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DNA double-strand breaks induce H2Ax phosphorylation domains in a contact-dependent manner

by Collins, Patrick L. , Sleckman, Barry P. , Bednarski, Jeffrey J. , Bassing, Craig H. , Purman, Caitlin , Porter, Sofia I. , Oltz, Eugene M. , Saini, Ankita , Gurewitz, Greer L. , Nganga, Vincent , Hayer, Katharina E.

in 13/106 / 13/109 / 45/15 / 45/22 / 45/29 / 631/250/2502/2170 / 631/337/100/101 / 631/337/1427/2191 / Animals / Cell Line, Transformed / Chromatin / Chromatin - metabolism / Chromosome rearrangements / Deoxyribonucleic acid / DNA / DNA Breaks, Double-Stranded / DNA Damage / DNA Repair / Domains / Double-strand break repair / Genomes / Histone H2A / Histones / Histones - metabolism / Humanities and Social Sciences / Mice / multidisciplinary / Phosphorylation / Repair / Science / Science (multidisciplinary) / Yeast

2020

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DNA double-strand breaks induce H2Ax phosphorylation domains in a contact-dependent manner

2020

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DNA double-strand breaks induce H2Ax phosphorylation domains in a contact-dependent manner

2020

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Journal Article

DNA double-strand breaks induce H2Ax phosphorylation domains in a contact-dependent manner

Collins, Patrick L.,

Sleckman, Barry P.,

Bednarski, Jeffrey J.,

Bassing, Craig H.,

Purman, Caitlin,

Porter, Sofia I.,

Oltz, Eugene M.,

Saini, Ankita,

Gurewitz, Greer L.,

Nganga, Vincent,

Hayer, Katharina E.

2020

Overview

Efficient repair of DNA double-strand breaks (DSBs) requires a coordinated DNA Damage Response (DDR), which includes phosphorylation of histone H2Ax, forming γH2Ax. This histone modification spreads beyond the DSB into neighboring chromatin, generating a DDR platform that protects against end disassociation and degradation, minimizing chromosomal rearrangements. However, mechanisms that determine the breadth and intensity of γH2Ax domains remain unclear. Here, we show that chromosomal contacts of a DSB site are the primary determinants for γH2Ax landscapes. DSBs that disrupt a topological border permit extension of γH2Ax domains into both adjacent compartments. In contrast, DSBs near a border produce highly asymmetric DDR platforms, with γH2Ax nearly absent from one broken end. Collectively, our findings lend insights into a basic DNA repair mechanism and how the precise location of a DSB may influence genome integrity. Formation of γH2Ax serves as a checkpoint for double-strand break (DSB) repair pathways. Here the authors reveal via integrated chromatin analysis that γH2Ax domains are established by chromosomal contacts with the DSB site.

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Publisher

Nature Publishing Group UK,Nature Publishing Group,Nature Portfolio

Subject

13/106

/ 13/109

/ 45/15

/ 45/22

/ 45/29

/ 631/250/2502/2170

/ 631/337/100/101