Control of inducible gene expression links cohesin to hematopoietic progenitor self-renewal and differentiation

Cuartero, Sergi; Weiss, Felix D.; Dharmalingam, Gopuraja; Guo, Ya; Ing-Simmons, Elizabeth; Masella, Silvia; Robles-Rebollo, Irene; Xiao, Xiaolin; Wang, Yi Fang; Barozzi, Iros; Djeghloul, Dounia; Amano, Mariane Tami; Niskanen, Henri; Petretto, Enrico; Dowell, Robin D.; Tachibana, Kikuë; Kaikkonen, Minna U.; Nasmyth, K; Lenhard, Boris; Natoli, Gioacchino; Fisher, Amanda G.; Merkenschlager, Matthias

doi:10.1038/s41590-018-0184-1

Cited by 177 publications

(199 citation statements)

References 88 publications

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“…Consistent with a role for cohesin in shaping gene regulatory architecture, its depletion prevents adequate activation of inducible genes (Cuartero et al, 2018). Surprisingly however, steady-state gene expression levels are less affected upon architectural protein depletion (Busslinger et al, 2017;Haarhuis et al, 2017;Nora et al, 2017;Rao et al, 2017;Schwarzer et al, 2017;Seitan et al, 2013;Sofueva et al, 2013).…”

Section: Introductionmentioning

confidence: 84%

“…However, the fact that many interactions with active enhancers are retained upon architectural protein depletion, and only a small number of contacts are gained in these conditions, may explain why this perturbation does not have a more pronounced effect on steady-state transcription. How can these observations be reconciled with the requirement for cohesin for gene induction (Cuartero et al, 2018) and lineagespecific gene regulation (Liu et al, 2019)? One possibility is that in non-transcriptionally-permissive chromatin contexts, cohesin/CTCF-independent promoter contacts are unable to form in the absence of some prior activation events, such as chromatin decompaction of the locus or establishment of appropriate chromosomal conformation.…”

Section: Discussionmentioning

confidence: 99%

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Cohesin-dependent and independent mechanisms support chromosomal contacts between promoters and enhancers

Thiecke

Wutz

Muhar

et al. 2020

Preprint

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It is currently assumed that 3D chromosomal organisation plays a central role in transcriptional control. However, recent evidence shows that steady-state transcription of only a minority of genes is affected by depletion of architectural proteins such as cohesin and CTCF. Here, we have used Capture Hi-C to interrogate the dynamics of chromosomal contacts of all human gene promoters upon rapid architectural protein degradation. We show that promoter contacts lost in these conditions tend to be long-range, with at least one interaction partner localising in the vicinity of topologically associated domain (TAD) boundaries. In contrast, many shorter-range chromosomal contacts, particularly those that connect active promoters with each other and with active enhancers remain unaffected by cohesin and CTCF depletion. We demonstrate that the effects of cohesin depletion on nascent transcription can be explained by changes in the connectivity of their enhancers. Jointly, these results provide a mechanistic explanation to the limited, but consistent effects of cohesin and CTCF on steady-state transcription and point towards the existence of alternative enhancer-promoter pairing mechanisms that are independent of these proteins.

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Section: Introductionmentioning

confidence: 84%

Section: Discussionmentioning

confidence: 99%

Cohesin-dependent and independent mechanisms support chromosomal contacts between promoters and enhancers

Thiecke

Wutz

Muhar

et al. 2020

Preprint

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“…Additionally, the loss of interphase chromosome structure in vertebrates by loss of cohesin SMC complexes can affect gene expression ( e.g. , (Bompadre and Andrey, 2019;Cuartero et al, 2018;Delaneau et al, 2019;Lupiáñez et al, 2015;Merkenschlager and Nora, 2016;Nora et al, 2017;Rao et al, 2017;Schoenfelder and Fraser, 2019;Schwarzer et al, 2017;Seitan et al, 2013) ). Similarly, mutations that perturb cohesin or condensin can lead to human developmental / disorders, such as Cornelia de Lange syndrome (de Lange, 1933) and microcephaly (Martin et al, 2016) .…”

Section: Discussionmentioning

confidence: 99%

Chromosome organization by one-sided and two-sided loop extrusion

Banigan

Berg

Brandão

et al. 2019

Preprint

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AbstractSMC complexes, such as condensin or cohesin, organize chromatin throughout the cell cycle by a process known as loop extrusion. SMC complexes reel in DNA, extruding and progressively growing DNA loops. Modeling assuming two-sided loop extrusion reproduces key features of chromatin organization across different organisms. In vitro single-molecule experiments confirmed that yeast condensins extrude loops, however, they remain anchored to their loading sites and extrude loops in a “one-sided” manner. We therefore simulate one-sided loop extrusion to investigate whether “one-sided” complexes can compact mitotic chromosomes, organize interphase domains, and juxtapose bacterial chromosomal arms, as can be done by “two-sided” loop extruders. While one-sided loop extrusion cannot reproduce these phenomena, variants can recapitulate in vivo observations. We predict that SMC complexes in vivo constitute effectively two-sided motors or exhibit biased loading and propose relevant experiments. Our work suggests that loop extrusion is a viable general mechanism of chromatin organization.Impact statementWe reconcile seemingly contradictory findings of single-molecule and in vivo experiments on a major mechanism of chromosome organization by computationally investigating mechanisms of loop extrusion that are consistent with both.

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“…To test this, we asked whether experimental cleavage of cohesin could significantly alter the structure of isolated chromosomes. Cohesin complexes are composed of Smc1, Smc3, the kleisin Scc1, and one of three auxillary subunits 13 and are required to keep sister chromatids together from DNA replication until mitosis, as well having roles in interphase genome organisation, gene transcription and DNA repair [12][13][14][15][16][17] . Proteomic analysis (Figure 1i and S1c) indicate that components of the cohesin complex bind mitotic chromosomes in different cell types 25,55,56 and are dynamically regulated so that the majority of cohesin dissociates from chromosome arms during prophase.…”

Section: Isolated Metaphase Chromosomes Are Sensitive To In Situ Cohementioning

confidence: 99%

“…While these interactions differ from those at interphase, it seems likely that at least some factors mediating local chromatin condensation during interphase might have similar or related roles in mitosis. The cohesin complex, for example, is required to keep newly replicated sister chromatids in close physical proximity during S/G2 to M phases of the cell cycle, but can also modulate interphase gene expression through local enhancer-promoter contact [12][13][14][15][16][17] .…”

Section: Introductionmentioning

confidence: 99%

Systematic identification of factors bound to isolated metaphase ESC chromosomes reveals a role for chromatin repressors in compaction

Djeghloul

A-C.

Patel

et al. 2019

Preprint

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Epigenetic information is transmitted from mother to daughter cells through mitosis. To identify trans-acting factors and cis-acting elements that might be important for conveying epigenetic memory through cell division, we isolated native (unfixed) chromosomes from metaphasearrested cells using flow cytometry and performed LC-MS/MS to determine the repertoire of chromosome-bound proteins. Quantitative proteomic comparisons between metaphasearrested cell lysates and chromosome-sorted samples revealed a cohort of proteins that were significantly enriched on mitotic ESC chromosomes. These include pluripotency-associated transcription factors, repressive chromatin-modifiers (such as PRC2 and DNA methyltransferases) and proteins governing chromosome architecture. We showed that deletion of PRC2, DNMT1/3a/3b or Mecp2 provoked an increase in the size of individual mitotic chromosomes consistent with de-condensation, as did experimental cleavage of cohesin complexes. These data provide a comprehensive inventory of chromosome-bound factors in pluripotent stem cells at mitosis and reveal an unexpected role for chromatin repressor complexes in preserving mitotic chromosome compaction.

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Control of inducible gene expression links cohesin to hematopoietic progenitor self-renewal and differentiation

Cited by 177 publications

References 88 publications

Cohesin-dependent and independent mechanisms support chromosomal contacts between promoters and enhancers

Cohesin-dependent and independent mechanisms support chromosomal contacts between promoters and enhancers

Chromosome organization by one-sided and two-sided loop extrusion

Systematic identification of factors bound to isolated metaphase ESC chromosomes reveals a role for chromatin repressors in compaction

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