Project description:Chromosomes must correctly fold in eukaryotic nuclei for proper genome function. Eukaryotic organisms hierarchically organize their genomes: in the fungus Neurospora crassa, chromatin fiber loops compact into Topologically Associated Domain (TAD)-like structures that are anchored by heterochromatic region aggregates. However, insufficient information exists on how histone post-translational modifications, including acetylation, impact genome organization. In Neurospora, the HCHC (HDA-1, CDP-2, HP1, CHAP) complex deacetylates heterochromatic regions including centromeres: loss of individual HCHC members increases centromeric acetylation and cytosine methylation. Here, we evaluate the role of the HCHC complex on genome organization using chromosome conformation capture with high-throughput sequencing (Hi-C) in Δcdp-2 or Δchap deletion strains. CDP-2 loss increases interactions between intra- and inter-chromosomal heterochromatic regions, while removal of CHAP decreases heterochromatic region compaction. Individual HCHC mutants exhibit different histone PTM patterns genome-wide: in Dcdp-2, heterochromatic H4K16 acetylation is increased, yet some heterochromatic regions lose H3K9 trimethylation, which locally increases inter-heterochromatin contacts; CHAP loss produces minimal acetylation changes but increases H3K9me3 enrichment in heterochromatin. Furthermore, deletion of the DIM-2 DNA methyltransferase in a Δcdp-2 background causes extensive genome disorder, as heterochromatic-euchromatic contacts increase despite additional H3K9me3 enrichment. Our results highlight how enhanced cytosine methylation ensures heterochromatic compartmentalization when silenced regions are acetylated.

Project description:Chromosomes must correctly fold in eukaryotic nuclei for proper genome function. Eukaryotic organisms hierarchically organize their genomes: in the fungus Neurospora crassa, chromatin fiber loops compact into Topologically Associated Domain (TAD)-like structures that are anchored by heterochromatic region aggregates. However, insufficient information exists on how histone post-translational modifications, including acetylation, impact genome organization. In Neurospora, the HCHC (HDA-1, CDP-2, HP1, CHAP) complex deacetylates heterochromatic regions including centromeres: loss of individual HCHC members increases centromeric acetylation and cytosine methylation. Here, we evaluate the role of the HCHC complex on genome organization using chromosome conformation capture with high-throughput sequencing (Hi-C) in Δcdp-2 or Δchap deletion strains. CDP-2 loss increases interactions between intra- and inter-chromosomal heterochromatic regions, while removal of CHAP decreases heterochromatic region compaction. Individual HCHC mutants exhibit different histone PTM patterns genome-wide: in Dcdp-2, heterochromatic H4K16 acetylation is increased, yet some heterochromatic regions lose H3K9 trimethylation, which locally increases inter-heterochromatin contacts; CHAP loss produces minimal acetylation changes but increases H3K9me3 enrichment in heterochromatin. Furthermore, deletion of the DIM-2 DNA methyltransferase in a Δcdp-2 background causes extensive genome disorder, as heterochromatic-euchromatic contacts increase despite additional H3K9me3 enrichment. Our results highlight how enhanced cytosine methylation ensures heterochromatic compartmentalization when silenced regions are acetylated.

Project description:Polycomb-repressive complex 1 (PRC1) has a constraining influence on 3D genome organization, mediating localized and chromosome-wide clustering of target loci. Polycomb-bound regions form transcriptionally repressive chromatin domains independent of topologically associating domains (TADs). Several subunits of PRC1 have the capacity to form biomolecular condensates through liquid-liquid phase separation (LLPS) in vitro and when tagged and over-expressed in cells. Here, we use 1,6 hexandiol (1,6-HD), which disrupts liquid-like condensates, to examine the role of endogenous PRC1 biomolecular condensates on local and chromosome-wide clustering of PRC1-bound loci. Using imaging and chromatin immunoprecipitation combined with deep sequencing (ChIP-seq) analyses, we show that PRC1-mediated localized chromatin compaction and clustering of targeted genomic loci at megabase and tens of megabase scales can be reversibly disrupted by the addition and subsequent removal of 1,6-HD to mouse embryonic stem cells (mESCs). Decompaction and dispersal of polycomb domains and clusters cannot be solely attributable to the reduction of PRC1 binding following 1,6-HD treatment as the addition of 2,5-HD has similar effects despite this alcohol not perturbing PRC1-mediated clustering, at least at the sub-megabase and megabase scales. These results suggest that weak, hydrophobic interactions between PRC1 molecules characteristic of liquid condensates do have a role in polycomb-mediated genome organization.

Project description:Eukaryotic genomes are folded into a hierarchy of three-dimensional structures that impact nuclear functions, including transcription, replication, and repair1-3. Studies in Drosophila and mammals have revealed megabase-sized topologically associated domains (TADs) within chromosomes, which in turn are spatially restricted within the nucleus4-8. However, little is known about local physical constraints that drive higher-order folding of chromosomes. Here we performed Hi-C analysis of the fission yeast Schizosaccharomyces pombe to explore genome organization at high resolution. S. pombe comprises a small genome ideal for examining structural features of chromatin folding, and contains fundamental components present in higher eukaryotes. Large domains of heterochromatin coat centromeres and telomeres and recruit cohesin, a ring-like protein complex that binds sister chromatids and mediates long range looping of interphase chromosomes. Our analyses reveal a highly ordered chromosome organization, consistent with a Rabl configuration, which is dependent on constraints imposed at centromeres and telomeres. We find that local chromatin compaction and cohesin recruitment to centromeres mediated by heterochromatin is required for maintaining global genome territorial restraint. In addition to larger complex domains, we also observed locally interacting regions of chromatin ~50 kilobases long, which organize chromosome arms into structures referred to as “globules”. Globule boundaries are enriched in cohesin and convergent gene orientation. The role of cohesin in maintaining globule domains is independent of its role in sister chromatid cohesion, as globule domains are also a feature of G1 chromosome architecture. Defect in cohesin disrupts globule domains and results in an altered chromosome organization at larger scales, including the loss of chromosome territories. Disruption of globules also affects functional annotation of the genome, leading to impairment of borders between neighboring transcriptional units. Our analyses reveal key features of chromatin organization and folding and show that distinct mechanisms uniquely impact the hierarchy of genome organization to protect genome integrity and to coordinate nuclear functions. Comparison of HiC contact maps under various conditions reveal fundamental principles of genome organization

Project description:Histones modulate gene expression by chromatin compaction, regulating numerous processes such as differentiation. However, the mechanisms underlying histone degradation remain elusive. When compared with their differentiated counterparts, immortal human embryonic stem cells (hESCs) have a unique chromatin architecture and low levels of trimethylated histone H3 at lysine 9 (H3K9me3), a heterochromatin-associated modification. Here we assess a link between the intrinsic epigenetic landscape and ubiquitin-proteasome system of hESCs. We find that hESCs exhibit high expression of UBE2K, a ubiquitin-conjugating enzyme. Loss of UBE2K increases the levels of H3K9 trimethyltransferase SETDB1, resulting in H3K9 trimethylation and repression of neurogenic genes during differentiation. Concomitantly, loss of UBE2K impairs the ability of hESCs to differentiate into neural progenitors with neurogenic properties. Besides H3K9 trimethylation, we find that UBE2K binds histone H3 to induce its polyubiquitination and degradation by the proteasome. Notably, ubc-20, the worm orthologue of UBE2K, also regulates both histone H3 levels and H3K9 trimethylation in C. elegans germline. Thus, our results indicate that UBE2K crosses evolutionary boundaries to promote histone H3 degradation and reduce H3K9me3 repressive marks in immortal cells.

Project description:Histones modulate gene expression by chromatin compaction, regulating numerous processes such as differentiation. However, the mechanisms underlying histone degradation remain elusive. When compared with their differentiated counterparts, immortal human embryonic stem cells (hESCs) have a unique chromatin architecture and low levels of trimethylated histone H3 at lysine 9 (H3K9me3), a heterochromatin-associated modification. Here we assess a link between the intrinsic epigenetic landscape and ubiquitin-proteasome system of hESCs. We find that hESCs exhibit high expression of UBE2K, a ubiquitin-conjugating enzyme. Loss of UBE2K increases the levels of H3K9 trimethyltransferase SETDB1, resulting in H3K9 trimethylation and repression of neurogenic genes during differentiation. Concomitantly, loss of UBE2K impairs the ability of hESCs to differentiate into neural progenitors with neurogenic properties. Besides H3K9 trimethylation, we find that UBE2K binds histone H3 to induce its polyubiquitination and degradation by the proteasome. Notably, ubc-20, the worm orthologue of UBE2K, also regulates both histone H3 levels and H3K9 trimethylation in C. elegans germline. Thus, our results indicate that UBE2K crosses evolutionary boundaries to promote histone H3 degradation and reduce H3K9me3 repressive marks in immortal cells.

Project description:Eukaryotic genomes are folded into three-dimensional structures that govern diverse hromosomal procsses. Studeis in Drosophila and mammals have revealed large self-associating tomological domains whose borders are enriched in cohesin/CTCF factors that are required for long-range intrations. However, mechanisms governing higher-order folding of chromatin fivbers and the exact function of cohesin in this process remain poor understood. Here we perform Hi-C to explore the organization of the Schizosaccharomyces pombe genome at high-resolution, which despite its small size comprises fundamental features found in higher eukaryotes. Our analyses reveal that in addition to determinants of Rabl-like chromosome architecture, smaller locally interacting regions of chromatin, referred to as globules, are a distinctive features of S. pombe chromosome organization. This feature of chromatin architecture requires a function of cohesin distinct from its role in sister chromatid cohesion. Cohesin is enriched at globule boundaries and its loss causes disruption of local globule structure and global chromosome territories. Heterochromatin, which selectively loads cohesin at specific loci including pericentromric and subtelomeric domains, is dispensable for globule formation but uniquely impacts genome organization through chromatin compaction by enforcing Rabl configuration. microarray CGH analysis in mutant fission yeast cell; Copy number change in rad21-K1 were examined by comparative genomic hybridization analysis.

Project description:Recent studies have shown that repressive chromatin machinery, including DNA methyltransferases (DNMTs) and Polycomb Repressor Complexes (PRCs), bind to chromosomes throughout mitosis and their depletion results in increased chromosome size. Enzymes that catalyse H3K9 methylation, such as Suv39h1, Suv39h2, G9a, GLP are also retained by mitotic chromosomes. Surprisingly however, mutants lacking H3K9me3 have unusually small and compact mitotic chromosomes that are associated with increased H3S10ph and H3K27me3 levels. Chromosome size and centromere compaction in these mutants was rescued by providing exogenous Suv39h1, or inhibiting Ezh2 activity. Quantitative proteomic comparisons of native mitotic chromosomes isolated from wildtype versus Suv39h1,2 double null ESCs revealed that H3K9me3 was essential for the efficient retention of bookmarking factors such as Esrrb. These results highlight an unexpected role for repressive heterochromatin domains in preserving transcription factor binding through mitosis, and underscore the importance of H3K9me3 for sustaining chromosome architecture and epigenetic memory during cell division.

Project description:ChIP-chip analyses of Psc3 in wild-type and mutant fission yeast cells. Eukaryotic genomes are folded into three-dimensional structures that govern diverse hromosomal procsses. Studeis in Drosophila and mammals have revealed large self-associating tomological domains whose borders are enriched in cohesin/CTCF factors that are required for long-range intrations. However, mechanisms governing higher-order folding of chromatin fivbers and the exact function of cohesin in this process remain poor understood. Here we perform Hi-C to explore the organization of the Schizosaccharomyces pombe genome at high-resolution, which despite its small size comprises fundamental features found in higher eukaryotes. Our analyses reveal that in addition to determinants of Rabl-like chromosome architecture, smaller locally interacting regions of chromatin, referred to as globules, are a distinctive features of S. pombe chromosome organization. This feature of chromatin architecture requires a function of cohesin distinct from its role in sister chromatid cohesion. Cohesin is enriched at globule boundaries and its loss causes disruption of local globule structure and global chromosome territories. Heterochromatin, which selectively loads cohesin at specific loci including pericentromric and subtelomeric domains, is dispensable for globule formation but uniquely impacts genome organization through chromatin compaction by enforcing Rabl configuration. Genome-wide distribution of Psc3 were determined by ChIP-chip analysis in wild-type and mutant fission yeast cells.

Project description:Detailed genomic contact maps have revealed that chromosomes are composed of developmentally stable topologically associated domains (TADs) and more flexible sub-TADs. These domains reside in active and inactive nuclear compartments, but cause and consequence of compartmentalization are largely unknown. Here, we combined lacO/lacR binding platforms with allele-specific 4C technologies to track their precise position in the three-dimensional genome upon recruitment of NANOG, SUV39H1 or EZH2. We observed locked genomic loci resistant to spatial repositioning and unlocked loci that could be repositioned to different nuclear sub-compartments with distinct chromatin signatures. Focal protein recruitment caused the entire sub- TAD, but not surrounding regions, to engage in new genomic contacts. Compartment switching was uncoupled from gene expression changes and enzymatically modifying histones per se was insufficient for repositioning. Collectively this suggests that transassociated factors determine three-dimensional compartmentalization independent of their cis-effect on local chromatin composition and activity. 4C-seq was performed on a range of viewpoints in 129/Sv;C57BL/6 embryonic stem cells carying a lacO array in chromosome 8 and 11.