A 3D Map of the Human Genome at Kilobase Resolution Reveals Principles of Chromatin Looping

SummaryWe use in situ Hi-C to probe the 3D architecture of genomes, constructing haploid and diploid maps of nine cell types. The densest, in human lymphoblastoid cells, contains 4.9 billion contacts, achieving 1 kb resolution. We find that genomes are partitioned into contact domains (median length, 185 kb), which are associated with distinct patterns of histone marks and segregate into six subcompartments. We identify ∼10,000 loops. These loops frequently link promoters and enhancers, correlate with gene activation, and show conservation across cell types and species. Loop anchors typically occur at domain boundaries and bind CTCF. CTCF sites at loop anchors occur predominantly (>90%) in a convergent orientation, with the asymmetric motifs “facing” one another. The inactive X chromosome splits into two massive domains and contains large loops anchored at CTCF-binding repeats.PaperFlic

Juicer Provides a One-Click System for Analyzing Loop-Resolution Hi-C Experiments

Hi-C experiments explore the 3D structure of the genome, generating terabases of data to create high-resolution contact maps. Here, we introduce Juicer, an open-source tool for analyzing terabase-scale Hi-C datasets. Juicer allows users without a computational background to transform raw sequence data into normalized contact maps with one click. Juicer produces a hic file containing compressed contact matrices at many resolutions, facilitating visualization and analysis at multiple scales. Structural features, such as loops and domains, are automatically annotated. Juicer is available as open source software at http://aidenlab.org/juicer/.National Institutes of Health (U.S.) (New Innovator Award 1DP2OD008540)National Science Foundation (U.S.) Physics Frontier Center (Grant PHY-1427654)National Human Genome Research Institute (U.S.) (Grant HG006193)Robert A. Welch Foundation (Grant Q-1866)Cancer Prevention and Research Institute of Texas (Scholar Award R1304)NVIDIA Corporation (Research Center Award)IBM (University Challenge Award)Google (Research Award)Baylor College of Medicine (McNair Medical Institute Scholar Award)National Human Genome Research Institute (U.S.) (Grant HG003067)National Institutes of Health (U.S.) (4D Nucleome Grant U01HL130010

Cohesin Loss Eliminates All Loop Domains

The human genome folds to create thousands of intervals, called “contact domains,” that exhibit enhanced contact frequency within themselves. “Loop domains” form because of tethering between two loci—almost always bound by CTCF and cohesin—lying on the same chromosome. “Compartment domains” form when genomic intervals with similar histone marks co-segregate. Here, we explore the effects of degrading cohesin. All loop domains are eliminated, but neither compartment domains nor histone marks are affected. Loss of loop domains does not lead to widespread ectopic gene activation but does affect a significant minority of active genes. In particular, cohesin loss causes superenhancers to co-localize, forming hundreds of links within and across chromosomes and affecting the regulation of nearby genes. We then restore cohesin and monitor the re-formation of each loop. Although re-formation rates vary greatly, many megabase-sized loops recovered in under an hour, consistent with a model where loop extrusion is rapid. Mapping the nucleome in 4D during cohesin loss and recovery reveals that cohesin degradation eliminates loop domains but has only modest transcriptional consequences. Keywords: cohesion; genome architecture; loop extrusion; chromatin loops; superenhancers; gene regulation; nuclear compartments; Hi-C; 4D Nucleome; CTC

Walking along chromosomes with super-resolution imaging, contact maps, and integrative modeling

Chromosome organization is crucial for genome function. Here, we present a method for visualizing chromosomal DNA at super-resolution and then integrating Hi-C data to produce three-dimensional models of chromosome organization. Using the super-resolution microscopy methods of OligoSTORM and OligoDNA-PAINT, we trace 8 megabases of human chromosome 19, visualizing structures ranging in size from a few kilobases to over a megabase. Focusing on chromosomal regions that contribute to compartments, we discover distinct structures that, in spite of considerable variability, can predict whether such regions correspond to active (A-type) or inactive (B-type) compartments. Imaging through the depths of entire nuclei, we capture pairs of homologous regions in diploid cells, obtaining evidence that maternal and paternal homologous regions can be differentially organized. Finally, using restraint-based modeling to integrate imaging and Hi-C data, we implement a method-integrative modeling of genomic regions (IMGR)-to increase the genomic resolution of our traces to 10 kb.This work was supported by funds from Ministerio de Ciencia, Innovación y Universidades of Spain (http://www.ciencia.gob.es/) (IJCI-2015-23352) to IF, Damon Runyon Cancer Research Foundation (https://www.damonrunyon.org/) and Howard Hughes Medical Institute (https://www.hhmi.org/) to BJB, Uehara Memorial Foundation Research (https://www.taisho-holdings.co.jp/en/environment/social/sciences/) to HMS, William Randolph Hearst Foundation (https://www.hearstfdn.org/) to RBM, EMBO (Long-Term fellowship) (https://www.embo.org/) to JE, NSF (Center for Theoretical Biological Physics, Rice University) (https://www.nsf.gov/) to MDP and JNO, NSF (CCF-1054898, CCF-1317291) (https://www.nsf.gov/), NIH (1R01EB018659-01, 1-U01- MH106011-01) (https://www.nih.gov/), and Office of Naval Research (N00014-13-1-0593, N00014-14-1-0610, N00014-16-1-2182, N00014-16-1- 2410) (https://www.onr.navy.mil/) to PY, NIH (1DP2OD008540, U01HL130010, UM1HG009375, 4DP2OD008540) (https://www.nih.gov/), NSF (PHY-1427654) (https://www.nsf.gov/), USDA (2017-05741) (https://www.usda.gov/), Welch Foundation (Q-1866) (http://www.welch1.org/), NVIDIA (https://www.nvidia.com/en-us/), IBM (https://www.ibm.com/us-en/?lnk=m), Google (https://www.google.com/), Cancer Prevention Research Institute of Texas (R1304) (http://www.cprit.state.tx.us/), and McNair Medical Institute (http://www.mcnairfoundation.org/what-we-fund/mcnair-medical-institute/) to E.L.A., Horizon 2020 Research and Innovation Programme (676556) (https://ec.europa.eu/programmes/horizon2020/en/), European Research Council (609989) (https://erc.europa.eu/), Ministerio de Ciencia, Innovación y Universidades of Spain (BFU2017-85926-P) (http://www.ciencia.gob.es/), CERCA, and AGAUR Programme of the Generalitat de Catalunya and Centros de Excelencia Severo Ochoa (SEV-2012-0208) (http://www.ciencia.gob.es/portal/site/MICINN/menuitem.7eeac5cd345b4f34f09dfd1001432ea0/?vgnextoid=cba733a6368c2310VgnVCM1000001d04140aRCRD) to M.A.M-R., and NIH (5DP1GM106412, R01HD091797, R01GM123289) (https://www.nih.gov/) to C-tW. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript

Spatially clustered loci with multiple enhancers are frequent targets of HIV-1 integration

HIV-1 recurrently targets active genes and integrates in the proximity of the nuclear pore compartment in CD4+ T cells. However, the genomic features of these genes and the relevance of their transcriptional activity for HIV-1 integration have so far remained unclear. Here we show that recurrently targeted genes are proximal to super-enhancer genomic elements and that they cluster in specific spatial compartments of the T cell nucleus. We further show that these gene clusters acquire their location during the activation of T cells. The clustering of these genes along with their transcriptional activity are the major determinants of HIV-1 integration in T cells. Our results provide evidence of the relevance of the spatial compartmentalization of the genome for HIV-1 integration, thus further strengthening the role of nuclear architecture in viral infection.This work was supported by German Center for Infection Research (DZIF) Thematic Translational Unit HIV-1 04.704 Infrastructural Measure to M.L. and by the Hector Grant M70 “HiPNose: HiV Positioning in the Nuclear Space” to M.L. and M.S. We acknowledge the financial support of the Spanish Ministry of Economy and Competitiveness (“Centro de Excelencia Severo Ochoa 2013–2017,” Plan Nacional BFU2012–37168), of the CERCA (Centres de Recerca de Catalunya) Programme/Generalitat de Catalunya, and of the European Research Council (Synergy Grant 609989). K.V. and M.K. are supported by the European Structural and Investment Funds grant for the Croatian National Centre of Research Excellence in Personalized Healthcare (contract #KK.01.1.1.01.0010), Croatian National Centre of Research Excellence for Data Science and Advanced Cooperative Systems (contract KK.01.1.1.01.0009), and Croatian Science Foundation (grant IP-2014–09–6400)