Project description:Mammalian genomes are organized into distinct chromatin structures, which include small-scale nucleosome arrays and large-scale topologically associating domains (TADs). The mechanistic interplay between chromatin structures across scales is poorly understood. Here, we investigate how changes in nucleosome architecture impact TAD organization by studying the role of the histone chaperone facilitates chromatin transcription (FACT) in 3D genome organization. We show that FACT depletion perturbs TADs, causing decreased insulation and weaker CTCF loops. These changes in TAD structure cannot be attributed to changes in chromatin occupancy of CTCF or cohesin and occur specifically in transcribed regions of the genome where we observe perturbed nucleosome organization in absence of FACT. FACT depletion therefore allows us to separate the role of CTCF binding from nucleosome architecture and to demonstrate that the organization of nucleosomes at TAD boundaries directly contributes to TAD formation.

Project description:FACT mediates cohesin function on chromatin Cohesin is a key regulator of genome architecture with roles in sister chromatid cohesion and the organisation of higher-order structures during interphase and mitosis. The recruitment and mobility of cohesin complexes on DNA are restricted by nucleosomes. Here we show that cohesin role in chromosome organization requires the histone chaperone FACT. Depletion of FACT in metaphase cells affects cohesin stability on chromatin reducing its accumulation at pericentric regions and binding on chromosome arms. Using Hi-C, we show that cohesin-dependent TAD (Topological Associated Domains)-like structures in G1 and metaphase chromosomes are disrupted in the absence of FACT. Surprisingly, sister chromatid cohesion is intact in FACT-depleted cells, although chromosome segregation failure is observed. Our results uncover a role for FACT in genome organisation by facilitating cohesin dependent compartmentalization of chromosomes into loop domains.

Project description:Serum response factor (SRF) is a transcription factor essential for cell proliferation, differentiation, and migration, and is required for primitive streak and mesoderm formation in the embryo. The canonical roles of SRF are mediated by a diverse set of context-dependent cofactors. Here we show that SRF physically interacts with CTCF and cohesin subunits at TAD boundaries and loop anchors. SRF reinforces the insulation of TADs and promotes the formation of long-range chromatin loops. In ES cells, SRF associates with Oct4, Sox2, and Nanog and contributes to the formation of 3D pluripotency hubs. Our findings reveal new roles of SRF in higher-order chromatin organization.

Project description:Chromatin organization and cell cycle are tightly intertwined in eukaryotes, but the underlying mechanisms remain unclear. We investigated how the retinoblastoma protein (RB), a key cell cycle regulator, influences chromatin architecture. Chromosome conformation capture assays reveal that RB loss increases the number and size of cohesin-dependent loops and strengthens topologically associating domains (TADs). RB shows extensive colocalization with cohesin in the human genome, and it impacts cohesin’s distribution on chromatin. Active RB evicted cohesin from RB-bound TAD boundaries, repressed insulator activity, and enhanced the expression of non-E2F target genes that are important for cell adhesion. We conclude that RB has a central role in the interplay between cell cycle and chromatin organization. This role safeguards chromatin architecture and controls transcription.

Project description:This SuperSeries is composed of the SubSeries listed below, and presents the high throuput sequencing datasets that were generated as part of a larger study that investigates the role of CTCF and cohesin as key drivers of 3D-nuclear organization, anchoring the megabase-scale Topologically Associating Domains (TADs) that segment the genome. This study presents and validates a computational method to predict cohesin-and-CTCF binding sites that form intra-TAD DNA loops. The intra-TAD loop anchors identified are structurally indistinguishable from TAD anchors regarding binding partners, sequence conservation, and resistance to cohesin knockdown; further, the intra-TAD loops retain key functional features of TADs, including chromatin contact insulation, blockage of repressive histone mark spread, and ubiquity across tissues. The intra-TAD loops are proposed to be formed by the same loop extrusion mechanism as the larger TAD loops; their shorter length enables finer regulatory control in restricting enhancer-promoter interactions, which enables selective, high-level expression of gene targets of super-enhancers and genes located within repressive nuclear compartments. These findings elucidate the role of intra-TAD cohesin-and-CTCF binding in nuclear organization associated with widespread insulation of distal enhancer activity.

Project description:Whereas folding of mammalian genomes at the large scale of epigenomic compartments and topologically associating domains (TADs) is now relatively well-understood, how chromatin is folded below this scale remains largely unexplored in mammals. Here, we overcome this limitation using a high-resolution 3C-based method, Micro-C, and probe the links between 3D-genome organization and transcriptional regulation in mouse stem cells. Combinatorial binding of transcription factors, cofactors, and chromatin modifiers spatially segregate TAD regions into various finer-scale structures with distinct regulatory features (i.e. stripes, dots, and domains linking promoter-promoter (P-P) or enhancer-promoter (E-P), and bundle contacts between Polycomb regions). E-P stripes extending from the edge of domains predominantly link co-expressed loci, often independently of CTCF and cohesin occupancy. Acute inhibition of transcription disrupts the gene-related folding features without altering higher-order chromatin structures. Analysis of ligation events sheds light on both the putative loop extrusion model and the “two-start” zig-zag 30-nanometer model of the chromatin fiber. Our work uncovers the finer-scale genome organization that establishes novel functional links between chromatin folding and gene regulation.

Project description:Recent advances enabled by Hi-C technique have unraveled principles of chromosomal folding, which were since linked to many genomic processes. In particular, Hi-C revealed that chromosomes of animals are organized into Topologically Associating Domains (TADs), evolutionary conserved compact chromatin domains that influence gene expression. However, mechanisms that underlie partitioning of the genome into TADs remain poorly understood. To explore principals of TAD folding in Drosophila melanogaster, we performed Hi-C and PolyA+ RNA-seq in four cell lines of various origins (S2, Kc167, DmBG3-c2, and OSC). Contrary to previous studies, we find that regions between TADs (i.e. the inter-TADs and TAD boundaries) in Drosophila are only weakly enriched with the insulator protein dCTCF, while another insulator protein Su(Hw) is preferentially present within TADs. However, Drosophila inter-TADs harbor active chromatin and constitutively transcribed (housekeeping) genes. Accordingly, we find that binding of insulator proteins dCTCF and Su(Hw) predict TAD boundaries much worse than the active chromatin marks (in the minimal case, H3K4me3 and total RNA) do. Moreover, inter-TADs correspond to decompacted interbands of polytene chromosomes, whereas TADs mostly correspond to densely packed bands. Collectively, our results suggest that TADs are condensed chromatin domains depleted in active chromatin marks, separated by regions of active chromatin that cannot be organized into compact structures, possibly due to high levels of histone acetylation. Finally, we test this hypothesis by polymer simulations, and find that TAD partitioning can be explained by different modes of inter-nucleosomal interactions for active and inactive chromatin. Hi-C experiments, PolyA+ RNA profiling and mapping of chromosomal rearrangements in four Drosophila melanogaster cell lines.

Project description:The molecular mechanisms underlying folding of mammalian chromosomes remain poorly understood. The transcription factor CTCF is a candidate regulator of chromosomal structure. Using the auxin-inducible degron system in mouse embryonic stem cells, we show that CTCF is absolutely and dose-dependently required for looping between CTCF target sites and insulation of topologically associating domains (TADs). Restoring CTCF reinstates proper architecture on altered chromosomes, indicating a powerful instructive function for CTCF in chromatin folding. CTCF remains essential for TAD organization in non-dividing cells. Surprisingly, active and inactive genome compartments remain properly segregated upon CTCF depletion, revealing that compartmentalization of mammalian chromosomes emerges independently of proper insulation of TADs. Further, our data support that CTCF mediates transcriptional insulator function through enhancer-blocking but not direct facultative heterochromatin barrier activity. Beyond defining the functions of CTCF in chromosome folding these results provide new fundamental insights into the rules governing mammalian genome organization.

Project description:Here we show that HNRNPU, the major nuclear matrix attachment factor, is necessary to maintain proper nuclear architecture in mouse hepatocytes. Upon HNRNPU depletion, the interactions between chromatin and nuclear lamina have been changed dramatically；chromatin organization is globally changed; boundaries of topologically associating domains (TADs) become weaker; inter-TAD interactions are increased; thousands of genes are significantly altered coincident with 3D chromatin changes. Mechanically, HNRNPU interacts with CTCF and RAD21, which affects the binding of RAD21 to the chromatin significantly, whereas CTCF bindings are almost unchanged, what’ more, the decrease of binding strengths are highly correlated with the weakness of loop bounded by Rad21. Taken together, we identify HNRNPU as a key regulator of chromatin architecture, and our data suggest the importance of nuclear matrix associating factors in 3D genome organization.

Project description:Mammalian genomes are organized into megabase-scale topologically associated domains (TADs) that have been proposed to represent large regulatory units. Here we demonstrate that disruption of TADs can cause rewiring of long-range regulatory architecture and result in pathogenic phenotypes. We show that distinct human limb malformations are caused by deletions, inversions, or duplications altering the structure of the TAD-spanning WNT6/IHH/EPHA4/PAX3 locus. Using CRISPR/Cas genome editing, we generated mice with corresponding rearrangements. Both in mouse limb tissue and patient-derived fibroblasts, disease-relevant structural changes cause ectopic interactions between promoters and non-coding DNA, and a cluster of limb enhancers normally associated with Epha4 is misplaced relative to TAD boundaries and drives ectopic limb expression of another gene in the locus. Our results demonstrate the functional importance of TADs for orchestrating gene expression via genome architecture and indicate criteria for predicting the pathogenicity of human structural variants, particularly in non-coding regions of the human genome. RNA-seq profile of developing distal limbs of mutants and WT animals at E11.5