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Replication fork stalling elicits chromatin compaction for the stability of stalling replication forks.


ABSTRACT: DNA replication forks in eukaryotic cells stall at a variety of replication barriers. Stalling forks require strict cellular regulations to prevent fork collapse. However, the mechanism underlying these cellular regulations is poorly understood. In this study, a cellular mechanism was uncovered that regulates chromatin structures to stabilize stalling forks. When replication forks stall, H2BK33, a newly identified acetylation site, is deacetylated and H3K9 trimethylated in the nucleosomes surrounding stalling forks, which results in chromatin compaction around forks. Acetylation-mimic H2BK33Q and its deacetylase clr6-1 mutations compromise this fork stalling-induced chromatin compaction, cause physical separation of replicative helicase and DNA polymerases, and significantly increase the frequency of stalling fork collapse. Furthermore, this fork stalling-induced H2BK33 deacetylation is independent of checkpoint. In summary, these results suggest that eukaryotic cells have developed a cellular mechanism that stabilizes stalling forks by targeting nucleosomes and inducing chromatin compaction around stalling forks. This mechanism is named the "Chromsfork" control: Chromatin Compaction Stabilizes Stalling Replication Forks.

SUBMITTER: Feng G 

PROVIDER: S-EPMC6642376 | biostudies-literature | 2019 Jul

REPOSITORIES: biostudies-literature

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Replication fork stalling elicits chromatin compaction for the stability of stalling replication forks.

Feng Gang G   Yuan Yue Y   Li Zeyang Z   Wang Lu L   Zhang Bo B   Luo Jiechen J   Ji Jianguo J   Kong Daochun D  

Proceedings of the National Academy of Sciences of the United States of America 20190701 29


DNA replication forks in eukaryotic cells stall at a variety of replication barriers. Stalling forks require strict cellular regulations to prevent fork collapse. However, the mechanism underlying these cellular regulations is poorly understood. In this study, a cellular mechanism was uncovered that regulates chromatin structures to stabilize stalling forks. When replication forks stall, H2BK33, a newly identified acetylation site, is deacetylated and H3K9 trimethylated in the nucleosomes surrou  ...[more]

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