Project description:The successful progression of a cell through the cell cycle requires the temporal regulation of many biological processes, including gene transcript levels and the number and condensation of chromosomes. Fission yeast (Schizosaccharomyces pombe) is a paradigm for cell cycle research and model for higher eukaryotic cells. Due to the small size of its genome, it is highly amenable to high resolution studies of the spatial organization of its genome. Here we present the results of a high resolution study in which we used synchronised S. pombe cells to investigate cell cycle phase dependent changes in genome organization and transcription patterns. We reveal cell cycle dependant changes in connections within and between chromosomes while confirming previously observed features of genome organization, such as telomere clustering. Our results show that chromosomes are effectively circular throughout the cell cycle and that they remain connected even during the M phase. Determining the structure and transcript levels for matched synchronized cells revealed: 1) that genes with high transcript levels are highly connected with the genome at specific stages of the cell cycle; and 2) that interactions have positive and negative effects on transcript levels. We hypothesize that the observed correlations between transcript levels and the formation and disruption of cell cycle specific chromosomal interactions implicate genome organization in epigenetic inheritance and bookmarking.

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:Global analyses of cell cycle dependent changes in fission yeast genome organization reveal correlations with alterations in transcript levels

Project description:Mitotic chromosomes are among the most recognizable structures in the cell, yet for over a century their internal organization remains largely unsolved. We applied chromosome conformation capture methods, 5C and Hi-C, across the cell cycle and revealed two alternative three-dimensional folding states of the human genome. We show that the highly compartmentalized and cell-type-specific organization described previously for non-synchronous cells is restricted to interphase. In metaphase, we identify a homogenous folding state, which is locus-independent, common to all chromosomes, and consistent among cell types, suggesting a general principle of metaphase chromosome organization. Using polymer simulations, we find that metaphase Hi-C data is inconsistent with classic hierarchical models, and is instead best described by a linearly-organized longitudinally compressed array of consecutive chromatin loops.

Project description:Global analyses of cell cycle dependent changes in fission yeast genome organization reveal correlations with alterations in transcript levels [GCC]

Project description:The duplication and segregation of chromosomes involve the dynamic re-organization of their internal structure by conserved architectural proteins, such as structural maintenance of chromosomes complexes (i.e., cohesin and condensin). Although the roles of these factors is actively investigated, a genome-wide view of chromosome dynamic architecture at both small and large-scales during cell division remains elusive. Here we report the first comprehensive 4D analysis of the Saccharomyces cerevisiae genome higher-order organization during the cell cycle, and investigate the roles of SMC in the observed structural transitions. During replication, cohesion establishment promotes long-range intra-chromosomal contacts and correlates with the individualization of chromosomes, which culminates at metaphase. Mitotic chromosomes are then abruptly reorganized in anaphase by mechanical forces exerted by the mitotic spindle. The formation of a condensin-dependent loop, that bridges the centromere cluster with the rDNA loci, suggests that condensin-mediated forces may also directly facilitate segregation. This work provides a comprehensive overview of chromosome dynamics during the cell cycle of a unicellular eukaryote that recapitulates and unveils new features of highly conserved stages of the cell division.

Project description:Global analyses of cell cycle dependent changes in fission yeast genome organization reveal correlations with alterations in transcript levels [RNA-Seq]

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.

Project description:<p>Aneuploidy causes system-wide disruptions in the stochiometric balances of transcripts, proteins, and metabolites, often resulting in detrimental effects for the organism. The protozoan parasite Leishmania has an unusually high tolerance for aneuploidy, but the molecular and functional consequences for the pathogen remain poorly understood. Here, we addressed this question in vitro and present the first integrated analysis of the genome, transcriptome, proteome, and metabolome of highly aneuploid Leishmania donovani strains. Our analyses unambiguously establish that aneuploidy in Leishmania proportionally impacts the average transcript- and protein abundance levels of affected chromosomes, ultimately correlating with the degree of metabolic differences between strains. This proportionality was present in both proliferative and non-proliferative in vitro promastigotes. However, protein complex subunits and non-cytoplasmic proteins, showed dosage compensation, responding less or even not at all to aneuploidy-induced dosage changes. In contrast to other Eukaryotes, we did not observe the widespread regulation at the transcript level that typically modulates some of the negative effects of aneuploidy. Further, the majority of differentially expressed proteins between aneuploid strains were encoded by non-aneuploid chromosomes and were not driven by a significant underlying transcript change, suggesting that aneuploidy is accompanied by extensive post-transcriptional protein-level modulation. This makes Leishmania a unique Eukaryotic model for elucidating post-transcriptional protein-abundance modulation in the context of aneuploidy.</p><p><br></p><p><strong>Data availability:</strong></p><p>Proteomic data associated with this study are available in the PRIDE repository: accession number <a href='https://www.ebi.ac.uk/pride/archive/projects/PXD028521' rel='noopener noreferrer' target='_blank'>PXD028521</a>.</p>

Project description:Spatial organization and gene expression of mammalian chromosomes are maintained and regulated in conjunction with cell cycle progression. This link is perturbed once cells enter senescence. The highly abundant HMGB1 protein, known to associate with bent and looped DNA, is actively depleted from senescent cell nuclei to act as an extracellular proinflammatory stimulus. Despite its physiological importance, we still lack understanding of the positioning and functional roles of HMGB1 on chromatin in vivo. To address this, we mapped HMGB1 binding genome-wide in different primary cells using a tailored protocol. We then integrated ChIP-seq and Hi-C data with a knot theory approach to uncover HMGB1 demarcation at the boundaries of particular topologically-associating domains (TADs). These TADs harbor genes involved in the key proinflammatory leg of the senescent transcriptional program. Moreover, we used sCLIP and siRNA-mediated knockdown to show that HMGB1 is a bona fide RNA-binding protein also affecting splicing choices. Together, our findings highlight a broader than hitherto assumed role for HMGB1 in chromatin homeostasis connected to cell cycle potency, and allow us to postulate a rheostat model for HMGB function with implications in cancer biology.