G mutants was accompanied by increased DNA methylation in the promoter region. Gene silencing was observed at early developmental stages, long before Pc-G and trithorax-group proteins exert their function in maintenance of the Hox patterns. Although all five Hox genes tested as Hox/reporter fusions were silenced in the Pc-G mutants, transcription of the endogenous loci was mildly decreased in a subset of these Hox genes, and Hoxb1 was the most strongly affected. We discuss the possibilities that the observed negative effect of Pc-G mutations on Hox and Hox/reporter expression may reflect a positive involvement of the Pc-G epigenetic repressors in initial Hox gene transcription and that this requirement is exacerbated by the reporter insertion.

Involvement of the histone deacetylase SIRT1 in chicken ovalbumin upstream promoter transcription factor (COUP-TF)-interacting protein 2-mediated transcriptional repression

Chicken ovalbumin upstream promoter transcription factor (COUP-TF)-interacting proteins 1 and 2 (CTIP1 and CTIP2) enhance transcriptional repression mediated by COUP-TF II and have been implicated in hematopoietic cell development and malignancies. CTIP1 and CTIP2 are also sequence-specific DNA-binding proteins that repress transcription through direct, COUP-TF-in-dependent binding to a GC-rich response element. CTIP1- and CTIP2-mediated transcriptional repression is insensitive to trichostatin A, an inhibitor of known class I and II histone deacetylases. However, chromatin immunoprecipitation assays revealed that expression of CTIP2 in mammalian cells resulted in deacetylation of histones H3 and/or H4 that were associated with the promoter region of a reporter gene. CTIP2-mediated transcriptional repression, as well as deacetylation of promoter-associated histones H3/H4 in CTIP2-transfected cells, was reversed by nicotinamide, an inhibitor of class III histone deacetylases such as the mammalian homologs of yeast Silent Information Regulator 2 (Sir2). The human homolog of yeast Sir2, SIRT1, was found to interact directly with CTIP2 and was recruited to the promoter template in a CTIP2-dependent manner. Moreover, SIRT1 enhanced the deacetylation of template-associated histones H3/H4 in CTIP2-transfected cells, and stimulated CTIP2-dependent transcriptional repression. Finally, endogenous SIRT1 and CTIP2 co-purified from Jurkat cell nuclear extracts in the context of a large (1-2 mDa) complex. These findings implicate SIRT1 as a histone H3/H4 deacetylase in mammalian cells and in transcriptional repression mediated by CTIP2.

Binary switches and modification cassettes in histone biology and beyond

An immense number of post-translational modifications on histone proteins have been described and additional sites of modification are still being uncovered. Whereas many direct and indirect connections between certain histone modifications and distinct biological phenomena have now been established, concepts for comprehending the extreme density and variety of these covalent modifications are lacking. Here, we formally introduce localized 'binary switches' and 'modification cassettes' as new concepts in histone biology, elucidating mechanisms that might govern the biological readout of distinct modification patterns. Specifically, our hypotheses provide missing models for the dynamic readout of stable histone modifications and offer explanations for several long-standing questions embedded in the literature. Our ideas might also apply to non-histone proteins and are open to direct experimental examination.

The eukaryotic genome: a system regulated at different hierarchical levels

Eukaryotic gene expression can be viewed within a conceptual framework in which regulatory mechanisms are integrated at three hierarchical levels. The first is the sequence level, i.e. the linear organization of transcription units and regulatory sequences. Here, developmentally co-regulated genes seem to be organized in clusters in the genome, which constitute individual functional units. The second is the chromatin level, which allows switching between different functional states. Switching between a state that suppresses transcription and one that is permissive for gene activity probably occurs at the level of the gene cluster, involving changes in chromatin structure that are controlled by the interplay between histone modification, DNA methylation, and a variety of repressive and activating mechanisms. This regulatory level is combined with control mechanisms that switch individual genes in the cluster on and off, depending on the properties of the promoter. The third level is the nuclear level, which includes the dynamic 3D spatial organization of the genome inside the cell nucleus. The nucleus is structurally and functionally compartmentalized and epigenetic regulation of gene expression may involve repositioning of loci in the nucleus through changes in large-scale chromatin structure.

Facile synthesis of site-specifically acetylated and methylated histone proteins: reagents for evaluation of the histone code hypothesis

The functional capacity of genetically encoded histone proteins can be powerfully expanded by posttranslational modification. A growing body of biochemical and genetic evidence clearly links the unique combinatorial patterning of side chain acetylation, methylation, and phosphorylation mainly within the highly conserved N termini of histones H2A, H2B, H3, and H4 with the regulation of gene expression and chromatin assembly and remodeling, in effect constituting a "histone code" for epigenetic signaling. Deconvoluting this code has proved challenging given the inherent posttranslational heterogeneity of histone proteins isolated from biological sources. Here we describe the application of native chemical ligation to the preparation of full-length histone proteins containing site-specific acetylation and methylation modifications. Peptide thioesters corresponding to histone N termini were prepared by solid phase peptide synthesis using an acid labile Boc/HF assembly strategy, then subsequently ligated to recombinantly produced histone C-terminal globular domains containing an engineered N-terminal cysteine residue. The ligation site is then rendered traceless by hydrogenolytic desulfurization, generating a native histone protein sequence. Synthetic histones generated by this method are fully functional, as evidenced by their self-assembly into a higher order H3/H4 heterotetramer, their deposition into nucleosomes by human ISWI-containing (Imitation of Switch) factor RSF (Remodeling and Spacing Factor), and by enzymatic modification by human Sirt1 deacetylase and G9a methyltransferase. Site-specifically modified histone proteins generated by this method will prove invaluable as novel reagents for the evaluation of the histone code hypothesis and analysis of epigenetic signaling mechanisms.

Age-related epigenetic changes and the immune system

The role of DNA methylation in immune function is discussed extensively in other papers in this issue. Many of these discussions assume that DNA methylation, a major mediator of epigenetic information, is fairly immutable and uniform in adult cells and tissues. There is, however, growing evidence that DNA methylation changes subtly with age. Normal aging cells and tissues show a progressive loss of 5-methylcytosine content, primarily within DNA repeated sequences, but also in potential gene regulatory areas. In parallel, selected genes show progressive age-related increases in promoter methylation, which, once a critical methylation density is reached, have the potential to permanently silence gene expression. These changes are highly mosaic within a given tissue and introduce a high degree of epigenetic variability in aging cells. Such epigenetic phenomena could impact immune response through masking/unmasking potential tissue antigens as well as by modulating the differentiation and response of immune effector cells. The contribution of epigenetic changes to the altered immune function observed in aging humans deserves careful investigation.

Lsh, a modulator of CpG methylation, is crucial for normal histone methylation

Methylation of histone tails and CpG methylation are involved in determining heterochromatin structure, but their cause and effect relationship has not been resolved as yet in mammals. Here we report that Lsh, a member of the SNF2 chromatin remodeling family, controls both types of epigenetic modifications. Lsh has been shown to be associated with pericentromeric heterochromatin and to be required for normal CpG methylation at pericentromeric sequences. Loss of Lsh, in Lsh-deficient mice, results in accumulation of di- and tri-methylated histone 3 at lysine 4 (H3-K4me) at pericentromeric DNA and other repetitive sequences. In contrast, di- or tri-methylation of H3-K9 and distribution of HP1 appear unchanged after Lsh deletion, suggesting independent regulatory mechanisms for H3-K4 or K9 methylation. Experimental DNA demethylation with 5'-azacytidine results in a similar increase of H3-K4me. These results support the model that loss of CpG methylation caused by Lsh deficiency antecedes elevation of H3-K4me. Thus, Lsh is crucial for the formation of normal heterochromatin, implying a functional role for Lsh in the regulation of transcription and mitosis.

Inheritance of gene density-related higher order chromatin arrangements in normal and tumor cell nuclei

A gene density-related difference in the radial arrangement of chromosome territories (CTs) was previously described for human lymphocyte nuclei with gene-poor CT #18 located toward the nuclear periphery and gene-dense CT #19 in the nuclear interior (Croft, J.A., J.M. Bridger, S. Boyle, P. Perry, P. Teague, and W.A. Bickmore. 1999. J. Cell Biol. 145:1119-1131). Here, we analyzed the radial distribution of chromosome 18 and 19 chromatin in six normal cell types and in eight tumor cell lines, some of them with imbalances and rearrangements of the two chromosomes. Our findings demonstrate that a significant difference in the radial distribution of #18 and #19 chromatin is a common feature of higher order chromatin architecture in both normal and malignant cell types. However, in seven of eight tumor cell lines, the difference was less pronounced compared with normal cell nuclei due to a higher fraction of nuclei showing an inverted CT position, i.e., a CT #18 located more internally than a CT #19. This observation emphasizes a partial loss of radial chromatin order in tumor cell nuclei.

Molecular basis for the discrimination of repressive methyl-lysine marks in histone H3 by Polycomb and HP1 chromodomains

On the histone H3 tail, Lys 9 and Lys 27 are both methylation sites associated with epigenetic repression, and reside within a highly related sequence motif ARKS. Here we show that the chromodomain proteins Polycomb (Pc) and HP1 (heterochromatin protein 1) are highly discriminatory for binding to these sites in vivo and in vitro. In Drosophila S2 cells, and on polytene chromosomes, methyl-Lys 27 and Pc are both excluded from areas that are enriched in methyl-Lys 9 and HP1. Swapping of the chromodomain regions of Pc and HP1 is sufficient for switching the nuclear localization patterns of these factors, indicating a role for their chromodomains in both target site binding and discrimination. To better understand the molecular basis for the selection of methyl-lysine binding sites, we solved the 1.8 A structure of the Pc chromodomain in complex with a H3 peptide bearing trimethyl-Lys 27, and compared it with our previously determined structure of the HP1 chromodomain in complex with a H3 peptide bearing trimethyl-Lys 9. The Pc chromodomain distinguishes its methylation target on the H3 tail via an extended recognition groove that binds five additional residues preceding the ARKS motif.

Epigenetic silencing of RNA polymerase I transcription

The genes that encode ribosomal RNA exist in two distinct types of chromatin--an 'open' conformation that is permissive to transcription and a 'closed' conformation that is transcriptionally refractive. Recent studies have provided insights into the molecular mechanisms that silence either entire nucleolus organizer regions (NORs) in genetic hybrids or individual rRNA genes within a NOR. An emerging theme from these studies is that epigenetic mechanisms operating at the level of DNA methylation and histone modifications alter the chromatin structure and control the ratio of active and inactive rRNA genes.

Structural basis for specific binding of Polycomb chromodomain to histone H3 methylated at Lys 27

The chromodomain of Drosophila Polycomb protein is essential for maintaining the silencing state of homeotic genes during development. Recent studies suggest that Polycomb mediates the assembly of repressive higher-order chromatin structures in conjunction with the methylation of Lys 27 of histone H3 by a Polycomb group repressor complex. A similar mechanism in heterochromatin assembly is mediated by HP1, a chromodomain protein that binds to histone H3 methylated at Lys 9. To understand the molecular mechanism of the methyl-Lys 27 histone code recognition, we have determined a 1.4-A-resolution structure of the chromodomain of Polycomb in complex with a histone H3 peptide trimethylated at Lys 27. The structure reveals a conserved mode of methyl-lysine binding and identifies Polycomb-specific interactions with histone H3. The structure also reveals a dPC dimer in the crystal lattice that is mediated by residues specifically conserved in the Polycomb family of chromodomains. The dimerization of dPC can effectively account for the histone-binding specificity and provides new mechanistic insights into the function of Polycomb. We propose that self-association is functionally important for Polycomb.

RNA interference: gene silencing in the fast lane

Sequencing of whole genomes has provided new perspectives into the blueprints of diverse organisms. Knowing the sequences, however, does not always tell us much about the function of the genes that regulate development and homeostasis. RNA interference (RNAi) is becoming the method of choice for gene function analysis in cells and whole organisms. Here we review the approaches available to perform RNAi experiments in mammalian cells and in mice. We discuss usage of RNAi in cancer research and as a possible therapeutic tool for cancer treatment.

Analysis of specific lysine histone H3 and H4 acetylation and methylation status in clones of cells with a gene silenced by nickel exposure

We have previously reported that the gpt transgene in G12 Chinese hamster cells could be silenced by water-insoluble nickel compounds nickel sulfide (NiS) or nickel subsulfide (Ni(3)S(2)) and showed that the transgene was silenced by de novo DNA methylation and chromatin condensation. To further understand the nature of this silencing, we used the chromatin immunoprecipitation assay to elucidate the chromatin structure in nickel-induced silenced G12 clones. We also analyzed the effects of the DNA methyltransferase inhibitor 5-azacytidine (5-AzaC) and a histone deacetylase inhibitor trichostatin A (TSA) on histone H3 and H4 acetylation and gpt gene expression in selected nickel-silenced clones. We observed that both histone H3 and H4 were hypoacetylated and a methyl DNA-binding protein MeCP2 was targeted to the gpt gene locus, resulting in a localized inactive chromatin configuration in nickel-silenced cell clones. The histone H3K9 was also found methylated in three of four nickel- silenced cell clones, whereas the histone H3K9 was deacetylated in all four cell clones, indicating that the H3K9 methylation was involved in nickel-induced gene silencing. The acetylation of the gpt gene could be increased by a combination of 5-AzaC and TSA treatment, but not by either 5-AzaC or TSA alone. The gpt transcript was studied by either Northern blot or by semiquantitative RT-PCR following treatment of the silenced clones with TSA or 5-AzaC. An increase in gpt mRNA could be detected by RT-PCR in the clones that regained acetylation of H3 and H4. These data show that gene silencing induced by nickel in the gpt transgenic cell line involved a loss of histone acetylation and an activation of histone methylation. Both H4 and H3 histone acetylation were lost in the silenced clones and these clones exhibited an increase in the methylation of the lysine 9 in histone H3.

Enrichment for histone H3 lysine 9 methylation at Alu repeats in human cells

The aim of this study was to identify in human cells common targets of histone H3 lysine 9 (H3-Lys9) methylation, a modification that is generally associated with gene silencing. After chromatin immunoprecipitation using an H3-Lys9 methylated antibody, we cloned the recovered DNA and sequenced 47 independent clones. Of these, 38 clones (81%) contained repetitive elements, either short interspersed transposable element (SINE or Alu elements), long terminal repeat (LTR), long interspersed transposable element (LINE), or satellite region (ALR/Alpha) DNA, and three additional clones were near Alu elements. Further characterization of these repetitive elements revealed that 32 clones (68%) were Alu repeats, corresponding to both old Alu (23 clones) and young Alu (9 clones) subfamilies. Association of H3-Lys9 methylation was confirmed by chromatin immunoprecipitation-PCR using conserved Alu primers. In addition, we randomly selected 5 Alu repeats from the recovered clones and confirmed association with H3-Lys9 by PCR using primer sets flanking the Alu elements. Treatment with the DNA methyltransferase inhibitor 5-aza-2'-deoxycytidine rapidly decreased the level of H3-Lys9 methylation in the Alu elements, suggesting that H3-Lys9 methylation may be related to the suppression of Alu elements through DNA methylation. Thus H3-Lys9 methylation is enriched at human repetitive elements, particularly Alu elements, and may play a role in the suppression of recombination by these elements.

The establishment and maintenance of lymphocyte identity through gene silencing

Cell identity is determined by selective gene activation and by the maintenance of other regulated genes in a silent state. Although activation mechanisms have been dissected in considerable depth, great strides towards an understanding of the molecular control of gene silencing have been made only recently. Molecular hallmarks of silent chromatin and proteins involved in its assembly and maintenance have been identified through genetic, cytological and biochemical studies in a variety of organisms. Immunologists are now beginning to use this knowledge to elucidate mechanisms underlying cell fate decisions and key developmental steps. This review surveys the current knowledge of gene silencing, with an emphasis on studies in lymphocytes that are advancing our general understanding of silencing mechanisms during development.

Mechanism of multiple lysine methylation by the SET domain enzyme Rubisco LSMT

SET domain protein methyltransferases catalyze the transfer of methyl groups from the cofactor S-adenosylmethionine (AdoMet) to specific lysine residues of protein substrates, such as the N-terminal tails of histones H3 and H4 and the large subunit of the Rubisco holoenzyme complex. The crystal structures of pea Rubisco large subunit methyltransferase (LSMT) in ternary complexes with either lysine or epsilon-N-methyllysine (MeLys) and the product S-adenosylhomocysteine (AdoHcy) were determined to resolutions of 2.65 and 2.55 A, respectively. The zeta-methyl group of MeLys is bound to the enzyme via carbon-oxygen hydrogen bonds that play a key role in catalysis. The methyl donor and acceptor are aligned in a linear geometry for S(N)2 nucleophilic transfer of the methyl group during catalysis. Differences in hydrogen bonding between the MeLys epsilon-amino group and Rubisco LSMT and SET7/9 explain why Rubisco LSMT generates multiply methylated Lys, wheras SET7/9 generates only MeLys.

Rb-mediated heterochromatin formation and silencing of E2F target genes during cellular senescence

Cellular senescence is an extremely stable form of cell cycle arrest that limits the proliferation of damaged cells and may act as a natural barrier to cancer progression. In this study, we describe a distinct heterochromatic structure that accumulates in senescent human fibroblasts, which we designated senescence-associated heterochromatic foci (SAHF). SAHF formation coincides with the recruitment of heterochromatin proteins and the retinoblastoma (Rb) tumor suppressor to E2F-responsive promoters and is associated with the stable repression of E2F target genes. Notably, both SAHF formation and the silencing of E2F target genes depend on the integrity of the Rb pathway and do not occur in reversibly arrested cells. These results provide a molecular explanation for the stability of the senescent state, as well as new insights into the action of Rb as a tumor suppressor.

Tails of intrigue: phosphorylation of RNA polymerase II mediates histone methylation

Histone lysine methylation plays a key role in the organization of chromatin structure and the regulation of gene expression. Recent studies demonstrated that the yeast Set1 and Set2 histone methyltransferases are recruited to mRNA coding regions by the PAF transcription elongation complex in a manner dependent upon the phosphorylation state of the carboxy-terminal domain of RNA polymerase II. These studies define an unexpected link between transcription elongation and histone methylation.

The histone 3 lysine 36 methyltransferase, SET2, is involved in transcriptional elongation

Existing evidence indicates that SET2, the histone 3 lysine 36 methyltransferase of Saccharomyces cerevisiae, is a transcriptional repressor. Here we show by five main lines of evidence that SET2 is involved in transcriptional elongation. First, most, if not all, subunits of the RNAP II holoenzyme co-purify with SET2. Second, all of the co-purifying RNAP II subunit, RPO21, was phosphorylated at serines 5 and 2 of the C-terminal domain (CTD) tail, indicating that the SET2 association is specific to either the elongating or SSN3 repressed forms (or both) of RNAP II. Third, the association of SET2 with CTD phosphorylated RPO21 remained in the absence of ssn3. Fourth, in the absence of ssn3, mRNA production from gal1 required SET2. Fifth, SET2 was detected on gal1 by in vivo crosslinking after, but not before, the induction of transcription. Similarly, SET2 physically associated with the transcribed region of pdr5 but was not detected on gal1 or pdr5 promoter regions. Since SET2 is also a histone methyltransferase, these results suggest a role for histone 3 lysine 36 methylation in transcriptional elongation.