The second decade of 3C technologies: detailed insights into nuclear organization

Denker, Annette; Laat, Wouter de

doi:10.1101/gad.281964.116

Cited by 306 publications

(245 citation statements)

References 217 publications

(282 reference statements)

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“…Chromosome conformation capture (3C) based methods, particularly high-throughput 3C (Hi-C), have enabled targeted or genome-wide mapping of chromatin architectures (Denker and De Laat 2016). These technologies provided critical insights into key structural and functional components of three-dimensional chromatin organization such as i) A/B compartments (Lieberman-aiden et al 2009), also referred to as compartment domains (Rao et al 2017), which are closely associated with open and closed chromatin domains, respectively; ii) topologically associating domains (TADs) (Dixon et al 2012;Nora et al 2012;Sexton et al 2012), also referred to as contact domains (Rao et al 2017), chromosomal units that spatially constrain cis-regulatory interactions; iii) CTCF loops, also referred to as insulated neighborhoods (Hnisz et al 2016) or loop domains (Rao et al 2017).…”

Section: Introductionmentioning

confidence: 99%

Thrombopoietin signaling to chromatin elicits rapid and pervasive epigenome remodeling within poised chromatin architectures

et al. 2018

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Thrombopoietin (TPO) is a critical cytokine regulating hematopoietic stem cell maintenance and differentiation into the megakaryocytic lineage. However, the transcriptional and chromatin dynamics elicited by TPO signaling are poorly understood. Here, we study the immediate early transcriptional and cis-regulatory responses to TPO in hematopoietic stem/progenitor cells (HSPCs) and use this paradigm of cytokine signaling to chromatin to dissect the relation between cisregulatory activity and chromatin architecture. We show that TPO profoundly alters the transcriptome of HSPCs, with key hematopoietic regulators being transcriptionally repressed within 30 minutes of TPO. By examining cis-regulatory dynamics and chromatin architectures, we demonstrate that these changes are accompanied by rapid and extensive epigenome remodeling of cis-regulatory landscapes that is spatially coordinated within topologically associating domains (TADs). Moreover, TPO-responsive enhancers are spatially clustered and engage in preferential homotypic intra-and inter-TAD interactions that are largely refractory to TPO signaling. By further examining the link between cis-regulatory dynamics and chromatin looping, we show that rapid modulation of cis-regulatory activity is largely independent of chromatin looping dynamics. Finally, we show that, although activated and repressed cis-regulatory elements share remarkably similar DNA sequence compositions, transcription factor binding patterns accurately predict rapid cis-regulatory responses to TPO.

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Section: Introductionmentioning

confidence: 99%

Thrombopoietin signaling to chromatin elicits rapid and pervasive epigenome remodeling within poised chromatin architectures

et al. 2018

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“…Furthermore, these enhancer-promoter physical interactions occur in a highly regulated manner that precludes spurious activation of non-target neighboring genes. We have now a first glimpse of how animal genomes are folded thanks to the use of several chromosome conformation capture techniques that identify DNA-DNA contacts throughout the genome (reviewed in [2]). Over the last years, the analyses of all possible contacts between a single genomic region and the rest of the genome at high resolution (4C-seq), or between all chromatin regions at low resolution (Hi-C), have shown that chromatin is compartmentalized into structures known as topologically associating domains (TADs): megabase-scale genomic regions in which sequences preferentially contact one another [3][4][5][6].…”

Section: Introductionmentioning

confidence: 99%

Cis-regulatory landscapes in development and evolution

Maeso

Acemel

Gómez-Skármeta

2017

Current Opinion in Genetics & Development

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The recent advances in our understanding of the 3D organization of the chromatin together with an almost unlimited ability to detect cis-regulatory elements genome-wide using different biochemical signatures has provided us with an unprecedented power to study gene regulation. It is now possible to profile the complete regulatory apparatus controlling the spatio-temporal expression of any given gene, the so-called gene Regulatory Landscapes (RLs). Here we review several studies over the last two years demonstrating the functional consequences of altering RL structure in development, disease and evolution. These works clearly shows that a deep understanding of transcriptional regulation is no longer conceivable without considering the 3D modular organization of animal genomes.

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“…Recent advances in proximity-ligation and deep-sequencing technologies have enabled the interrogation of genome organization at a genomewide scale and nucleosome resolution (de Laat and Dekker 2012;Denker and de Laat 2016). Within individual chromosomes, open chromatin and active genes tend to spatially cluster into "A" compartments, whereas closed, inactive chromatin spatially segregates into "B" compartments (Lieberman-Aiden et al 2009;Rao et al 2014).…”

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confidence: 99%

YY1 and CTCF orchestrate a 3D chromatin looping switch during early neural lineage commitment

et al. 2017

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CTCF is an architectural protein with a critical role in connecting higher-order chromatin folding in pluripotent stem cells. Recent reports have suggested that CTCF binding is more dynamic during development than previously appreciated. Here, we set out to understand the extent to which shifts in genome-wide CTCF occupancy contribute to the 3D reconfiguration of fine-scale chromatin folding during early neural lineage commitment. Unexpectedly, we observe a sharp decrease in CTCF occupancy during the transition from naï ve/primed pluripotency to multipotent primary neural progenitor cells (NPCs). Many pluripotency gene-enhancer interactions are anchored by CTCF, and its occupancy is lost in parallel with loop decommissioning during differentiation. Conversely, CTCF binding sites in NPCs are largely preexisting in pluripotent stem cells. Only a small number of CTCF sites arise de novo in NPCs. We identify another zinc finger protein, Yin Yang 1 (YY1), at the base of looping interactions between NPC-specific genes and enhancers. Putative NPC-specific enhancers exhibit strong YY1 signal when engaged in 3D contacts and negligible YY1 signal when not in loops. Moreover, siRNA knockdown of Yy1 specifically disrupts interactions between key NPC enhancers and their target genes. YY1-mediated interactions between NPC regulatory elements are often nested within constitutive loops anchored by CTCF. Together, our results support a model in which YY1 acts as an architectural protein to connect developmentally regulated looping interactions; the location of YY1-mediated interactions may be demarcated in development by a preexisting topological framework created by constitutive CTCF-mediated interactions.

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The second decade of 3C technologies: detailed insights into nuclear organization

Cited by 306 publications

References 217 publications

Thrombopoietin signaling to chromatin elicits rapid and pervasive epigenome remodeling within poised chromatin architectures

Thrombopoietin signaling to chromatin elicits rapid and pervasive epigenome remodeling within poised chromatin architectures

Cis-regulatory landscapes in development and evolution

YY1 and CTCF orchestrate a 3D chromatin looping switch during early neural lineage commitment

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