Mapping the semi-nested community structure of 3D chromosome contact networks

Mammalian DNA folds into 3D structures that facilitate and regulate genetic processes such as transcription, DNA repair, and epigenetics. Several insights derive from chromosome capture methods, such as Hi-C, which allow researchers to construct contact maps depicting 3D interactions among all DNA s...

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Veröffentlicht in:	PLoS computational biology 2023-07, Vol.19 (7), p.e1011185-e1011185
Hauptverfasser:	Bernenko, Dolores, Lee, Sang Hoon, Stenberg, Per, Lizana, Ludvig
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Analysis Animals Biology and Life Sciences Chromatin Chromatin - genetics Chromatin Assembly and Disassembly Chromosomes Chromosomes - genetics Community structure Compartments Deoxyribonucleic acid DNA DNA - genetics DNA repair Empirical analysis Epigenesis, Genetic Epigenetic inheritance Epigenetics Folding Fractals Gene mapping Genetic aspects Genetic transcription Hypotheses Localization Mammals - genetics Nesting Phase separation Physical sciences Physiological aspects Pollinators Research and Analysis Methods Structure
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creator	Bernenko, Dolores Lee, Sang Hoon Stenberg, Per Lizana, Ludvig
description	Mammalian DNA folds into 3D structures that facilitate and regulate genetic processes such as transcription, DNA repair, and epigenetics. Several insights derive from chromosome capture methods, such as Hi-C, which allow researchers to construct contact maps depicting 3D interactions among all DNA segment pairs. These maps show a complex cross-scale organization spanning megabase-pair compartments to short-ranged DNA loops. To better understand the organizing principles, several groups analyzed Hi-C data assuming a Russian-doll-like nested hierarchy where DNA regions of similar sizes merge into larger and larger structures. Apart from being a simple and appealing description, this model explains, e.g., the omnipresent chequerboard pattern seen in Hi-C maps, known as A/B compartments, and foreshadows the co-localization of some functionally similar DNA regions. However, while successful, this model is incompatible with the two competing mechanisms that seem to shape a significant part of the chromosomes' 3D organization: loop extrusion and phase separation. This paper aims to map out the chromosome's actual folding hierarchy from empirical data. To this end, we take advantage of Hi-C experiments and treat the measured DNA-DNA interactions as a weighted network. From such a network, we extract 3D communities using the generalized Louvain algorithm. This algorithm has a resolution parameter that allows us to scan seamlessly through the community size spectrum, from A/B compartments to topologically associated domains (TADs). By constructing a hierarchical tree connecting these communities, we find that chromosomes are more complex than a perfect hierarchy. Analyzing how communities nest relative to a simple folding model, we found that chromosomes exhibit a significant portion of nested and non-nested community pairs alongside considerable randomness. In addition, by examining nesting and chromatin types, we discovered that nested parts are often associated with active chromatin. These results highlight that cross-scale relationships will be essential components in models aiming to reach a deep understanding of the causal mechanisms of chromosome folding.
doi_str_mv	10.1371/journal.pcbi.1011185
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Several insights derive from chromosome capture methods, such as Hi-C, which allow researchers to construct contact maps depicting 3D interactions among all DNA segment pairs. These maps show a complex cross-scale organization spanning megabase-pair compartments to short-ranged DNA loops. To better understand the organizing principles, several groups analyzed Hi-C data assuming a Russian-doll-like nested hierarchy where DNA regions of similar sizes merge into larger and larger structures. Apart from being a simple and appealing description, this model explains, e.g., the omnipresent chequerboard pattern seen in Hi-C maps, known as A/B compartments, and foreshadows the co-localization of some functionally similar DNA regions. However, while successful, this model is incompatible with the two competing mechanisms that seem to shape a significant part of the chromosomes' 3D organization: loop extrusion and phase separation. This paper aims to map out the chromosome's actual folding hierarchy from empirical data. To this end, we take advantage of Hi-C experiments and treat the measured DNA-DNA interactions as a weighted network. From such a network, we extract 3D communities using the generalized Louvain algorithm. This algorithm has a resolution parameter that allows us to scan seamlessly through the community size spectrum, from A/B compartments to topologically associated domains (TADs). By constructing a hierarchical tree connecting these communities, we find that chromosomes are more complex than a perfect hierarchy. Analyzing how communities nest relative to a simple folding model, we found that chromosomes exhibit a significant portion of nested and non-nested community pairs alongside considerable randomness. In addition, by examining nesting and chromatin types, we discovered that nested parts are often associated with active chromatin. 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subjects	Algorithms Analysis Animals Biology and Life Sciences Chromatin Chromatin - genetics Chromatin Assembly and Disassembly Chromosomes Chromosomes - genetics Community structure Compartments Deoxyribonucleic acid DNA DNA - genetics DNA repair Empirical analysis Epigenesis, Genetic Epigenetic inheritance Epigenetics Folding Fractals Gene mapping Genetic aspects Genetic transcription Hypotheses Localization Mammals - genetics Nesting Phase separation Physical sciences Physiological aspects Pollinators Research and Analysis Methods Structure
title	Mapping the semi-nested community structure of 3D chromosome contact networks
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