Project description:The carboxy-terminal domain (CTD) of RNA polymerase II (Pol II) consists of heptad repeats with the consensus motif Y1-S2-P3-T4-S5-P6-S7. Dynamic phosphorylation of the CTD coordinates Pol II progression through the transcription cycle. Monoclonal antibodies have been used to study in vivo the potentially phosphorylated CTD amino acids (Y1, S2, T4, S5 and S7). However, the epitopes detected by antibodies can be masked by proteins or modifications at neighbouring sites. Therefore, the effectiveness of antibodies in western blot or ChIP analysis reflects the number of accessible CTD phosphorylation marks, but not the total number of phosphorylations. Most importantly, CTD phospho-specific antibodies do not provide any heptad - (location) specific information of CTD phosphorylation. Due to these limitations, the principles and patterns of CTD phosphorylation remained elusive. Here, we use genetic and mass spectrometric approaches to directly detect and map phosphosites along the entire CTD. We confirm phosphorylation of CTD residues Y1, S2, T4, S5 and S7 in mammalian and yeast cells. Although specific phosphorylation signatures dominate, adjacent CTD repeats can be differently phosphorylated, leading to a high variation of coexisting phosphosites in mono- and di-heptad CTD repeats. Inhibition of CDK9 kinase specifically reduces S2 phosphorylation levels within the CTD.

Project description:SUMOylation of Linker Histone H1 Drives Chromatin Condensation and Restriction of Embryonic Cell Fate Identity

Project description:Linker histone H1 plays a key role in chromatin organization and maintenance, however, our knowledge of the regulation of H1 functions by its posttranslational modifications (PTMs) is very limited. In this study, we report on the generation of homogeneously and site-specifically mono- and di-acetylated H1 (H1 Ac) using genetic code expansion. We used these modified histones to identify and comprehensively characterize the acetylation-dependent cellular interactome for linker histone H1 and show that site-specific acetylation results in overlapping, but distinct groups of interacting partners. Intriguingly, H1 acetylation-specific interactors comprise translational initiation factors and are involved in transcriptional regulation, suggesting that acetylation of H1 may indeed act as a regulator of the linker histone H1 by modulation of protein-protein interactions.

Project description:We employed the DamID technique to systematically map the genomic distribution of all canonical somatic H1 subtypes (H1.1-H1.5) in human IMR90 cells. Human cells contain up to eleven histone H1 proteins, with different spatial and temporal expression patterns. These include five canonical, replication-dependent somatic H1 subtypes (H1.1, H1.2, H1.3, H1.4 and H1.5). Despite being a key chromatin component, the genomic distribution of the somatic canonical H1 subtypes is still unknown and their role in chromatin related processes has so far remained elusive. Here we employed a DamID approach to map for the first time the genomic localization of all somatic canonical H1 subtypes in human cells. Our integrative analysis reveals novel insights into H1 subtype distribution and uncovers functional chromatin features potentially regulating the H1 genomic landscape. In general H1.2 to H1.5 are depleted from GC-rich regions and regulatory regions associated with active transcription. H1.1 shows a binding profile distinct from the other subtypes, suggesting a unique function for H1.1 in chromatin-regulated processes. Interestingly, our data indicate a novel role for somatic H1 subtypes in the three-dimensional organization of the genome by marking repressive regions within topological domains such as LADs. Our work integrates the five somatic linker histone H1 subtypes into the epigenome maps of human cells and provides a resource to refine our understanding of the significance of H1 and its heterogeneity in the control of genome function. DamID profiling of somatic linker histone variants H1.1, H1.2, H1.3, H1.4 and H1.5 in human fibroblasts. Two biological replicate samples of all H1 variants were hybridized on NimbleGen Human ChIP-chip 2.1M Economy Whole-Genome Tiling - Array GPL16055 covering small human chromosomes.

Project description:Eukaryotic chromosomal DNA is assembled into regularly spaced nucleosomes, which play a central role in gene regulation by determining accessibility of control regions. The nucleosome contains ~147 bp of DNA wrapped ~1.7 times around a central core histone octamer. The linker histone, H1, binds both to the nucleosome, sealing the DNA coils, and to the linker DNA between nucleosomes, directing chromatin folding. Micrococcal nuclease (MNase) digests the linker to yield the chromatosome, containing H1 and ~160 bp, and then converts it to a core particle, containing ~147 bp and no H1. Sequencing of nucleosomal DNA obtained after MNase digestion (MNase-seq) generates genome-wide nucleosome maps that are important for understanding gene regulation. We present an improved MNase-seq method involving simultaneous digestion with exonuclease III, which removes linker DNA. Remarkably, we discovered two novel intermediate particles containing 154 or 161 bp, corresponding to 7 bp protruding from one or both sides of the nucleosome core. These particles are detected in yeast lacking H1 and in H1-depleted mouse chromatin. They can be reconstituted in vitro using purified core histones and DNA. We propose that these "proto-chromatosomes" are fundamental chromatin subunits, which include the H1 binding site and influence nucleosome spacing independently of H1.

Project description:Linker histones are involved in the formation of higher-order chromatin structure. Although linker histones have been implicated in the regulation of specific genes, it still remains unclear what their principal binding determinants are and how their repressive function in vitro can be reconciled with presumed broad binding in vivo. We generated a full genome, high resolution binding map of linker histone H1 in Drosophila Kc cells, using DamID. H1 binds at similar levels across much of the genome, both in classical euchromatin and heterochromatin. Strikingly, there are pronounced dips of low H1 occupancy around transcription start sites of active genes and at many distant cis-regulatory sites. H1 dips are not due to lack of nucleosomes. Rather, all regions with low binding of H1 show enrichment of the histone variant H3.3 which itself has been linked to high nucleosome turnover. Upon knockdown of H3.3, we find that H1 levels increase at sites previously not covered with H1 with a concomitant increase in nucleosome repeat length. These changes are independent of transcriptional changes. Our results show that the H3.3 protein counteracts association of H1 at genomic sites with high rates of histone turnover. This antagonism provides a mechanism to keep diverse genomic sites in an open chromatin conformation. For this study, we generated DamID profiles of histone H1 and RpII18 and a FAIRE profile in Drosophila Kc167 cells. Additionally, we generated H1 profiles in cells treated with RNAi against white, H3.3B, or H3.3A and H3.3B. Nucleosome positioning profiles were generated in untreated cells and cells treated with RNAi against white, H3.3B, or H3.3A and H3.3B. Profiles of expression changes were generated for H3.3B RNAi and H3.3A and H3.3B RNAi. DamID experiments for H1 and RpII18 were performed in Drosophila cell cultures. Samples were hybridized to 380k NimbleGen arrays with 300 bp probe spacing. Formaldehyde-assisted isolation of regulatotry elements (FAIRE) was performed in Drosophila Kc167 cells. Samples were hybridized to 380k NimbleGen arrays with 300 bp probe spacing over non-crosslinked genomic DNA. Nucleosome positioning profiles were made by hybridizing mononucleosomal DNA over MNase digested purified genomic DNA on 380k NimbleGen arrays with 10 bp probe spacing. Expression profiles were made as H3.3 RNAi over white RNAi cohybridizations on spotted INDAC long oligo arrays. Every experiment was done in duplicate in the reverse dye orientation.

Project description:Linker histones are involved in the formation of higher-order chromatin structure. Although linker histones have been implicated in the regulation of specific genes, it still remains unclear what their principal binding determinants are and how their repressive function in vitro can be reconciled with presumed broad binding in vivo. We generated a full genome, high resolution binding map of linker histone H1 in Drosophila Kc cells, using DamID. H1 binds at similar levels across much of the genome, both in classical euchromatin and heterochromatin. Strikingly, there are pronounced dips of low H1 occupancy around transcription start sites of active genes and at many distant cis-regulatory sites. H1 dips are not due to lack of nucleosomes. Rather, all regions with low binding of H1 show enrichment of the histone variant H3.3 which itself has been linked to high nucleosome turnover. Upon knockdown of H3.3, we find that H1 levels increase at sites previously not covered with H1 with a concomitant increase in nucleosome repeat length. These changes are independent of transcriptional changes. Our results show that the H3.3 protein counteracts association of H1 at genomic sites with high rates of histone turnover. This antagonism provides a mechanism to keep diverse genomic sites in an open chromatin conformation. For this study, we generated DamID profiles of histone H1 and RpII18 in Drosophila Kc167 cells. Additionally, we generated H1 profiles in cells treated with RNAi against white, H3.3B, or H3.3A and H3.3B. Nucleosome occupancy profiles were generated in untreated cells and cells treated with RNAi against white or H3.3A and H3.3B. Profiles of expression changes were generated for H3.3B RNAi and H3.3A and H3.3B RNAi. DamID experiments for H1 and RpII18 were performed in Drosophila cell cultures. Samples were hybridized to 380k NimbleGen arrays with 300 bp probe spacing. Formaldehyde-assisted isolation of regulatotry elements (FAIRE) was performed in Drosophila Kc167 cells. Samples were hybridized to 380k NimbleGen arrays with 300 bp probe spacing over non-crosslinked genomic DNA. Nucleosome positioning profiles were made by hybridizing mononucleosomal DNA over MNase digested purified genomic DNA on 380k NimbleGen arrays with 10 bp probe spacing. Expression profiles were made as H3.3 RNAi over white RNAi cohybridizations on spotted INDAC long oligo arrays. Every experiment was done in duplicate in the reverse dye orientation.

Project description:SUMOylation of Linker Histone H1 Drives Chromatin Condensation and Restriction of Embryonic Cell Fate Identity [SMART-Seq]

Project description:SUMOylation of Linker Histone H1 Drives Chromatin Condensation and Restriction of Embryonic Cell Fate Identity [ChIP-seq]

Project description:SUMOylation of Linker Histone H1 Drives Chromatin Condensation and Restriction of Embryonic Cell Fate Identity [RNA-seq]