Transcription regulation by histone methylation: interplay between different covalent modifications of the core histone tails

Targeted recruitment of a histone H4-specific methyltransferase by the transcription factor YY1

Methylation of specific residues within the N-terminal histone tails plays a critical role in regulating eukaryotic gene expression. Although great advances have been made toward identifying histone methyltransferases (HMTs) and elucidating the consequences of histone methylation, little is known about the recruitment of HMTs to regulatory regions of chromatin. Here we report that the sequence-specific DNA-binding transcription factor Yin Yang 1 (YY1) binds to and recruits the histone H4 (Arg 3)-specific methyltransferase, PRMT1, to a YY1-activated promoter. Our data confirm that histone methylation does not occur randomly but rather is a targeted event and provides one mechanism by which HMTs can be recruited to chromatin to activate gene expression.

Association of class I histone deacetylases with transcriptional corepressor CtBP

The C-terminal binding protein (CtBP) family proteins are transcriptional regulators that are conserved from worm to human. They function as corepressors of a wide array of DNA-binding transcriptional repressors. The mammalian CtBPs appear to mediate transcriptional repression in a histone deacetylase (HDAC)-dependent or -independent manner, depending on the context of the promoter. To identify the components of the CtBP corepressor complex, we isolated CtBP-containing protein complexes from the nuclear extracts prepared from HeLa cells infected with adenovirus vectors that expresses hCtBP1. Western blot analysis of these complexes suggests that hCtBP1 associates with class I HDACs, HDAC-1, HDAC-2 and HDAC-3. Some of these HDACs also interact with the Drosophila CtBP homolog, dCtBP. The CtBP protein complex exhibits significant HDAC activity in vitro suggesting that association of CtBP with HDACs may be functionally relevant.

The NuRD complex: linking histone modification to nucleosome remodeling

ATP-dependent nucleosome remodeling and core histone tail modifications play important roles in chromatin function. Purification and characterization of the NuRD/Mi-2 complex, which possesses both nucleosome remodeling and histone deacetylase activities, suggests that ATP-dependent nucleosome remodeling and histone tail modification can be coupled. Recent studies indicate that NuRD is an integral part of the MeCP1 complex, suggesting that nucleosome remodeling and histone deacetylation play important roles in methylated DNA silencing. Studies in Caenorhabditis elegans have revealed important functions of the NuRD complex in embryonic patterning and Ras signaling. Accumulating evidence indicates that NuRD may regulate transcription of specific genes by interacting with specific transcriptional factors. In addition, it may also participate in genome-wide transcriptional regulation through an association with histone tails.

Selective gene regulation by SWI/SNF-related chromatin remodeling factors

Chromatin is a highly dynamic structure that plays a key role in the orchestration of gene expression patterns during cellular differentiation and development. The packaging of DNA into chromatin generates a barrier to the transcription machinery. The two main strategies by which cells alleviate chromatin-mediated repression are through the action of ATP-dependent chromatin remodeling complexes and enzymes that covalently modify the histones. Various signaling pathways impinge upon the targeting and activity of these enzymes, thereby controlling gene expression in response to physiological and developmental cues. Chromatin structure also underlies many so-called epigenetic phenomena, leading to the mitotically stable propagation of differential expression of genetic information. Here, we will focus on the role of SWI/SNF-related ATP-dependent chromatin remodeling complexes in developmental gene regulation. First, we compare different models for how remodelers can act in a gene-selective manner, and either cooperate or antagonize other chromatin-modulating systems in the cell. Next, we discuss their functioning during the control of developmental gene expression programs.

Role of histone H3 lysine 27 methylation in X inactivation

The Polycomb group (PcG) protein Eed is implicated in regulation of imprinted X-chromosome inactivation in extraembryonic cells but not of random X inactivation in embryonic cells. The Drosophila homolog of the Eed-Ezh2 PcG protein complex achieves gene silencing through methylation of histone H3 on lysine 27 (H3-K27), which suggests a role for H3-K27 methylation in imprinted X inactivation. Here we demonstrate that transient recruitment of the Eed-Ezh2 complex to the inactive X chromosome (Xi) occurs during initiation of X inactivation in both extraembryonic and embryonic cells and is accompanied by H3-K27 methylation. Recruitment of the complex and methylation on the Xi depend on Xist RNA but are independent of its silencing function. Together, our results suggest a role for Eed-Ezh2-mediated H3-K27 methylation during initiation of both imprinted and random X inactivation and demonstrate that H3-K27 methylation is not sufficient for silencing of the Xi.

Genetic adaptation controlled by methylations and acetylations at the nuclear and cytosolic levels: a hypothetical model

Metabolic sensors related to the maturation of metabolism seem to control a process of generic adaptation involving the silencing of genes and the expression of their copies more adapted to environmental changes. Nuclear methylases and histone deacetylases control the gene silencing process. Nuclear methylases compete with cytosolic methylases for the same methyl donnors, this will favor the expression of unmethylated more adapted gene copies, when cytosotic methylases take over. Methylated cytosolic compounds may then represent an index of this adaptation. If a more adapted gene copy is mutated, the regulatory ligand of the gene product that does not find its target may induce a reexpression of the silenced gene. The hypothetical model proposed considers that gene silencing and expression of a more adequate copy involves a non-specific gene silencer switch that depends on the histone status; the silencer switch is counteracted by the ligand of the adapted gene copy product acting like an inducer.

Global and specific transcriptional repression by the histone H3 amino terminus in yeast

The yeast CHA1 promoter is activated in the presence of serine or threonine. Activation requires the Cha4p activator, and it results in perturbation of a nucleosome that incorporates the TATA element under noninducing conditions. We show that in yeast lacking the amino terminus of histone H3, the promoter is constitutively active and the chromatin is concomitantly perturbed. This derepression occurs in the absence of elevated intracellular levels of serine or threonine and is not observed in cells lacking Rpd3p, Tup1p, or the amino terminus of histone H4. Furthermore, derepression in the absence of the H3 amino terminus requires the primary activator of this promoter, Cha4p, which we show by chromatin immunoprecipitation to be constitutively bound to the CHA1 promoter in WT yeast. Thus, the H3 amino terminus is required to prevent Cha4p from activating CHA1 in the absence of inducer. We also present results of a microarray experiment showing that the H3 amino terminus has a substantial repressive effect on a genome-wide scale.

The nonessential H2A N-terminal tail can function as an essential charge patch on the H2A.Z variant N-terminal tail

Tetrahymena thermophila cells contain three forms of H2A: major H2A.1 and H2A.2, which make up approximately 80% of total H2A, and a conserved variant, H2A.Z. We showed previously that acetylation of H2A.Z was essential (Q. Ren and M. A. Gorovsky, Mol. Cell 7:1329-1335, 2001). Here we used in vitro mutagenesis of lysine residues, coupled with gene replacement, to identify the sites of acetylation of the N-terminal tail of the major H2A and to analyze its function in vivo. Tetrahymena cells survived with all five acetylatable lysines replaced by arginines plus a mutation that abolished acetylation of the N-terminal serine normally found in the wild-type protein. Thus, neither posttranslational nor cotranslational acetylation of major H2A is essential. Surprisingly, the nonacetylatable N-terminal tail of the major H2A was able to replace the essential function of the acetylation of the H2A.Z N-terminal tail. Tail-swapping experiments between H2A.1 and H2A.Z revealed that the nonessential acetylation of the major H2A N-terminal tail can be made to function as an essential charge patch in place of the H2A.Z N-terminal tail and that while the pattern of acetylation of an H2A N-terminal tail is determined by the tail sequence, the effects of acetylation on viability are determined by properties of the H2A core and not those of the N-terminal tail itself.

Collaborative spirit of histone deacetylases in regulating chromatin structure and gene expression

The flexible N-terminal tails of core histones are subject to dynamic, reversible lysine acetylation. At least 10 histone deacetylases have been identified in Saccharomyces cerevisiae and 19 in humans. Emerging themes regarding the function and regulation of these enzymes include the following: targeted and non-targeted chromatin deacetylation; their collaboration with each other and with other chromatin regulators to promote transcriptional repression and silencing; deacetylation of transcription factors and other non-histone proteins; and regulation by subcellular compartmentalization and subunit association. Histone deacetylases are important targets for drugs with potential therapeutic value in the treatment of cancer, neurodegenerative disorders, cardiac hypertrophy and other human diseases.

Human Sin3 deacetylase and trithorax-related Set1/Ash2 histone H3-K4 methyltransferase are tethered together selectively by the cell-proliferation factor HCF-1

The abundant and chromatin-associated protein HCF-1 is a critical player in mammalian cell proliferation as well as herpes simplex virus (HSV) transcription. We show here that separate regions of HCF-1 critical for its role in cell proliferation associate with the Sin3 histone deacetylase (HDAC) and a previously uncharacterized human trithorax-related Set1/Ash2 histone methyltransferase (HMT). The Set1/Ash2 HMT methylates histone H3 at Lys 4 (K4), but not if the neighboring K9 residue is already methylated. HCF-1 tethers the Sin3 and Set1/Ash2 transcriptional regulatory complexes together even though they are generally associated with opposite transcriptional outcomes: repression and activation of transcription, respectively. Nevertheless, this tethering is context-dependent because the transcriptional activator VP16 selectively binds HCF-1 associated with the Set1/Ash2 HMT complex in the absence of the Sin3 HDAC complex. These results suggest that HCF-1 can broadly regulate transcription, both positively and negatively, through selective modulation of chromatin structure.

Histone and chromatin cross-talk

Chromatin is the physiologically relevant substrate for all genetic processes inside the nuclei of eukaryotic cells. Dynamic changes in the local and global organization of chromatin are emerging as key regulators of genomic function. Indeed, a multitude of signals from outside and inside the cell converges on this gigantic signaling platform. Numerous post-translational modifications of histones, the main protein components of chromatin, have been documented and analyzed in detail. These 'marks' appear to crucially mediate the functional activity of the genome in response to upstream signaling pathways. Different layers of cross-talk between several components of this complex regulatory system are emerging, and these epigenetic circuits are the focus of this review.

Methylation of SPT5 regulates its interaction with RNA polymerase II and transcriptional elongation properties

SPT5 and its binding partner SPT4 function in both positively and negatively regulating transcriptional elongation. The demonstration that SPT5 and RNA polymerase II are targets for phosphorylation by CDK9/cyclin T1 indicates that posttranslational modifications of these factors are important in regulating the elongation process. In this study, we utilized a biochemical approach to demonstrate that SPT5 was specifically associated with the protein arginine methyltransferases PRMT1 and PRMT5 and that SPT5 methylation regulated its interaction with RNA polymerase II. Specific arginine residues in SPT5 that are methylated by these enzymes were identified and demonstrated to be important in regulating its promoter association and subsequent effects on transcriptional elongation. These results suggest that methylation of SPT5 is an important posttranslational modification that is involved in regulating its transcriptional elongation properties in response to viral and cellular factors.

The Set2 histone methyltransferase functions through the phosphorylated carboxyl-terminal domain of RNA polymerase II

The histone methyltransferase Set2, which specifically methylates lysine 36 of histone H3, has been shown to repress transcription upon tethering to a heterologous promoter. However, the mechanism of targeting and the consequence of Set2-dependent methylation have yet to be demonstrated. We sought to identify the protein components associated with Set2 to gain some insights into the in vivo function of this protein. Mass spectrometry analysis of the Set2 complex, purified using a tandem affinity method, revealed that RNA polymerase II (pol II) is associated with Set2. Immunoblotting and immunoprecipitation using antibodies against subunits of pol II confirmed that the phosphorylated form of pol II is indeed an integral part of the Set2 complex. Gst-Set2 preferentially binds to CTD synthetic peptides phosphorylated at serine 2, and to a lesser extent, serine 5 phosphorylated peptides, but has no affinity for unphosphorylated CTD, suggesting that Set2 associates with the elongating form of the pol II. Furthermore, we show that set2Delta ppr2Delta double mutants (PPR2 encodes TFIIS, a transcription elongation factor) are synthetically hypersensitive to 6-azauracil, and that deletions in the CTD reduce in vivo levels of H3 lysine 36 methylation. Collectively, these results suggest that Set2 is involved in regulating transcription elongation through its direct contact with pol II.

High conservation of the Set1/Rad6 axis of histone 3 lysine 4 methylation in budding and fission yeasts

Histone 3 lysine 4 (H3 Lys(4)) methylation in Saccharomyces cerevisiae is mediated by the Set1 complex (Set1C) and is dependent upon ubiquitinylation of H2B by Rad6. Mutually exclusive methylation of H3 at Lys(4) or Lys(9) is central to chromatin regulation; however, S. cerevisiae lacks Lys(9) methylation. Furthermore, a different H3 Lys(4) methylase, Set 7/9, has been identified in mammals, thereby questioning the relevance of the S. cerevisiae findings for eukaryotes in general. We report that the majority of Lys(4) methylation in Schizosaccharomyces pombe, like in S. cerevisiae, is mediated by Set1C and is Rad6-dependent. S. pombe Set1C mediates H3 Lys(4) methylation in vitro and contains the same eight subunits found in S. cerevisiae, including the homologue of the Drosophila trithorax Group protein, Ash2. Three additional features of S. pombe Set1C each involve PHD fingers. Notably, the Spp1 subunit is dispensable for H3 Lys(4) methylation in budding yeast but required in fission yeast, and Sp_Set1C has a novel proteomic hyperlink to a new complex that includes the homologue of another trithorax Group protein, Lid (little imaginal discs). Thus, we infer that Set1C is highly conserved in eukaryotes but observe that its links to the proteome are not.

Structure of the catalytic domain of human DOT1L, a non-SET domain nucleosomal histone methyltransferase

Dot1 is an evolutionarily conserved histone methyltransferase that methylates lysine-79 of histone H3 in the core domain. Unlike other histone methyltransferases, Dot1 does not contain a SET domain, and it specifically methylates nucleosomal histone H3. We have solved a 2.5 A resolution structure of the catalytic domain of human Dot1, hDOT1L, in complex with S-adenosyl-L-methionine (SAM). The structure reveals a unique organization of a mainly alpha-helical N-terminal domain and a central open alpha/beta structure, an active site consisting of a SAM binding pocket, and a potential lysine binding channel. We also show that a flexible, positively charged region at the C terminus of the catalytic domain is critical for nucleosome binding and enzymatic activity. These structural and biochemical analyses, combined with molecular modeling, provide mechanistic insights into the catalytic mechanism and nucleosomal specificity of Dot1 proteins.

Balance between acetylation and methylation of histone H3 lysine 9 on the E2F-responsive dihydrofolate reductase promoter

Epigenetic marks that specify silent heterochromatic domains in eucaryotic genomes include methylation of histone H3 lysine 9. Strikingly, active loci in the vicinity of silent domains are sometimes characterized by acetylation of histone H3 lysine 9, suggesting that the balance between these two competitive modifications is important for the establishment of specific chromatin structures. Some euchromatic genes, targeted by the retinoblastoma protein Rb, are also believed to be regulated by histone H3 lysine 9 methylation. Here, we study the dihydrofolate reductase promoter, which is repressed in G0 and at the beginning of G1 by p107 or p130, two Rb-related proteins. We found that these two pocket proteins share with Rb the ability to associate with the histone methyl transferase SUV39H1. SUV39H1 can be recruited to the E2F transcription factor and functions as a transcriptional corepressor. With ChIP assays followed by real-time PCR, we showed that K9 of histone H3 evolves from a hypermethylated state in G0 to a hyperacetylated state at the G1/S transition. Taken together, these results indicate that the temporal regulation of euchromatic promoters may involve controlling the balance between methylation and acetylation of histone H3 lysine 9, a feature previously described for the spatial regulation of chromatin function.

Phosphorylation of RNA polymerase II CTD regulates H3 methylation in yeast

Histone methylation is now realized to be a pivotal regulator of gene transcription. Although recent studies have shed light on a trans-histone regulatory pathway that controls H3 Lys 4 and H3 Lys 79 methylation in Saccharomyces cerevisiae, the regulatory pathway that affects Set2-mediated H3 Lys 36 methylation is unknown. To determine the functions of Set2, and identify factors that regulate its site of methylation, we genomically tagged Set2 and identified its associated proteins. Here, we show that Set2 is associated with Rbp1 and Rbp2, the two largest subunits of RNA polymerase II (RNA pol II). Moreover, we find that this association is specific for the interaction of Set2 with the hyperphosphorylated form of RNA pol II. We further show that deletion of the RNA pol II C-terminal domain (CTD) kinase Ctk1, or partial deletion of the CTD, results in a selective abolishment of H3 Lys 36 methylation, implying a pathway of Set2 recruitment to chromatin and a role for H3 Lys 36 methylation in transcription elongation. In support, chromatin immunoprecipitation assays demonstrate the presence of Set2 methylation in the coding regions, as well as promoters, of genes regulated by Ctk1 or Set2. These data document a new link between histone methylation and the transcription apparatus and uncover a regulatory pathway that is selective for H3 Lys 36 methylation.

The fission yeast spSet1p is a histone H3-K4 methyltransferase that functions in telomere maintenance and DNA repair in an ATM kinase Rad3-dependent pathway

We have characterized spSet1p, the Schizosaccharomyces pombe ortholog of the budding yeast histone H3 methyltransferase Set1p. SpSet1p catalyzes methylation of H3 at K4, in vivo and in vitro. Deleting spset1 partially affects telomeric and centromeric silencing. Strikingly, lack of spSet1p causes elongation of telomeres in wild-type cells and in most DNA damage checkpoint rad mutant cells, but not in cells lacking the ATM kinase Rad3 or its associated protein Rad26. Interestingly, spset1 deletion specifically causes a reduction in sensitivity to ultraviolet radiation of the PCNA-like checkpoint mutants hus1 and rad1, but not of cells devoid of Rad3. This partial suppression was not due to restoration of checkpoint function or to transcriptional induction of DNA repair genes. Moreover, spset1 allows recovery specifically of the crb2 checkpoint mutant upon treatment with the replication inhibitor hydroxyurea but not upon UV irradiation. Nevertheless, the pathway induced in spset1 cells cannot substitute for the Mus81/Rqh1 DNA damage tolerance pathway. Our results suggest that SpSet1p and the ATM kinase Rad3 function in a common genetic pathway linking chromatin to telomere length regulation and DNA repair.

Memory by modification: the influence of chromatin structure on gene expression during vertebrate development

Multicellular development is programmed by regulated interactions between transcription factors and target genes. Target genes function as nucleosomal arrays whose higher order structure, composition and accessibility to transcription machinery are strictly and dynamically controlled. Several classes of chromatin-associated proteins generate or remove localized, covalent chromatin modifications that signify gene expression status, whereas others modulate nucleosome organization and so regulate template availability for transcription. In vertebrates, covalent modification of the DNA template itself also has dramatic impacts on gene expression and development. Here I review recent discoveries that improve our understanding of the influence of chromatin structure on gene expression and I discuss their relevance to mechanisms of vertebrate development.

Hypoxia actively represses transcription by inducing negative cofactor 2 (Dr1/DrAP1) and blocking preinitiation complex assembly

Hypoxia is a growth inhibitory stress associated with multiple disease states. We find that hypoxic stress actively regulates transcription not only by activation of specific genes but also by selective repression. We reconstituted this bimodal response to hypoxia in vitro and determined a mechanism for hypoxia-mediated repression of transcription. Hypoxic cell extracts are competent for transcript elongation, but cannot assemble a functional preinitiation complex (PIC) at a subset of promoters. PIC assembly and RNA polymerase II C-terminal domain (CTD) phosphorylation were blocked by hypoxic induction and core promoter binding of negative cofactor 2 protein (NC2 alpha/beta, Dr1/DrAP1). Immunodepletion of NC2 beta/Dr1 protein complexes rescued hypoxic-repressed transcription without alteration of normoxic transcription. Physiological regulation of NC2 activity may represent an active means of conserving energy in response to hypoxic stress.

Histone deacetylation by Sir2 generates a transcriptionally repressed nucleoprotein complex

Sir2 is an NAD-dependent histone deacetylase required for transcriptional silencing. To study the mechanism of Sir2 function, we examined the biochemical properties of purified recombinant Drosophila Sir2 (dSir2). First, we performed histone deacetylation assays and found that dSir2 deacetylates a broad range of acetylated lysine residues. We then carried out in vitro transcription experiments and observed that dSir2 does not repress transcription with either naked DNA templates or chromatin assembled from native (and mostly unacetylated) histones. It was possible, however, that repression by dSir2 requires an acetylated histone substrate. We therefore tested the transcriptional effects of dSir2 with native histones that were hyperacetylated by treatment with acetic anhydride. Assembly of the hyperacetylated histones onto DNA yields a soluble histone-DNA complex that differs from canonical nucleosomal chromatin. With this hyperacetylated histone-DNA complex, we observed potent (50- to 100-fold) NAD-dependent transcriptional repression by purified dSir2. In contrast, repression by dSir2 was not observed in parallel experiments in which histones were hyperpropionylated with propionic anhydride. We also found that dSir2 mediates the formation of a nuclease-resistant fast-sedimenting histone-DNA complex in an NAD-dependent manner. Unlike dSir2, the dHDAC1 deacetylase does not strongly repress transcription or generate a nuclease-resistant histone-DNA complex. Furthermore, with yeast Sir2, the transcriptional repression we observe correlates with deacetylation activity in vitro and silencing activity in vivo. These findings suggest that deacetylation by Sir2 causes a conformational change or rearrangement of histones into a transcriptionally repressive chromatin structure.

Histone modifications in Arabidopsis- high methylation of H3 lysine 9 is dispensable for constitutive heterochromatin

N-terminal modifications of nucleosomal core histones are involved in gene regulation, DNA repair and recombination as well as in chromatin modeling. The degree of individual histone modifications may vary between specific chromatin domains and throughout the cell cycle. We have studied the nuclear patterns of histone H3 and H4 acetylation and of H3 methylation in Arabidopsis. A replication-linked increase of acetylation only occurred at H4 lysine 16 (not for lysines 5 and 12) and at H3 lysine 18. The last was not observed in other plants. Strong methylation at H3 lysine 4 was restricted to euchromatin, while strong methylation at H3 lysine 9 occurred preferentially in heterochromatic chromocenters of Arabidopsis nuclei. Chromocenter appearance, DNA methylation and histone modification patterns were similar in nuclei of wild-type and kryptonite mutant (which lacks H3 lysine 9-specific histone methyltransferase), except that methylation at H3 lysine 9 in heterochromatic chromocenters was reduced to the same low level as in euchromatin. Thus, a high level of H3methylK9 is apparently not necessary to maintain chromocenter structure and does not prevent methylation of H3 lysine 4 within Arabidopsis chromocenters.

Controlling the double helix

Chromatin is the complex of DNA and proteins in which the genetic material is packaged inside the cells of organisms with nuclei. Chromatin structure is dynamic and exerts profound control over gene expression and other fundamental cellular processes. Changes in its structure can be inherited by the next generation, independent of the DNA sequence itself.

Direct association of p300 with unmodified H3 and H4 N termini modulates p300-dependent acetylation and transcription of nucleosomal templates

The nature of histone acetylation events in active chromatin is an important issue in transcriptional regulation. We have systematically analyzed the ability of p300, either alone or in response to an interacting activator, to acetylate specific recombinant histones in the context of free histones, histone octamers, or nucleosomal arrays. Our results indicate that p300 has an intrinsic ability to acetylate all core histones but that the level and specificity of histone acetylation is indeed context-dependent. Thus, H3 and H4 are preferentially acetylated in free octamers, whereas all histones are nearly equally acetylated, in an activator-dependent manner, in chromatin. Moreover, H3 and H4 show H2A and H2B tail-independent acetylation in chromatin, whereas maximal H2A and H2B acetylation in this context is dependent upon H3 and H4 tails (but not their acetylation). In further support of an apparent intrinsic preference of p300 for the H3 and H4 tails, as well as an important role for direct interactions of p300 with unacetylated H3 and H4 tails in both acetylation and transcription, we have shown that p300 selectively acetylates isolated H3 and H4 tails, that p300 strongly and selectively binds to free unacetylated H3 and H4 tails, and that p300-mediated acetylation of nucleosomal histones and transcriptional activation are selectively inhibited by isolated (unacetylated) H3 and H4 tails.

Mechanism of histone lysine methyl transfer revealed by the structure of SET7/9-AdoMet

The methylation of lysine residues of histones plays a pivotal role in the regulation of chromatin structure and gene expression. Here, we report two crystal structures of SET7/9, a histone methyltransferase (HMTase) that transfers methyl groups to Lys4 of histone H3, in complex with S-adenosyl-L-methionine (AdoMet) determined at 1.7 and 2.3 A resolution. The structures reveal an active site consisting of: (i) a binding pocket between the SET domain and a c-SET helix where an AdoMet molecule in an unusual conformation binds; (ii) a narrow substrate-specific channel that only unmethylated lysine residues can access; and (iii) a catalytic tyrosine residue. The methyl group of AdoMet is directed to the narrow channel where a substrate lysine enters from the opposite side. We demonstrate that SET7/9 can transfer two but not three methyl groups to unmodified Lys4 of H3 without substrate dissociation. The unusual features of the SET domain-containing HMTase discriminate between the un- and methylated lysine substrate, and the methylation sites for the histone H3 tail.

Myelodysplastic syndrome

The last decade has witnessed a multistep evolution in the understanding of the natural history, clinical manifestations, and some of the molecular mechanisms that underlie the ineffective hematopoiesis and leukemic transformation in the myelodysplastic syndrome (MDS). The international prognostic scoring system, FAB, and WHO classifications have helped define specific subgroups with their characteristic cytogenetic, molecular and immunological abnormalities. Until recently the mainstay of the treatment has been entirely supportive with blood and platelet transfusions. What is increasingly manifest now is the considerable excitement generated by the emergence of novel therapeutic strategies based on painstaking research findings from the laboratories. In Section I, Dr. Alan List reviews the therapeutic strategies with the specific emphasis on the relevance of molecular mechanism of apoptosis and targeted therapies using small molecules. Of particular interest is the excitement surrounding the clinical benefit obtained from potent immunomodulatory derivative (IMiD) of thalidomide CC5013. The review provides an update of the role of small molecule inhibitors of VEGF receptor tyrosine kinase, arsenic trioxide, oral matrix metalloprotease inhibitors, farnesyl transferase inhibitors, and imatinib mesylate in the treatment of MDS subgroups. In Section II, Dr. Steven Gore describes the results of clinical trials of inhibitors of DNA methylation such as 5 azacytidine (5 AC) and 5-aza 2-deoxycytidine (Decitabine). The review also provides an update on the rationale and results obtained from the combination therapy using histone deacetylases (HDAC) and DNA methyltransferase inhibitors in the treatment of MDS. In Section III, Professor Ghulam Mufti and Dr. Aloysius Ho describe the role of bone marrow transplantation with particular emphasis on recent results from reduced-intensity conditioned transplants, exploiting the graft versus leukemia effect without significant early treatment-related mortality. The section provides an update on the results obtained from the manipulation of the host's immune system with immunosuppressive agents such as ALG and/or cyclosporine A.

Crosstalk between CARM1 methylation and CBP acetylation on histone H3

BACKGROUND

Dynamic changes in the modification pattern of histones, such as acetylation, phosphorylation, methylation, and ubiquitination, are thought to provide a code for the correct regulation of gene expression mostly by affecting chromatin structure and interactions of non-histone regulatory factors with chromatin. Recent studies have suggested the existence of an interplay between histone modifications during transcription. The CBP/p300 acetylase and the CARM1 methyltransferase can positively regulate the expression of estrogen-responsive genes, but the existence of a crosstalk between lysine acetylation and arginine methylation on chromatin has not yet been established in vivo.

RESULTS

By following the in vivo pattern of modifications on histone H3, following estrogen stimulation of the pS2 promoter, we show that arginine methylation follows prior acetylation of H3. Within 15 min after estrogen stimulation, CBP is bound to chromatin, and acetylation of K18 takes place. Following these events, K23 is acetylated, CARM1 associates with chromatin, and methylation at R17 takes place. Exogenous expression of CBP is sufficient to drive the association of CARM1 with chromatin and methylation of R17 in vivo, whereas an acetylase-deficient CBP mutant is unable to induce these events. A mechanism for the observed cooperation between acetylation and arginine methylation comes from the finding that acetylation at K18 and K23, but not K14, tethers recombinant CARM1 to the H3 tail and allows it to act as a more efficient arginine methyltransferase.

CONCLUSION

These results reveal an ordered and interdependent deposition of acetylation and arginine methylation during estrogen-regulated transcription and provide support for a combinatorial role of histone modifications in gene expression.

Gene-specific targeting of H3K9 methylation is sufficient for initiating repression in vivo

Covalent modifications of chromatin have emerged as key determinants of the genome's transcriptional competence. Histone H3 lysine 9 (H3K9) methylation is an epigenetic signal that is recognized by HP1 and correlates with gene silencing in a variety of organisms. Discovery of the enzymes that catalyze H3K9 methylation has identified a second gene-specific function for this modification in transcriptional repression. Whether H3K9 methylation is causative in the initiation and establishment of gene repression or is a byproduct of the process leading to the repressed state remains unknown. To investigate the role of HMTs and specifically H3K9 methylation in gene repression, we have employed engineered zinc-finger transcription factors (ZFPs) to target HMT activity to a specific endogenous gene. By utilizing ZFPs that recognize the promoter of the endogenous VEGF-A gene, and thus employing this chromosomal locus as an in vivo reporter, we show that ZFPs linked to a minimal catalytic HMT domain affect local methylation of histone H3K9 and the consequent repression of target gene expression. Furthermore, amino acid substitutions within the HMT that ablate its catalytic activity effectively eliminate the ability of the ZFP fusions to repress transcription. Thus, H3K9 methylation is a primary signal that is sufficient for initiating a gene repression pathway in vivo.

Association of the histone methyltransferase Set2 with RNA polymerase II plays a role in transcription elongation

The Saccharomyces cerevisiae protein, Set2, has recently been shown to be a histone methyltransferase. To elucidate the function of Set2, its associated proteins were identified using tandem affinity purification and mass spectrometry. We found that Set2 associates with RNA polymerase II. The interaction between the Set2 protein and RNA polymerase II requires the WW domain in Set2 and phosphorylation of the carboxyl-terminal domain of the largest subunit of RNA polymerase II. Set2 directly binds to the carboxyl-terminal domain with phosphorylated Ser(2) in the heptapeptide repeats. set2 deletion mutant is sensitive to 6-azauracil, a property often associated with impaired transcription elongation. Together, our results suggest that Set2 through association with the elongating form of RNA polymerase II plays an important role in transcription elongation.

Gene silencing in phenomena related to DNA repair

DNA methylation is essential for embryonic development and important for transcriptional repression, as observed in several biological phenomena. These include genomic imprinting, X-inactivation and carcinogenesis. The basic mechanism by which DNA methylation silences transcription is generally understood, but there is still much to be learned about how DNA methyltransferase is targeted to a specific region of the gene. Silencing by DNA methylation occurs at an early stage of carcinogenesis, when the DNA repair genes, MGMT and hMLH1, are frequently inactivated, resulting in mutations in key cancer-related genes in cells. Mice defective in Mgmt and/or Mlh1 gave clear evidence of the significant roles of these proteins in carcinogenesis. Recently, it has been demonstrated that DNA methylation is linked to histone methylation in fungi and plants, although it remains unknown whether this mechanism occurs in mammalian systems.

Signaling network model of chromatin

We suggest that common principles underlie both cellular signaling networks and chromatin. To exemplify similarities, we focus on signaling complexes that form at membrane receptors and on nucleosomes. Multiple signal-transducing modifications on side chain residues of receptor tyrosine kinases (RTKs) and histone proteins are used to create docking sites that facilitate proximal relations of enzymes and their substrates. We argue that multiple histone modifications, like RTK modifications, promote switch-like behavior and ensure robustness of the signal, and we compare this interpretation with the histone code hypothesis. This view provides insight into chromatin function and epigenetic inheritance.

Heritable chromatin structure: mapping "memory" in histones H3 and H4

Telomeric position effect in Saccharomyces cerevisiae is a chromatin-mediated phenomenon in which telomere proximal genes are repressed (silenced) in a heritable, but reversible, fashion. Once a transcriptional state (active or silenced) is established, however, there is a strong tendency for that state to be propagated. Twenty-five years ago, H. Weintraub and colleagues suggested that such heritability could be mediated by posttranslational modification of chromatin [Weintraub, H., Flint, S. J., Leffak, I. M., Groudine, M. & Grainger, R. M. (1977) Cold Spring Harbor Symp. Quant. Biol. 42, 401-407]. To identify potential sites within the chromatin that might act as sources of "memory" for the heritable transmission, we performed a genetic screen to isolate mutant alleles of the histones H3 and H4 genes that would "lock" telomeric marker genes into a silenced state. We identified mutations in the NH(2)-terminal tail and core of both histones; most of the amino acid changes mapped adjacent to lysines that are known sites of acetylation or methylation. We developed a method using MS to quantify the level of acetylation at each lysine within the histone H4 NH(2)-terminal tail in these mutants. We discovered that each of these mutants had a dramatic reduction in the level of acetylation at lysine 12 within the histone H4 tail. We propose that this lysine serves as a "memory mark" for propagating the expression state of a telomeric gene: when it is unacetylated, silent chromatin will be inherited; when it is acetylated an active state will be inherited.

Histone H3 lysine 4 methylation is mediated by Set1 and promotes maintenance of active chromatin states in fission yeast

Methylation of histone H3 at lysine 4 (H3 Lys-4) or lysine 9 (H3 Lys-9) is known to define active and silent chromosomal domains respectively from fission yeast to humans. However, in budding yeast, H3 Lys-4 methylation is also necessary for silent chromatin assembly at telomeres and ribosomal DNA. Here we demonstrate that deletion of set1, which encodes a protein containing an RNA recognition motif at its amino terminus and a SET domain at the carboxy terminus, abolishes H3 Lys-4 methylation in fission yeast. Unlike in budding yeast, Set1-mediated H3 Lys-4 methylation is not required for heterochromatin assembly at the silent mating-type region and centromeres in fission yeast. Our analysis suggests that H3 Lys-4 methylation is a stable histone modification present throughout the cell cycle, including mitosis. The loss of H3 Lys-4 methylation in set1Delta cells is correlated with a decrease in histone H3 acetylation levels, suggesting a mechanistic link between H3 Lys-4 methylation and acetylation of the H3 tail. We suggest that methylation of H3 Lys-4 primarily acts in the maintenance of transcriptionally poised euchromatic domains, and that this modification is dispensable for heterochromatin formation in fission yeast, which instead utilizes H3 Lys-9 methylation.

Two ubiquitin-conjugating enzymes, Rhp6 and UbcX, regulate heterochromatin silencing in Schizosaccharomyces pombe

Methylation of histone H3 has been linked to the assembly of higher-order chromatin structures. Very recently, several examples, including the Schizosaccharomyces pombe mating-type region, chicken beta-globin locus, and inactive X-chromosome, revealed that H3-Lys9-methyl (Me) is associated with silent chromatin while H3-Lys4-Me is prominent in active chromatin. Surprisingly, it was shown that homologs of Drosophila Su(var)3-9 specifically methylate the Lys9 residue of histone H3. Here, to identify putative enzymes responsible for destabilization of heterochromatin, we screened genes whose overexpressions disrupt silencing at the silent mat3 locus in fission yeast. Interestingly, we identified two genes, rhp6(+) and ubcX(+) (ubiquitin-conjugating enzyme participating in silencing), both of which encode ubiquitin-conjugating enzymes. Their overexpression disrupted silencing at centromeres and telomeres as well as at mat3. Additionally, the overexpression interfered with centromeric function, as confirmed by elevated minichromosome loss and antimicrotubule drug sensitivity. On the contrary, deletion of rhp6(+) or ubcX(+) enhanced silencing at all heterochromatic regions tested, indicating that they are negative regulators of silencing. More importantly, chromatin immunoprecipitation showed that their overexpression alleviated the level of H3-Lys9-Me while enhancing the level of H3-Lys4-Me at the silent regions. On the contrary, their deletions enhanced the level of H3-Lys9-Me while alleviating that of H3-Lys4-Me. Taken together, the data suggest that two ubiquitin-conjugating enzymes, Rhp6 and UbcX, affect methylation of histone H3 at silent chromatin, which then reconfigures silencing.

Characterizing the physical genome

The genome of an organism is a dynamic physical entity, comprising genomic DNA bound to many different proteins and organized into chromosomes. A thorough characterization of the physical genome is relevant to our understanding of processes such as the regulation of gene expression, DNA replication and repair, recombination, chromosome segregation, epigenetic inheritance and genomic instability. Methods based on microarrays are beginning to provide a detailed picture of this physical genome, and they complement the genome-wide studies of mRNA expression profiling that have previously been so successful.

Inhibitors of histone deacetylase and DNA methyltransferase synergistically activate the methylated metallothionein I promoter by activating the transcription factor MTF-1 and forming an open chromatin structure

Inhibitors of DNA methyltransferase (Dnmt) and histone deacetylases (HDAC) synergistically activate the methylated metallothionein I gene (MT-I) promoter in mouse lymphosarcoma cells. The cooperative effect of these two classes of inhibitors on MT-I promoter activity was robust following demethylation of only a few CpG dinucleotides by brief exposure to 5-azacytidine (5-AzaC) but persisted even after prolonged treatment with the nucleoside analog. HDAC inhibitors (trichostatin A [TSA] and depsipeptide) either alone or in combination with 5-AzaC did not facilitate demethylation of the MT-I promoter. Treatment of cells with HDAC inhibitors increased accumulation of multiply acetylated forms of H3 and H4 histones that remained unaffected after treatment with 5-AzaC. Chromatin immunoprecipitation (ChIP) assay showed increased association of acetylated histone H4 and lysine 9 (K9)-acetyl H3 with the MT-I promoter after treatment with TSA, which was not affected following treatment with 5-AzaC. In contrast, the association of K9-methyl histone H3 with the MT-I promoter decreased significantly after treatment with 5-AzaC and TSA. ChIP assay with antibodies specific for methyl-CpG binding proteins (MBDs) demonstrated that only methyl-CpG binding protein 2 (MeCP2) was associated with the MT-I promoter, which was significantly enhanced after TSA treatment. Association of histone deacetylase 1 (HDAC1) with the promoter decreased after treatment with TSA or 5-AzaC and was abolished after treatment with both inhibitors. Among the DNA methyltransferases, both Dnmt1 and Dnmt3a were associated with the MT-I promoter in the lymphosarcoma cells, and association of Dnmt1 decreased with time after treatment with 5-AzaC. Treatment of these cells with HDAC inhibitors also increased expression of the MTF-1 (metal transcription factor-1) gene as well as its DNA binding activity. In vivo genomic footprinting studies demonstrated increased occupancy of MTF-1 to metal response elements of the MT-I promoter after treatment with both inhibitors. Analysis of the promoter by mapping with restriction enzymes in vivo showed that the MT-I promoter attained a more open chromatin structure after combined treatment with 5-AzaC and TSA as opposed to treatment with either agent alone. These results implicate involvement of multifarious factors including modified histones, MBDs, and Dnmts in silencing the methylated MT-I promoter in lymphosarcoma cells. The synergistic activation of this promoter by these two types of inhibitors is due to demethylation of the promoter and altered association of different factors that leads to reorganization of the chromatin and the resultant increase in accessibility of the promoter to the activated transcription factor MTF-1.

Cellular identity and lineage choice

In multicellular organisms, cells usually respond to signals that they encounter in a manner that depends on their particular lineage 'identity'. In other words, cells that have identical genomes can respond in markedly different ways to the same stimulus, with the outcome being determined largely by the previous developmental history of the cell. This general observation implies that individual somatic cells retain a 'working memory' of their ancestry and that this epigenetic information can be passed through successive rounds of DNA replication and cell division. Here, I discuss whether recent advances in our knowledge of chromatin biology and gene silencing can provide new insights into how cell fate is chosen and maintained during development.

hSWI/SNF-catalyzed nucleosome sliding does not occur solely via a twist-diffusion mechanism

Nucleosome remodeling by the hSWI/SNF complex and other chromatin remodeling complexes can cause translocation (sliding) of the histone octamer in cis along DNA. Structural and biochemical evidence suggest that sliding involves a DNA twist-diffusion process whereby the DNA rotates about the helical axis without major displacement from the surface of the nucleosome and that this process may be driven by torsional stress within the DNA. We report that hSWI/SNF efficiently catalyzes sliding of nucleosomes containing branched DNAs as steric blocks to twist-diffusion and a nick to allow dissipation of torsional stress within the nucleosome. These results suggest that SWI/SNF-catalyzed nucleosome sliding does not occur exclusively via a simple twist-diffusion mechanism and support models in which the DNA maintains its rotational orientation to and is at least partially separated from the histone surface during nucleosome translocation.

Cellular memory and the histone code

The histone tails on the nucleosome surface are subject to enzyme-catalyzed modifications that may, singly or in combination, form a code specifying patterns of gene expression. Recent papers provide insights into how a combinatorial code might be set and read. They show how modification of one residue can influence that of another, even when they are located on different histones, and how modifications at specific genomic locations might be perpetuated on newly assembled chromatin.

MLL targets SET domain methyltransferase activity to Hox gene promoters

MLL, the human homolog of Drosophila trithorax, maintains Hox gene expression in mammalian embryos and is rearranged in human leukemias resulting in Hox gene deregulation. How MLL or MLL fusion proteins regulate gene expression remains obscure. We show that MLL regulates target Hox gene expression through direct binding to promoter sequences. We further show that the MLL SET domain is a histone H3 lysine 4-specific methyltransferase whose activity is stimulated with acetylated H3 peptides. This methylase activity is associated with Hox gene activation and H3 (Lys4) methylation at cis-regulatory sequences in vivo. A leukemogenic MLL fusion protein that activates Hox expression had no effect on histone methylation, suggesting a distinct mechanism for gene regulation by MLL and MLL fusion proteins.

Role of histone H3 lysine 27 methylation in Polycomb-group silencing

Polycomb group (PcG) proteins play important roles in maintaining the silent state of HOX genes. Recent studies have implicated histone methylation in long-term gene silencing. However, a connection between PcG-mediated gene silencing and histone methylation has not been established. Here we report the purification and characterization of an EED-EZH2 complex, the human counterpart of the Drosophila ESC-E(Z) complex. We demonstrate that the complex specifically methylates nucleosomal histone H3 at lysine 27 (H3-K27). Using chromatin immunoprecipitation assays, we show that H3-K27 methylation colocalizes with, and is dependent on, E(Z) binding at an Ultrabithorax (Ubx) Polycomb response element (PRE), and that this methylation correlates with Ubx repression. Methylation on H3-K27 facilitates binding of Polycomb (PC), a component of the PRC1 complex, to histone H3 amino-terminal tail. Thus, these studies establish a link between histone methylation and PcG-mediated gene silencing.

The nucleolar remodeling complex NoRC mediates heterochromatin formation and silencing of ribosomal gene transcription

Epigenetic control mechanisms silence about half of the ribosomal RNA (rRNA) genes in metabolically active cells. In exploring the mechanism by which the active or silent state of rRNA genes is inherited, we found that NoRC, a nucleolar remodeling complex containing Snf2h (also called Smarca5, SWI/SNF-related matrix-associated actin-dependent regulator of chromatin, subfamily a, member 5), represses rDNA transcription. NoRC mediates rDNA silencing by recruiting DNA methyltransferase and histone deacetylase activity to the rDNA promoter, thus establishing structural characteristics of heterochromatin such as DNA methylation, histone hypoacetylation and methylation of the Lys9 residue of histone H3. These results indicate that active and inactive rRNA genes can be demarcated by their associated proteins, and link chromatin remodeling to DNA methylation and specific histone modifications.

High-resolution mapping of changes in histone-DNA contacts of nucleosomes remodeled by ISW2

The imitation switch (ISWI) complex from yeast containing the Isw2 and Itc1 proteins was shown to preferentially slide mononucleosomes with as little as 23 bp of linker DNA from the end to the center of DNA. The contacts of unique residues in the histone fold regions of H4, H2B, and H2A with DNA were determined with base pair resolution before and after chromatin remodeling by a site-specific photochemical cross-linking approach. The path of DNA and the conformation of the histone octamer in the nucleosome remodeled or slid by ISW2 were not altered, because after adjustment for the new translational position, the DNA contacts at specific sites in the histone octamer had not been changed. Maintenance of the canonical nucleosome structure after sliding was also demonstrated by DNA photoaffinity labeling of histone proteins at specific sites within the DNA template. In addition, nucleosomal DNA does not become more accessible during ISW2 remodeling, as assayed by restriction endonuclease cutting. ISW2 was also shown to have the novel capability of counteracting transcriptional activators by sliding nucleosomes through Gal4-VP16 bound initially to linker DNA and displacing the activator from DNA.