Histones comprise the major protein component of chromatin, the scaffold in which the eukaryotic genome is packaged, and are subject to many types of post-translational modifications (PTMs), especially on their flexible tails. These modifications may constitute a 'histone code' and could be used to manage epigenetic information that helps extend the genetic message beyond DNA sequences. This proposed code, read in part by histone PTM-binding 'effector' modules and their associated complexes, is predicted to define unique functional states of chromatin and/or regulate various chromatin-templated processes. A wealth of structural and functional data show how chromatin effector modules target their cognate covalent histone modifications. Here we summarize key features in molecular recognition of histone PTMs by a diverse family of 'reader pockets', highlighting specific readout mechanisms for individual marks, common themes and insights into the downstream functional consequences of the interactions. Changes in these interactions may have far-reaching implications for human biology and disease, notably cancer.The vast majority of DNA in eukaryotic organisms is intimately wrapped around core histone proteins, forming chromatin, the physiological context in which the genomes of these organisms must function. Control of the dynamics of chromatin structure has been implicated widely in regulating both access to and interpretation of the associated DNA template 1 . For example, numerous studies suggest that gene expression patterns can be positively or negatively regulated by complexes of proteins that fine-tune the structural properties of chromatin, often through covalent PTMs of histone proteins or other chromatin-remodeling complexes 2,3 . As chromatin architecture may be transmissible to daughter cells along a particular developmental lineage, histones and their PTMs are likely candidates for epigenetic information carriers that propagate phenotypic determinants not encoded in the DNA sequence. More than 70 different sites for histone PTMs and eight HHS Public Access Author Manuscript Author ManuscriptAuthor ManuscriptAuthor Manuscript types of histone PTMs have been reported, largely from the extensive application of mass spectrometry-and antibody-based detection techniques, as well as from metabolic-labeling studies [1][2][3] . Remarkably, almost two-thirds of potentially modifiable residues on histones have been characterized as PTM sites, and as more sensitive detection methods become available, this number is likely to increase. Despite the large number of histone PTMs, only a subset of amino acid residues in histones are known to be covalently modified, which include lysine (K), arginine (R), serine (S), threonine (T), tyrosine (Y), histidine (H) and glutamic acid (E) 1 . The majority of the PTMs are additions of relatively small yet chemically and structurally distinct moieties, such as acetyl, methyl and phosphate groups (Fig. 1a); these have been identified on sites ranging from the flexible tail...
Methylated H3K27 is an important mark for Polycomb group (PcG) protein-mediated transcriptional gene silencing (TGS) in multicellular eukaryotes. Here a Drosophila E(z) homolog, EZL1, is characterized in the ciliated protozoan Tetrahymena thermophila and is shown to be responsible for H3K27 methylation associated with developmentally regulated heterochromatin formation and DNA elimination. Importantly, Ezl1p-catalyzed H3K27 methylation occurs in an RNA interference (RNAi)-dependent manner. H3K27 methylation also regulates H3K9 methylation in these processes. Furthermore, an "effector" of programmed DNA elimination, the chromodomain protein Pdd1p, is shown to bind both K27-and K9-methylated H3. These studies provide a framework for an RNAi-dependent, Polycomb group protein-mediated heterochromatin formation pathway in Tetrahymena and underscore the connection between the two highly conserved machineries in eukaryotes.[Keywords: RNA interference; H3K27 methylation; Polycomb group proteins; heterochromatin; DNA elimination] Supplemental material is available at http://www.genesdev.org.
Posttranslational histone modifications participate in modulating the structure and function of chromatin. Promoters of transcribed genes are enriched with K4 trimethylation and hyperacetylation on the N-terminal tail of histone H3. Recently, PHD finger proteins, like Yng1 in the NuA3 HAT complex, were shown to interact with H3K4me3, indicating a biochemical link between K4 methylation and hyperacetylation. By using a combination of mass spectrometry, biochemistry, and NMR, we detail the Yng1 PHD-H3K4me3 interaction and the importance of NuA3-dependent acetylation at K14. Furthermore, genome-wide ChIP-Chip analysis demonstrates colocalization of Yng1 and H3K4me3 in vivo. Disrupting the K4me3 binding of Yng1 altered K14ac and transcription at certain genes, thereby demonstrating direct in vivo evidence of sequential trimethyl binding, acetyltransferase activity, and gene regulation by NuA3. Our data support a general mechanism of transcriptional control through which histone acetylation upstream of gene activation is promoted partially through availability of H3K4me3, "read" by binding modules in select subunits.
Recent studies show that heterochromatin‐associated protein‐1 (HP1) recognizes a ‘histone code’ involving methylated Lys9 (methyl‐K9) in histone H3. Using in situ immunofluorescence, we demonstrate that methyl‐K9 H3 and HP1 co‐localize to the heterochromatic regions of Drosophila polytene chromosomes. NMR spectra show that methyl‐K9 binding of HP1 occurs via its chromo (chromosome organization modifier) domain. This interaction requires methyl‐K9 to reside within the proper context of H3 sequence. NMR studies indicate that the methylated H3 tail binds in a groove of HP1 consisting of conserved residues. Using fluorescence anisotropy and isothermal titration calorimetry, we determined that this interaction occurs with a KD of ∼100 μM, with the binding enthalpically driven. A V26M mutation in HP1, which disrupts its gene silencing function, severely destabilizes the H3‐binding interface, and abolishes methyl‐K9 H3 tail binding. Finally, we note that sequence diversity in chromo domains may lead to diverse functions in eukaryotic gene regulation. For example, the chromo domain of the yeast histone acetyltransferase Esa1 does not interact with methyl‐ K9 H3, but instead shows preference for unmodified H3 tail.
Histone H3 lysine 9 methylation [Me(Lys9)H3] is an epigenetic mark for heterochromatin-dependent gene silencing, mediated by direct binding to chromodomain-containing proteins such as Heterochromatin Protein 1. In the ciliate Tetrahymena, two chromodomain proteins, Pdd1p and Pdd3p, are involved in the massive programmed DNA elimination that accompanies macronuclear development. We report that both proteins bind H3(Lys9)Me in vitro. In vivo, H3(Lys9)Me is confined to the time period and location where DNA elimination occurs, and associates with eliminated sequences. Loss of parental Pdd1p expression drastically reduces H3(Lys9)Me. Finally, tethering Pdd1p is sufficient to promote DNA excision. These results extend the range of H3(Lys9)Me involvement in chromatin activities outside transcriptional regulation and also strengthen the link between heterochromatin formation and programmed DNA elimination.
The germline genome of the binucleated ciliate Tetrahymena thermophila undergoes programmed chromosome breakage and massive DNA elimination to generate the somatic genome. Here, we present a complete sequence assembly of the germline genome and analyze multiple features of its structure and its relationship to the somatic genome, shedding light on the mechanisms of genome rearrangement as well as the evolutionary history of this remarkable germline/soma differentiation. Our results strengthen the notion that a complex, dynamic, and ongoing interplay between mobile DNA elements and the host genome have shaped Tetrahymena chromosome structure, locally and globally. Non-standard outcomes of rearrangement events, including the generation of short-lived somatic chromosomes and excision of DNA interrupting protein-coding regions, may represent novel forms of developmental gene regulation. We also compare Tetrahymena’s germline/soma differentiation to that of other characterized ciliates, illustrating the wide diversity of adaptations that have occurred within this phylum.DOI: http://dx.doi.org/10.7554/eLife.19090.001
Summary Herpesviruses, which are major human pathogens, establish life-long persistent infections. Although the α-, β-, and γ-herpesviruses infect different tissues and cause distinct diseases, they each encode a conserved serine/threonine kinase critical for virus replication and spread. The extent of substrate conservation and the key common cell signalling pathways targeted by these kinases are unknown. Using a human protein microarray high-throughput approach we identify shared substrates of the conserved kinases from herpes simplex virus, human cytomegalovirus, Epstein-Barr virus (EBV) and Kaposi's sarcoma associated herpesvirus. DNA damage response (DDR) proteins were statistically enriched and the histone acetyltransferase TIP60, an upstream regulator of the DDR pathway, was required for efficient herpesvirus replication. During EBV replication, TIP60 activation by the BGLF4 kinase triggers EBV-induced DDR and also mediates induction of viral lytic gene expression. Identification of key cellular targets of the conserved herpesvirus kinases will facilitate the development of broadly effective anti-viral strategies.
Individual posttranslational modifications (PTMs) on histones have well established roles in certain biological processes, notably transcriptional programming. Recent genomewide studies describe patterns of covalent modifications, such as H3 methylation and acetylation at promoters of specific target genes, or ''bivalent domains,'' in stem cells, suggestive of a possible combinatorial interplay between PTMs on the same histone. However, detection of long-range PTM associations is often problematic in antibody-based or traditional mass spectrometric-based analyses. Here, histone H3 from a ciliate model was analyzed as an enriched source of transcriptionally active chromatin. Using a recently developed mass spectrometric approach, combinatorial modification states on single, long N-terminal H3 fragments (residues 1-50) were determined. The entire modification status of intact N termini was obtained and indicated correlations between K4 methylation and H3 acetylation. In addition, K4 and K27 methylation were identified concurrently on one H3 species. This methodology is applicable to other histones and larger polypeptides and will likely be a valuable tool in understanding the roles of combinatorial patterns of PTMs.bivalent domain ͉ electron transfer dissociation ͉ mass spectrometry ͉ posttranslational modifications ͉ Tetrahymena
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