Project description:H1 linker histones are the most abundant chromatin-binding proteins1. In vitro studies indicate that their association with chromatin determines nucleosome spacing and enables arrays of nucleosomes to fold into more compact chromatin structures. However, the in vivo roles of H1 are poorly understood2. Here we show that the local density of H1 controls the balance of repressive and active chromatin domains by promoting genomic compaction. We generated a conditional triple-H1-knockout mouse strain and depleted H1 in haematopoietic cells. H1 depletion in T cells leads to de-repression of T cell activation genes, a process that mimics normal T cell activation. Comparison of chromatin structure in normal and H1-depleted CD8+ T cells reveals that H1-mediated chromatin compaction occurs primarily in regions of the genome containing higher than average levels of H1: the chromosome conformation capture (Hi-C) B compartment and regions of the Hi-C A compartment marked by PRC2. Reduction of H1 stoichiometry leads to decreased H3K27 methylation, increased H3K36 methylation, B-to-A-compartment shifting and an increase in interaction frequency between compartments. In vitro, H1 promotes PRC2-mediated H3K27 methylation and inhibits NSD2-mediated H3K36 methylation. Mechanistically, H1 mediates these opposite effects by promoting physical compaction of the chromatin substrate. Our results establish H1 as a critical regulator of gene silencing through localized control of chromatin compaction, 3D genome organization and the epigenetic landscape.

Project description:In mammals, DNA methylation is essential for protecting repetitive sequences from aberrant transcription and recombination. In some developmental contexts (e.g., preimplantation embryos) DNA is hypomethylated but repetitive elements are not dysregulated, suggesting that alternative protection mechanisms exist. Here we explore the processes involved by investigating the role of the chromatin factors Daxx and Atrx. Using genome-wide binding and transcriptome analysis, we found that Daxx and Atrx have distinct chromatin-binding profiles and are co-enriched at tandem repetitive elements in wild-type mouse ESCs. Global DNA hypomethylation further promoted recruitment of the Daxx/Atrx complex to tandem repeat sequences, including retrotransposons and telomeres. Knockdown of Daxx/Atrx in cells with hypomethylated genomes exacerbated aberrant transcriptional de-repression of repeat elements and telomere dysfunction. Mechanistically, Daxx/Atrx-mediated repression seems to involve Suv39h recruitment and H3K9 trimethylation. Our data therefore suggest that Daxx and Atrx safeguard the genome by silencing repetitive elements when DNA methylation levels are low.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:H1 linker histones are key chromatin architectural proteins facilitating the formation of higher order chromatin structures. The H1 family constitutes the most heterogeneous group of histone proteins, with eleven non-allelic H1 variants in mammals. H1 variants differ in their biochemical properties and exhibit significant sequence divergence from one another, yet most of them are highly conserved during evolution from mouse to human. H1 variants are differentially regulated during development and their cellular compositions undergo dramatic changes in embryogenesis, gametogenesis, tissue maturation and cellular differentiation. As a group, H1 histones are essential for mouse development and proper stem cell differentiation. Here we summarize our current knowledge on the expression and functions of H1 variants in mammalian development and stem cell differentiation. Their diversity, sequence conservation, complex expression and distinct functions suggest that H1s mediate chromatin reprogramming and contribute to the large variations and complexity of chromatin structure and gene expression in the mammalian genome.

Project description:H1 linker histones are the most abundant chromatin binding proteins. Their association with chromatin determines the spacing between nucleosomes and enables arrays of nucleosomes to fold into more compact chromatin structures. Mammals express multiple H1 proteins and are able to compensate for the loss of one or even two members by increasing synthesis of other members to maintain a constant H1 to nucleosome stoichiometry. To study the role of H1 in mammalian development, we generated a conditional triple H1 knockout (H1cTKO) mouse strain that enables depletion of H1 in specific cell types. Here, we report on the effects of depleting H1 in adult hematopoietic cells. Deletion of the genes encoding three widely expressed H1 subtypes (H1c, H1d, and H1e) has particularly profound effects on B- and T- lymphocyte development. H1 depletion leads to de-repression of T-cell activation genes, and a shift in T-cells towards effector functions, a process that mimics normal T-cell activation. Comparison of chromatin structure in normal and H1-depleted CD8+ T-cells revealed that H1 binding produces localized chromatin compaction within spatially defined chromatin domains containing above average levels of H1. Reduction of H1 stoichiometry in these regions leads to decreases in H3K27 methylation and increases in H3K36 methylation. In vitro, H1 promotes PRC2-mediated H3K27 methylation and inhibits NSD2-mediated H3K36 methylation. Mechanistically, H1 mediates these opposite effects by promoting physical compaction of the chromatin substrate. These findings identify H1 as a critical regulator of the epigenetic landscape in mammalian cells.

Project description:H1 linker histones are the most abundant chromatin binding proteins. Their association with chromatin determines the spacing between nucleosomes and enables arrays of nucleosomes to fold into more compact chromatin structures. Mammals express multiple H1 proteins and are able to compensate for the loss of one or even two members by increasing synthesis of other members to maintain a constant H1 to nucleosome stoichiometry. To study the role of H1 in mammalian development, we generated a conditional triple H1 knockout (H1cTKO) mouse strain that enables depletion of H1 in specific cell types. Here, we report on the effects of depleting H1 in adult hematopoietic cells. Deletion of the genes encoding three widely expressed H1 subtypes (H1c, H1d, and H1e) has particularly profound effects on B- and T- lymphocyte development. H1 depletion leads to de-repression of T-cell activation genes, and a shift in T-cells towards effector functions, a process that mimics normal T-cell activation. Comparison of chromatin structure in normal and H1-depleted CD8+ T-cells revealed that H1 binding produces localized chromatin compaction within spatially defined chromatin domains containing above average levels of H1. Reduction of H1 stoichiometry in these regions leads to decreases in H3K27 methylation and increases in H3K36 methylation. In vitro, H1 promotes PRC2-mediated H3K27 methylation and inhibits NSD2-mediated H3K36 methylation. Mechanistically, H1 mediates these opposite effects by promoting physical compaction of the chromatin substrate. These findings identify H1 as a critical regulator of the epigenetic landscape in mammalian cells.

Project description:H1 linker histones are the most abundant chromatin binding proteins. Their association with chromatin determines the spacing between nucleosomes and enables arrays of nucleosomes to fold into more compact chromatin structures. Mammals express multiple H1 proteins and are able to compensate for the loss of one or even two members by increasing synthesis of other members to maintain a constant H1 to nucleosome stoichiometry. To study the role of H1 in mammalian development, we generated a conditional triple H1 knockout (H1cTKO) mouse strain that enables depletion of H1 in specific cell types. Here, we report on the effects of depleting H1 in adult hematopoietic cells. Deletion of the genes encoding three widely expressed H1 subtypes (H1c, H1d, and H1e) has particularly profound effects on B- and T- lymphocyte development. H1 depletion leads to de-repression of T-cell activation genes, and a shift in T-cells towards effector functions, a process that mimics normal T-cell activation. Comparison of chromatin structure in normal and H1-depleted CD8+ T-cells revealed that H1 binding produces localized chromatin compaction within spatially defined chromatin domains containing above average levels of H1. Reduction of H1 stoichiometry in these regions leads to decreases in H3K27 methylation and increases in H3K36 methylation. In vitro, H1 promotes PRC2-mediated H3K27 methylation and inhibits NSD2-mediated H3K36 methylation. Mechanistically, H1 mediates these opposite effects by promoting physical compaction of the chromatin substrate. These findings identify H1 as a critical regulator of the epigenetic landscape in mammalian cells.

Project description:H1 linker histones are the most abundant chromatin binding proteins. Their association with chromatin determines the spacing between nucleosomes and enables arrays of nucleosomes to fold into more compact chromatin structures. Mammals express multiple H1 proteins and are able to compensate for the loss of one or even two members by increasing synthesis of other members to maintain a constant H1 to nucleosome stoichiometry. To study the role of H1 in mammalian development, we generated a conditional triple H1 knockout (H1cTKO) mouse strain that enables depletion of H1 in specific cell types. Here, we report on the effects of depleting H1 in adult hematopoietic cells. Deletion of the genes encoding three widely expressed H1 subtypes (H1c, H1d, and H1e) has particularly profound effects on B- and T- lymphocyte development. H1 depletion leads to de-repression of T-cell activation genes, and a shift in T-cells towards effector functions, a process that mimics normal T-cell activation. Comparison of chromatin structure in normal and H1-depleted CD8+ T-cells revealed that H1 binding produces localized chromatin compaction within spatially defined chromatin domains containing above average levels of H1. Reduction of H1 stoichiometry in these regions leads to decreases in H3K27 methylation and increases in H3K36 methylation. In vitro, H1 promotes PRC2-mediated H3K27 methylation and inhibits NSD2-mediated H3K36 methylation. Mechanistically, H1 mediates these opposite effects by promoting physical compaction of the chromatin substrate. These findings identify H1 as a critical regulator of the epigenetic landscape in mammalian cells.

Project description:H1 linker histones are the most abundant chromatin binding proteins. Their association with chromatin determines the spacing between nucleosomes and enables arrays of nucleosomes to fold into more compact chromatin structures. Mammals express multiple H1 proteins and are able to compensate for the loss of one or even two members by increasing synthesis of other members to maintain a constant H1 to nucleosome stoichiometry. To study the role of H1 in mammalian development, we generated a conditional triple H1 knockout (H1cTKO) mouse strain that enables depletion of H1 in specific cell types. Here, we report on the effects of depleting H1 in adult hematopoietic cells. Deletion of the genes encoding three widely expressed H1 subtypes (H1c, H1d, and H1e) has particularly profound effects on B- and T- lymphocyte development. H1 depletion leads to de-repression of T-cell activation genes, and a shift in T-cells towards effector functions, a process that mimics normal T-cell activation. Comparison of chromatin structure in normal and H1-depleted CD8+ T-cells revealed that H1 binding produces localized chromatin compaction within spatially defined chromatin domains containing above average levels of H1. Reduction of H1 stoichiometry in these regions leads to decreases in H3K27 methylation and increases in H3K36 methylation. In vitro, H1 promotes PRC2-mediated H3K27 methylation and inhibits NSD2-mediated H3K36 methylation. Mechanistically, H1 mediates these opposite effects by promoting physical compaction of the chromatin substrate. These findings identify H1 as a critical regulator of the epigenetic landscape in mammalian cells.

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.