Project description:Chromatin loops are a major componant of 3D nuclear organization that appear as intense point-to-point interactions in Hi-C maps. Identification of these loops is an important part of Hi-C analysis. We present SIP, Significant Interaction Peak caller, a platform independent program to identify these loops in a time and memory efficient manner and which is resistant to noise and sequencing depth. We also present a companion tool, SIPMeta, to create more visually accurate average plots of Hi-C and HiChIP data. We then demonstrate that use of SIP and SIPMeta can lead to biological insight through characterizing the contribution of several transcription factors to CTCF loops in human cells. We then use SIP and SIPMeta to discover loops associated with condensin IDCC in C. elegans and confirm these loops by HiChIP. These loops form a network of interactions and likely explain the partial condensation of dosage compensated X chromosomes in hermaphrodites.

Project description:Mechanisms of X chromosome dosage compensation have been studied extensively in a few model species representing clades of shared sex chromosome ancestry. However, the diversity within each clade as a function of sex chromosome evolution is largely unknown. Here, we anchor ourselves to the nematode Caenorhabditis elegans, for which a well-studied mechanism of dosage compensation occurs through a specialized structural maintenance of chromosomes (SMC) complex, and explore the diversity of dosage compensation in the surrounding phylogeny of nematodes. Through phylogenetic analysis of the C. elegans dosage compensation complex and a survey of its epigenetic signatures, including X-specific topologically associating domains (TADs) and X-enrichment of H4K20me1, we found that the condensin-mediated mechanism evolved recently in the lineage leading to Caenorhabditis through an SMC-4 duplication. Intriguingly, an independent duplication of SMC-4 and the presence of X-specific TADs in Pristionchus pacificus suggest that condensin-mediated dosage compensation arose more than once. mRNA-seq analyses of gene expression in several nematode species indicate that dosage compensation itself is ancestral, as expected from the ancient XO sex determination system. Indicative of the ancestral mechanism, H4K20me1 is enriched on the X chromosomes in Oscheius tipulae, which does not contain X-specific TADs or SMC-4 paralogs. Together, our results indicate that the dosage compensation system in C. elegans is surprisingly new, and condensin may have been co-opted repeatedly in nematodes, suggesting that the process of evolving a chromosome-wide gene regulatory mechanism for dosage compensation is constrained.

Project description:Mechanisms of X chromosome dosage compensation have been studied extensively in a few model species representing clades of shared sex chromosome ancestry. However, the diversity within each clade as a function of sex chromosome evolution is largely unknown. Here, we anchor ourselves to the nematode Caenorhabditis elegans, for which a well-studied mechanism of dosage compensation occurs through a specialized structural maintenance of chromosomes (SMC) complex, and explore the diversity of dosage compensation in the surrounding phylogeny of nematodes. Through phylogenetic analysis of the C. elegans dosage compensation complex and a survey of its epigenetic signatures, including X-specific topologically associating domains (TADs) and X-enrichment of H4K20me1, we found that the condensin-mediated mechanism evolved recently in the lineage leading to Caenorhabditis through an SMC-4 duplication. Intriguingly, an independent duplication of SMC-4 and the presence of X-specific TADs in Pristionchus pacificus suggest that condensin-mediated dosage compensation arose more than once. mRNA-seq analyses of gene expression in several nematode species indicate that dosage compensation itself is ancestral, as expected from the ancient XO sex determination system. Indicative of the ancestral mechanism, H4K20me1 is enriched on the X chromosomes in Oscheius tipulae, which does not contain X-specific TADs or SMC-4 paralogs. Together, our results indicate that the dosage compensation system in C. elegans is surprisingly new, and condensin may have been co-opted repeatedly in nematodes, suggesting that the process of evolving a chromosome-wide gene regulatory mechanism for dosage compensation is constrained.

Project description:The three-dimensional (3D) organization of a genome plays a critical role in regulating gene expression, yet little is known about the machinery and mechanisms that determine higher-order chromosome structure or how structure influences gene expression. Here we exploit the X-chromosome-wide process of dosage compensation to dissect these mechanisms. The dosage compensation complex (DCC) of C. elegans, a condensin complex, binds to both X chromosomes of hermaphrodites via sequence-specific recruitment sites (rex sites) to reduce chromosome-wide gene expression by half. Using genome-wide chromosome conformation capture and single-cell FISH to compare chromosome structure in wild-type and DCC-defective embryos (DC mutants), we show that the DCC remodels X chromosomes of hermaphrodites into a spatial conformation distinct from autosomes. The dosage-compensated X chromosomes are composed of Topologically Associating Domains (TADs) that have sharper boundaries and more regular spacing than TADs on autosomes. Most TAD boundaries on X coincide with the highest-affinity rex sites, and these boundaries are lost or diminished in DC mutants, thereby restoring the topology of X to a native conformation resembling that of autosomes. Although most rex sites engage in multiple strong DCC-dependent long-range interactions, the strongest interactions occur between rex sites at the DCC-dependent TAD boundaries. We propose the DCC actively shapes the topology of the entire X chromosome by forming new TAD boundaries and reinforcing pre-existing weak TAD boundaries through interactions between its highest affinity sites. Such changes in higher-order X-chromosome structure then influence gene expression over long distances.

Project description:The three-dimensional (3D) organization of a genome plays a critical role in regulating gene expression, yet little is known about the machinery and mechanisms that determine higher-order chromosome structure or how structure influences gene expression. Here we exploit the X-chromosome-wide process of dosage compensation to dissect these mechanisms. The dosage compensation complex (DCC) of C. elegans, a condensin complex, binds to both X chromosomes of hermaphrodites via sequence-specific recruitment sites (rex sites) to reduce chromosome-wide gene expression by half. Using genome-wide chromosome conformation capture and single-cell FISH to compare chromosome structure in wild-type and DCC-defective embryos (DC mutants), we show that the DCC remodels X chromosomes of hermaphrodites into a spatial conformation distinct from autosomes. The dosage-compensated X chromosomes are composed of Topologically Associating Domains (TADs) that have sharper boundaries and more regular spacing than TADs on autosomes. Most TAD boundaries on X coincide with the highest-affinity rex sites, and these boundaries are lost or diminished in DC mutants, thereby restoring the topology of X to a native conformation resembling that of autosomes. Although most rex sites engage in multiple strong DCC-dependent long-range interactions, the strongest interactions occur between rex sites at the DCC-dependent TAD boundaries. We propose the DCC actively shapes the topology of the entire X chromosome by forming new TAD boundaries and reinforcing pre-existing weak TAD boundaries through interactions between its highest affinity sites. Such changes in higher-order X-chromosome structure then influence gene expression over long distances.

Project description:The three-dimensional (3D) organization of a genome plays a critical role in regulating gene expression, yet little is known about the machinery and mechanisms that determine higher-order chromosome structure or how structure influences gene expression. Here we exploit the X-chromosome-wide process of dosage compensation to dissect these mechanisms. The dosage compensation complex (DCC) of C. elegans, a condensin complex, binds to both X chromosomes of hermaphrodites via sequence-specific recruitment sites (rex sites) to reduce chromosome-wide gene expression by half. Using genome-wide chromosome conformation capture and single-cell FISH to compare chromosome structure in wild-type and DCC-defective embryos (DC mutants), we show that the DCC remodels X chromosomes of hermaphrodites into a spatial conformation distinct from autosomes. The dosage-compensated X chromosomes are composed of Topologically Associating Domains (TADs) that have sharper boundaries and more regular spacing than TADs on autosomes. Most TAD boundaries on X coincide with the highest-affinity rex sites, and these boundaries are lost or diminished in DC mutants, thereby restoring the topology of X to a native conformation resembling that of autosomes. Although most rex sites engage in multiple strong DCC-dependent long-range interactions, the strongest interactions occur between rex sites at the DCC-dependent TAD boundaries. We propose the DCC actively shapes the topology of the entire X chromosome by forming new TAD boundaries and reinforcing pre-existing weak TAD boundaries through interactions between its highest affinity sites. Such changes in higher-order X-chromosome structure then influence gene expression over long distances.

Project description:Gene dosage imbalance of heteromorphic sex chromosomes (XY or ZW) exists between the sexes, and with the autosomes. Mammalian X chromosome inactivation was long thought to imply a critical need for dosage compensation in vertebrates. However, mRNA abundance measurements that demonstrated sex chromosome transcripts are neither balanced between the sexes or with autosomes in monotreme mammals or birds brought sex chromosome dosage compensation into question. This study examines transcriptomic and proteomic levels of dosage compensation in platypus and chicken compared to mouse, a model eutherian species. We analyzed mRNA and protein levels in heart and liver tissues of chicken, mouse and platypus.

Project description:In Caenorhabditis elegans, the dosage compensation complex (DCC) specifically binds to and represses transcription from both X chromosomes in hermaphrodites. The DCC is composed of an X-specific condensin complex that interacts with several proteins. During embryogenesis, DCC starts localizing to the X chromosomes around the 40-cell stage, and is followed by X-enrichment of H4K20me1 between 100-cell to comma stage. Here, we analyzed dosage compensation of the X chromosome between sexes, and the roles of dpy-27 (condensin subunit), dpy-21 (non-condensin DCC member), set-1 (H4K20 monomethylase) and set-4 (H4K20 di-/tri-methylase) in X chromosome repression using mRNA-seq and ChIP-seq analyses across several developmental time points. We found that the DCC starts repressing the X chromosomes by the 40-cell stage, but X-linked transcript levels remain significantly higher in hermaphrodites compared to males through the comma stage of embryogenesis. Dpy-27 and dpy-21 are required for X chromosome repression throughout development, but particularly in early embryos dpy-27 and dpy-21 mutations produced distinct expression changes, suggesting a DCC independent role for dpy-21. We previously hypothesized that the DCC increases H4K20me1 by reducing set-4 activity on the X chromosomes. Accordingly, in the set-4 mutant, H4K20me1 increased more from the autosomes compared to the X, equalizing H4K20me1 level between X and autosomes. H4K20me1 increase on the autosomes led to a slight repression, resulting in a relative effect of X derepression. H4K20me1 depletion in the set-1 mutant showed greater X derepression compared to equalization of H4K20me1 levels between X and autosomes in the set-4 mutant, indicating that H4K20me1 level is important, but X to autosomal balance of H4K20me1 contributes only slightly to X-repression. Thus H4K20me1 by itself is not a downstream effector of the DCC. In summary, X chromosome dosage compensation starts in early embryos as the DCC localizes to the X, and is strengthened in later embryogenesis by H4K20me1.

Project description:Mechanisms establishing higher-order chromosome structures and their roles in gene regulation are elusive. We analyzed chromosome architecture during nematode X-chromosome dosage compensation, which represses transcription via a dosage-compensation condensin complex (DCC) that binds hermaphrodite Xs and establishes megabase-size topologically associating domains (TADs). We show that DCC binding at high-occupancy sites (rex sites) defines eight TAD boundary locations. Single rex deletions disrupted boundaries, and single insertions created new boundaries, demonstrating one rex site is necessary and sufficient for DCC-dependent boundary formation. Deleting eight rex sites (8rexΔ) recapitulated TAD structure of DCC mutants, permitting analysis when chromosome-wide domain architecture was disrupted but most DCC binding remained. 8rexΔ animals exhibited no changes in X expression and lacked dosage-compensation mutant phenotypes. Hence, TAD boundaries are neither the cause nor consequence of gene repression during dosage compensation. Abrogating TAD structure did, however, reduce thermotolerance, accelerate aging, and shorten lifespan, implicating chromosome architecture in regulating stress responses and aging.

Project description:Mechanisms establishing higher-order chromosome structures and their roles in gene regulation are elusive. We analyzed chromosome architecture during nematode X-chromosome dosage compensation, which represses transcription via a dosage-compensation condensin complex (DCC) that binds hermaphrodite Xs and establishes megabase-size topologically associating domains (TADs). We show that DCC binding at high-occupancy sites (rex sites) defines eight TAD boundary locations. Single rex deletions disrupted boundaries, and single insertions created new boundaries, demonstrating one rex site is necessary and sufficient for DCC-dependent boundary formation. Deleting eight rex sites (8rexΔ) recapitulated TAD structure of DCC mutants, permitting analysis when chromosome-wide domain architecture was disrupted but most DCC binding remained. 8rexΔ animals exhibited no changes in X expression and lacked dosage-compensation mutant phenotypes. Hence, TAD boundaries are neither the cause nor consequence of gene repression during dosage compensation. Abrogating TAD structure did, however, reduce thermotolerance, accelerate aging, and shorten lifespan, implicating chromosome architecture in regulating stress responses and aging.