Project description:Background: Histone post-translational modifications (PTMs) constitute a branch of epigenetic mechanisms that can control the expression of eukaryotic genes in a heritable manner. Recent studies have identified several PTM-binding proteins containing diverse specialized domains whose recognition of specific PTM sites leads to gene activation or repression. Here, we present a high-throughput proteogenomic platform designed to characterize the nucleosomal make-up of chromatin enriched with a set of histone PTM-binding proteins known as histone PTM readers. We support our findings with gene expression data correlating to PTM distribution. Results: We isolated human mononucleosomes bound by the bromodomain-containing proteins Brd2, Brd3 and Brd4, and by the chromodomain-containing heterochromatin proteins HP1alpha and HP1beta. Histone PTMs were quantified by mass spectrometry (ChIP-qMS), and their associated DNAs were mapped using deep sequencing. Our results reveal that Brd- and HP1-bound nucleosomes are enriched in histone PTMs consistent with actively transcribed euchromatin and silent heterochromatin, respectively. Data collected using RNA-Seq (GSM301568) show that Brd-bound sites correlate with highly expressed genes. In particular, Brd3 and Brd4 are most enriched on nucleosomes located within HOX gene clusters, whose expression is reduced upon Brd4 depletion by shRNA. Conclusions: Proteogenomic mapping of histone PTM readers, alongside the characterization of their local chromatin environments and transcriptional information, should prove useful for determining how histone PTMs are bound by these readers and how they contribute to distinct transcriptional states. Examination of Brd and HP1 proteins-binding sites in HEK293 cells.

Project description:Background: Histone post-translational modifications (PTMs) constitute a branch of epigenetic mechanisms that can control the expression of eukaryotic genes in a heritable manner. Recent studies have identified several PTM-binding proteins containing diverse specialized domains whose recognition of specific PTM sites leads to gene activation or repression. Here, we present a high-throughput proteogenomic platform designed to characterize the nucleosomal make-up of chromatin enriched with a set of histone PTM-binding proteins known as histone PTM readers. We support our findings with gene expression data correlating to PTM distribution. Results: We isolated human mononucleosomes bound by the bromodomain-containing proteins Brd2, Brd3 and Brd4, and by the chromodomain-containing heterochromatin proteins HP1alpha and HP1beta. Histone PTMs were quantified by mass spectrometry (ChIP-qMS), and their associated DNAs were mapped using deep sequencing. Our results reveal that Brd- and HP1-bound nucleosomes are enriched in histone PTMs consistent with actively transcribed euchromatin and silent heterochromatin, respectively. Data collected using RNA-Seq (GSM301568) show that Brd-bound sites correlate with highly expressed genes. In particular, Brd3 and Brd4 are most enriched on nucleosomes located within HOX gene clusters, whose expression is reduced upon Brd4 depletion by shRNA. Conclusions: Proteogenomic mapping of histone PTM readers, alongside the characterization of their local chromatin environments and transcriptional information, should prove useful for determining how histone PTMs are bound by these readers and how they contribute to distinct transcriptional states. Comparison of Brd2 and HP1b shRNA knockdown HEK293 cells to control knockdown HEK293 cells.

Project description:The recognition of modified histones by “reader” proteins constitutes a key mechanism regulating gene expression in the chromatin context. Compared with the great variety of readers for histone methylation, few protein modules that recognize histone acetylation are known. Here we show that the evolutionarily conserved YEATS domains constitute a novel family of acetyllysine readers. The human AF9 YEATS domain binds strongly to histone H3K9 acetylation and, to a lesser extent, H3K27 and H3K18 acetylation. Crystal structural studies revealed that AF9 YEATS adopts an eight-stranded immunoglobin fold and utilizes a serine-lined aromatic “sandwiching” cage for acetyllysine readout, representing a novel recognition mechanism that is distinct from that of known acetyllysine readers. Histone acetylation recognition by AF9 is important for the chromatin recruitment of the H3K79 methyltransferase DOT1L. Together, our studies identify the YEATS domain as a novel acetyllysine-binding module, thereby establishing the first direct link between histone acetylation and DOTL1-mediated H3K79 methylation in transcription control. ChIP-seq analysis of AF9, H3K79me3, H3K9ac in Hela cells and H3K79me3 in Hela AF9 knockdown and Hela Dot1L knockdown cells.

Project description:Elucidation of interactions involving DNA and histone post-translational-modifications (PTMs) is essential for providing insight into complex biological functions. Reader assemblies connected via flexible linkages facilitate avidity and increase affinity, however little is known of the contribution to the recognition process of multiple PTMs due to rigidity in the absence of conformational flexibility. We report here the high resolution crystal structure of the triple-reader module (PHD-Bromo-PWWP) of ZMYND8 which forms a stable unit capable of simultaneously recognizing multiple histone PTMs, while presenting a charged platform for association with DNA. Single domain disruptions destroy the functional network of interactions initiated by ZMYND8, impairing recruitment to sites of DNA damage. Our data establish proof-of-principle that rigidity can be compensated by concomitant DNA and histone PTM interactions, maintaining multivalent engagement of transient chromatin states, thus identifying an important underappreciated role for rigid multivalent reader modules in nucleosome binding and chromatin function.

Project description:Elucidation of multivalent interactions involving both DNA and histone post-translational-modifications (PTMs) is essential for providing insight into complex biological functions. We report here the high resolution crystal structure of the N-terminal triple reader module (PHD-Bromo-PWWP) of ZMYND8, which forms a stable unit, capable of simultaneously recognizing histone PTMs and providing a charged platform for DNA interaction. Monte Carlo simulations provide a model whereby the reader module directly engages the core nucleosome particle, extracting the entire histone H3 tail and initiating contacts with the DNA super-coil structure. Systematic mutation of these interaction interfaces reveals cooperativity within the ensemble. Single domain disruption destroys the functional network of interactions initiated by ZMYND8, which impairs recruitment to sites of DNA damage and alters transcription. Taken together, our results establish an important role of the ZMYND8 multivalent reader module in nucleosome binding and chromatin function.

Project description:Nucleosome context regulates chromatin reader preference

Project description:Chemical modification of histone proteins by methylation plays a central role in chromatin regulation by recruiting epigenetic ‘readers’ via specialized binding domains. Depending on the degree of methylation, the exact modified amino acid, and the associated reader proteins histone methylations are involved in the regulation of all DNA-based processes, such as transcription, DNA replication, and DNA repair. We have previously established a method that allows the unbiased identification of nuclear proteins which binding to nucleosomes is regulated by the presence of specific histone modifications (1,2). The method is based on an in-vitro reconstitution of semi-synthetic nucleosomes bearing a predefined set of histone modifications which are subsequently used as baits for affinity purification pull-down experiments with nuclear extracts followed by identification and quantification of nucleosome-interacting proteins using LC-MS/MS. Here we provide a representative set of label-free MS results for nucleosome pull-down affinity purification experiments performed using unmodified as well as H3K4me3- and H3K9me3-modified di-nucleosomes and nuclear extract obtained from HeLa S3 cells. 1. Bartke T, Vermeulen M, Xhemalce B, Robson SC, Mann M, Kouzarides T (2010) Nucleosome-interacting proteins regulated by DNA and histone methylation. Cell 143:470-484 2. Makowski MM, Gräwe C, Foster BM, Nguyen NV, Bartke T, Vermeulen M (2018) Global profiling of protein-DNA and protein-nucleosome binding affinities using quantitative mass spectrometry. Nat Commun 9:1653

Project description:Histone post-translational modifications (PTMs) play a critical role in chromatin regulation. It has been proposed that these PTMs form localized “codes” that are read by specialized domains (reader domains) in chromatin associated proteins (CAPs) to regulate downstream function. Substantial effort has been made to define [CAP - histone PTM] specificity, and in doing so to decipher the histone code. However, this has largely been done using a reductive approach of isolated reader domains and histone peptides, with the assumption that PTM readout is unaffected by any higher order considerations. Here we show that histone PTM specificity is in fact dependent on nucleosomal context, necessitating we re-define the ‘histone code’ concept and further interrogate it at the nucleosomal level.

Project description:Lysine and arginine methylation are amongst the most frequent modifications on unstructured histone tails and in combination with other modifications provide the basis for a combinatorial 'chromatin or histone code'. Recognition of modified histone residues is accomplished in a specific manner by 'reader' domains that recognize chromatin modifications allowing to associate with specific effector complexes mediating chromatin functions. The methyl-lysine and methyl-arginine reader domain protein SPINDLIN1 (SPIN1) belongs to a family of 5 human genes, and has been identified as a putative oncogene and transcriptional co-activator containing three Tudor domains, able to mediate chromatin binding. Here we report on the discovery of the potent and selective bivalent Tudor domain inhibitor VinSPINIn* (see Footnote), which simultaneously engages Tudor domains 1 and 2 and effectively competes with chromatin binding. Inhibitor, chemoproteomic and knockdown studies in squamous cell carcinoma suggest an un-anticipated complexity of SPIN isoform mediated interactions in regulating cellular phenotypes.

Project description:Background: Histone post-translational modifications (PTMs) constitute a branch of epigenetic mechanisms that can control the expression of eukaryotic genes in a heritable manner. Recent studies have identified several PTM-binding proteins containing diverse specialized domains whose recognition of specific PTM sites leads to gene activation or repression. Here, we present a high-throughput proteogenomic platform designed to characterize the nucleosomal make-up of chromatin enriched with a set of histone PTM-binding proteins known as histone PTM readers. We support our findings with gene expression data correlating to PTM distribution. Results: We isolated human mononucleosomes bound by the bromodomain-containing proteins Brd2, Brd3 and Brd4, and by the chromodomain-containing heterochromatin proteins HP1alpha and HP1beta. Histone PTMs were quantified by mass spectrometry (ChIP-qMS), and their associated DNAs were mapped using deep sequencing. Our results reveal that Brd- and HP1-bound nucleosomes are enriched in histone PTMs consistent with actively transcribed euchromatin and silent heterochromatin, respectively. Data collected using RNA-Seq (GSM301568) show that Brd-bound sites correlate with highly expressed genes. In particular, Brd3 and Brd4 are most enriched on nucleosomes located within HOX gene clusters, whose expression is reduced upon Brd4 depletion by shRNA. Conclusions: Proteogenomic mapping of histone PTM readers, alongside the characterization of their local chromatin environments and transcriptional information, should prove useful for determining how histone PTMs are bound by these readers and how they contribute to distinct transcriptional states.