Formation of new chromatin domains determines pathogenicity of genomic duplications

Franke, Martin; Ibrahim, Daniel M.; Andrey, Guillaume; Schwarzer, Wibke; Heinrich, Verena; Schöpflin, Robert; Kraft, Katerina; Kempfer, Rieke; Jerković, Ivana; Chan, Wing Lee; Spielmann, Malte; Timmermann, Bernd; Wittler, Lars; Kurth, Ingo; Cambiaso, Paola; Zuffardi, Orsetta; Houge, Gunnar; Lambie, Lindsay; Brancati, Francesco; Pombo, Ana; Vingron, Martin; Spitz, François; Mundlos, Stefan

doi:10.1038/nature19800

Cited by 583 publications

(573 citation statements)

References 37 publications

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“…Irrespective of the mechanisms underlying their formation, genetic evidence suggests that TADs contribute to establish correct interaction patterns between enhancers and promoters (Symmons et al 2014;Lupiáñez et al 2015;Franke et al 2016). Consistent with this, transcriptional coregulation of neighboring genes is favored within TADs during differentiation (Nora et al 2012) and upon transcriptional responses to external stimuli (Le Dily et al 2014).…”

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confidence: 66%

“…Several studies have provided evidence on the fundamental role of compartmentalization into TADs to instruct enhancer-promoter communication (Nora et al 2012;Symmons et al 2014;Lupiáñez et al 2015;Franke et al 2016), but they remain elusive on what makes TADs 'special' compared to other chromosomal folding layers, such as sub-TADs and notably contact domains or meta-TADs. In this study, we present a new domain-calling algorithm that is able to segment Hi-C interaction maps into nested sets of The number of sublevels in a domain correlates with the transcriptional activity within the domain (shown for domains at 65% RI in ESC).…”

Section: Discussionmentioning

confidence: 99%

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Reciprocal insulation analysis of Hi-C data shows that TADs represent a functionally but not structurally privileged scale in the hierarchical folding of chromosomes

et al. 2017

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Understanding how regulatory sequences interact in the context of chromosomal architecture is a central challenge in biology. Chromosome conformation capture revealed that mammalian chromosomes possess a rich hierarchy of structural layers, from multi-megabase compartments to sub-megabase topologically associating domains (TADs) and sub-TAD contact domains. TADs appear to act as regulatory microenvironments by constraining and segregating regulatory interactions across discrete chromosomal regions. However, it is unclear whether other (or all) folding layers share similar properties, or rather TADs constitute a privileged folding scale with maximal impact on the organization of regulatory interactions. Here, we present a novel algorithm named CaTCH that identifies hierarchical trees of chromosomal domains in Hi-C maps, stratified through their reciprocal physical insulation, which is a single and biologically relevant parameter. By applying CaTCH to published Hi-C data sets, we show that previously reported folding layers appear at different insulation levels. We demonstrate that although no structurally privileged folding level exists, TADs emerge as a functionally privileged scale defined by maximal boundary enrichment in CTCF and maximal cell-type conservation. By measuring transcriptional output in embryonic stem cells and neural precursor cells, we show that the likelihood that genes in a domain are coregulated during differentiation is also maximized at the scale of TADs. Finally, we observe that regulatory sequences occur at genomic locations corresponding to optimized mutual interactions at the same scale. Our analysis suggests that the architectural functionality of TADs arises from the interplay between their ability to partition interactions and the specific genomic position of regulatory sequences.

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confidence: 66%

Section: Discussionmentioning

confidence: 99%

Reciprocal insulation analysis of Hi-C data shows that TADs represent a functionally but not structurally privileged scale in the hierarchical folding of chromosomes

et al. 2017

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“…As TADs and CDs likely represent orthogonal measures of the same structural units, we use the term TADs unless specifically referring to published data sets employing the CD approach. Topological constraints imposed by TADs favor looping interactions to cis-regulatory element:gene pairings within the same TAD (Lupianez et al 2015;Franke et al 2016;Hnisz et al 2016). However, a higher level of genome organization also occurs where multiple TADs many megabase pairs distal on one chromosome or on different chromosomes can be adjacent and share a functional state (Lieberman-Aiden et al 2009).…”

Section: [Supplemental Materials Is Available For This Article]mentioning

confidence: 99%

Constrained release of lamina-associated enhancers and genes from the nuclear envelope during T-cell activation facilitates their association in chromosome compartments

et al. 2017

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The 3D organization of the genome changes concomitantly with expression changes during hematopoiesis and immune activation. Studies have focused either on lamina-associated domains (LADs) or on topologically associated domains (TADs), defined by preferential local chromatin interactions, and chromosome compartments, defined as higher-order interactions between TADs sharing functionally similar states. However, few studies have investigated how these affect one another. To address this, we mapped LADs using Lamin B1-DamID during Jurkat T-cell activation, finding significant genome reorganization at the nuclear periphery dominated by release of loci frequently important for T-cell function. To assess how these changes at the nuclear periphery influence wider genome organization, our DamID data sets were contrasted with TADs and compartments. Features of specific repositioning events were then tested by fluorescence in situ hybridization during T-cell activation. First, considerable overlap between TADs and LADs was observed with the TAD repositioning as a unit. Second, A1 and A2 subcompartments are segregated in 3D space through differences in proximity to LADs along chromosomes. Third, genes and a putative enhancer in LADs that were released from the periphery during T-cell activation became preferentially associated with A2 subcompartments and were constrained to the relative proximity of the lamina. Thus, lamina associations influence internal nuclear organization, and changes in LADs during T-cell activation may provide an important additional mode of gene regulation.

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“…Understanding how enhancers 20 regulate gene expression is therefore essential to understand how organisms develop and function throughout life. In fact, disruption of enhancer function has been shown to lead to abnormal gene expression and thus to diseases [4][5][6][7][8] . In addition, the majority of variants identified in Genome Wide Association Studies (GWAS) are found outside coding sequences 9,10 .…”

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confidence: 99%

Enhancer-gene maps in the human and zebrafish genomes using evolutionary linkage conservation

Clément

Torbey

Gilardi-Hebenstreit

et al. 2018

Preprint

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Gene regulation by enhancer sequences controls the spatiotemporal expression of target genes, often over long genomic distances. Current methods used to identify these interactions in the human genome require complex experimental setups and are restricted to specific cell types. Here we use PEGASUS, an approach that captures evolutionary signals 5 of synteny conservation to predict such interaction potentially in any biological context. We apply it to the human and zebrafish genomes and exploit the 1.3 million human and 55,000 zebrafish enhancers that we predicted to uncover fundamental principles of gene enhancer function in vertebrates. We show that the number of enhancers linked to a gene positively correlates with expression breadth in space and time and that the enhancer-target distance 10 is evolutionarily neutral. We uncover almost 2000 regulatory interactions ancestral to vertebrates, which are strongly enriched in core developmental processes. Using PEGASUS and its evolutionary view of enhancer-gene interactions, we provide a highly complementary resource to functional assays which uncovers key principles of enhancer biology.

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Formation of new chromatin domains determines pathogenicity of genomic duplications

Cited by 583 publications

References 37 publications

Reciprocal insulation analysis of Hi-C data shows that TADs represent a functionally but not structurally privileged scale in the hierarchical folding of chromosomes

Reciprocal insulation analysis of Hi-C data shows that TADs represent a functionally but not structurally privileged scale in the hierarchical folding of chromosomes

Constrained release of lamina-associated enhancers and genes from the nuclear envelope during T-cell activation facilitates their association in chromosome compartments

Enhancer-gene maps in the human and zebrafish genomes using evolutionary linkage conservation

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