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:As a key structural component of the chromatin of higher eukaryotes, linker histones (H1s) are involved in stabilizing the folding of extended nucleosome arrays into higher-order chromatin structures and function as a gene-specific regulators of transcription in vivo. The H1 C-terminal domain (CTD) is essential for high affinity binding of linker histones to chromatin and stabilization of higher-order chromatin structure. Importantly, the H1 CTD is an intrinsically disordered domain that undergoes a drastic condensation upon binding to nucleosomes. Moroever, although phosphorylation is a prevalent posttranslational modification (PTM) within the H1 CTD, exactly where this modification is installed and how phosphorylation influences the structure of the H1 CTD remains unclear for many H1s. Using novel mass spectrometry techniques, we identified six phosphorylation sites within the CTD of the archetypal linker histone Xenopus H1.0. We then analyzed nucleosome-dependent CTD condensation and H1-dependent linker DNA conformation for six full-length H1s in which the phosphorylated serine residues were replaced by glutamic acid residues.

Project description:Chromatin dynamics can regulate all DNA-dependent processes. Access to DNA within chromatin is orchestrated mainly by histones and their posttranslational modifications (PTM). Like other eukaryotes, the apicomplexan parasite Toxoplasma gondii encodes for four canonical histones and five histone variants. By contrast, the linker histone (H1) has never been identified in apicomplexan parasites. In other eukaryotes, histone H1 compacts the chromatin by linking the nucleosome and increasing the DNA compaction. H1 is a multifunctional protein and can be involved in different steps of DNA metabolism or associated with protein complexes related to distinct biological processes. We have identified a novel protein in T. gondii that, although lacking the globular domain of mammalian H1, is remarkably like the H1-like proteins of bacteria and trypanosomatids. Our results demonstrate that TgH1-like is a nuclear protein associated with chromatin and other histones. Curiously, TgH1-like is also in the nucleolus and associated with ribosomal proteins, indicating a versatile function in this parasite. Although knockout of tgh1-like does not affect the cell cycle, it causes endopolygeny and asynchronous division. Interestingly, mutating post-translationally modified amino acids results in defects in cell division like ∆tgh1-like, showing that these sites are important for protein function. Furthermore, in the bradyzoite stage, this protein is expressed only in dividing parasites, reinforcing its importance in cell division. Indeed, the absence of TgH1-like decreases compaction of peripheral chromatin, confirming its role in the chromatin modulation in T. gondii.

Project description:H1 linker histones facilitate higher order chromatin folding and are essential for mammalian development. To achieve high resolution mapping of H1 variants H1d and H1c in embryonic stem cells (ESCs), we have established a knock-in system and shown that the N-terminally tagged H1 proteins are functionally interchangeable to their endogenous counterparts in vivo. H1d and H1c are depleted from GC- and gene-rich regions and active promoters, inversely correlated with H3K4me3, but positively correlated with H3K9me3 and associated with characteristic sequence features. Surprisingly, both H1d and H1c are significantly enriched at major satellites, which display increased nucleosome spacing compared with bulk chromatin. While also depleted at active promoters and enriched at major satellites, overexpressed H10 displays differential binding patterns in specific repetitive sequences compared with H1d and H1c. Depletion of H1c, H1d and H1e causes pericentric chromocenter clustering and de-repression of major satellites. These results integrate the localization of an understudied type of chromatin proteins, namely the H1 variants, into the epigenome map of mouse ESCs, and we identify significant changes at pericentric heterochromatin upon depletion of this epigenetic mark. Mapping linker histone H1 variants H1d, H1c and H10 as well as 3 core histone modifications in mouse ESC genome.

Project description:In humans, there are eleven subtypes of linker histones that exhibit cell- and tissue-specific expression. Linker histone H1 proteins bind to both the core histones and linker DNA of chromatin fibers; and not only participate in control of gene activity but also serve to stabilize higher order chromatin structure. To determine the potential roles of linker histones in differentiation, we examined the global distribution of linker histone subtype H1.5 in human IMR90 fibroblasts and H1 embryonic stem cells (hESCs). Surprisingly, H1.5 binds to and represses a large fraction of gene family clusters in fully differentiated cell types representing all three embryonic germ layers. Little or no H1.5 enrichment at gene family clusters was detected in undifferentiated hESCs or partially differentiated somatic cells. We also found that SIRT1 histone deacetylase and H3K9me2, a repressive histone modification, are also enriched at gene family cluster in IMR90 cells, likely generating a stably repressive chromatin domain. To find out the mechanism of H1.5 targeting, H1.5 or SIRT1 was depleted in IMR90 cells by siRNA, and the binding patterns of SIRT1 and H1.5 were examined. In H1.5 knockdown cells, SIRT1 binding pattern was changed dramatically, and this changed pattern highly correlates to SIRT1 distribution in hESC. However, depletion of SIRT1 could not change the global binding pattern of H1.5. Depletion of H1.5 or SIRT1 leads to up-regulation of ~50% gene family clusters. However, the sets of gene family clusters that are affected by these two factors are different, suggesting H1.5 and SIRT1 may regulate gene transcription via different pathways. One-color array. Two replicates for each sample.

Project description:In humans, there are eleven subtypes of linker histones that exhibit cell- and tissue-specific expression. Linker histone H1 proteins bind to both the core histones and linker DNA of chromatin fibers; and not only participate in control of gene activity but also serve to stabilize higher order chromatin structure. To determine the potential roles of linker histones in differentiation, we examined the global distribution of linker histone subtype H1.5 in human IMR90 fibroblasts and H1 embryonic stem cells (hESCs). Surprisingly, H1.5 binds to and represses a large fraction of gene family clusters in fully differentiated cell types representing all three embryonic germ layers. Little or no H1.5 enrichment at gene family clusters was detected in undifferentiated hESCs or partially differentiated somatic cells. We also found that SIRT1 histone deacetylase and H3K9me2, a repressive histone modification, are also enriched at gene family cluster in IMR90 cells, likely generating a stably repressive chromatin domain. To find out the mechanism of H1.5 targeting, H1.5 or SIRT1 was depleted in IMR90 cells by siRNA, and the binding patterns of SIRT1 and H1.5 were examined. In H1.5 knockdown cells, SIRT1 binding pattern was changed dramatically, and this changed pattern highly correlates to SIRT1 distribution in hESC. However, depletion of SIRT1 could not change the global binding pattern of H1.5. Depletion of H1.5 or SIRT1 leads to up-regulation of ~50% gene family clusters. However, the sets of gene family clusters that are affected by these two factors are different, suggesting H1.5 and SIRT1 may regulate gene transcription via different pathways. Two-color microarrays. Two replicates for each sample.

Project description:Decoding the role of histone posttranslational modifications (PTMs) is key to understand the fundamental process of epigenetic regulation. While this process is well studied for core histones and many of their PTMs, this is not the case for linker histone H1 in general and its ubiquitylation in particular due to a lack of proper tools. Here, we report on the generation of site-specifically mono-ubiquitylated H1.2 via click chemistry and identify its ubiquitin-dependent interactome on a proteome-wide scale. We show that the H1 interactome is generally modulated by ubiquitylation and that site-specific ubiquitylation results in overlapping, but distinct interactomes. We further demonstrate that site-specific ubiquitylation of H1 affects the interaction with enzymes relevant for deubiquitylation and deacetylation. We finally show that site-specific ubiquitylation at position K64 impacts H1-dependent chromatosome assembly as well as H1-induced phase separation. In summary, we propose that site-specific ubiquitylation plays a general regulatory role for linker histone H1.

Project description:Decoding the role of histone posttranslational modifications (PTMs) is key to understand the fundamental process of epigenetic regulation. While this process is well studied for core histones and many of their PTMs, this is not the case for linker histone H1 in general and its ubiquitylation in particular due to a lack of proper tools. Here, we report on the generation of site-specifically mono-ubiquitylated H1.2 via click chemistry and identify its ubiquitin-dependent interactome on a proteome-wide scale. We show that the H1 interactome is generally modulated by ubiquitylation and that site-specific ubiquitylation results in overlapping, but distinct interactomes. We further demonstrate that site-specific ubiquitylation of H1 affects the interaction with enzymes relevant for deubiquitylation and deacetylation. We finally show that site-specific ubiquitylation at position K64 impacts H1-dependent chromatosome assembly as well as H1-induced phase separation. In summary, we demonstrate that site-specific ubiquitylation is a general functional regulator for linker histone H1.

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 highly abundant chromatin-associated proteins with well-established structural roles in chromatin and as general transcriptional repressors. In addition, it has been long proposed that histone H1 exerts context-specific effects on gene expression. Here, we have identified a new function of histone H1 in chromatin structure and transcription using a range of genomic approaches. We show that histone H1-depleted cells accumulate nascent non-coding RNAs on chromatin, suggesting that histone H1 prevents non-coding RNA transcription and regulates non-coding transcript turnover on chromatin. Accumulated non-coding transcripts have reduced levels of m6A modification causing replication-transcription conflicts. Accordingly, altering the m6A RNA methylation pathway rescues the replicative phenotype of H1 loss. This work unveils unexpected regulatory roles of histone H1 on non-coding RNA turnover and m6A deposition, highlighting the intimate relationship between chromatin conformation, RNA metabolism and DNA replication to maintain genome performance.