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Literature DB >> 29033319

Checkpoint Kinase Rad53 Couples Leading- and Lagging-Strand DNA Synthesis under Replication Stress.

Haiyun Gan¹, Chuanhe Yu², Sujan Devbhandari³, Sushma Sharma⁴, Junhong Han⁵, Andrei Chabes⁴, Dirk Remus⁶, Zhiguo Zhang⁷.

Abstract

The checkpoint kinase Rad53 is activated during replication stress to prevent fork collapse, an essential but poorly understood process. Here we show that Rad53 couples leading- and lagging-strand synthesis under replication stress. In rad53-1 cells stressed by dNTP depletion, the replicative DNA helicase, MCM, and the leading-strand DNA polymerase, Pol ε, move beyond the site of DNA synthesis, likely unwinding template DNA. Remarkably, DNA synthesis progresses further along the lagging strand than the leading strand, resulting in the exposure of long stretches of single-stranded leading-strand template. The asymmetric DNA synthesis in rad53-1 cells is suppressed by elevated levels of dNTPs in vivo, and the activity of Pol ε is compromised more than lagging-strand polymerase Pol δ at low dNTP concentrations in vitro. Therefore, we propose that Rad53 prevents the generation of excessive ssDNA under replication stress by coordinating DNA unwinding with synthesis of both strands.

Entities: Chemical Disease Gene Species

Keywords: ChIP-ssSeq; DNA replication checkpoint; Rad53; dNTP pools; eSPAN; fork collapse; lagging strand DNA synthesis; leading strand DNA synthesis

Mesh：

Substances：

Year: 2017 PMID： 29033319 PMCID： PMC5802358 DOI： 10.1016/j.molcel.2017.09.018

Source DB: PubMed Journal: Mol Cell ISSN： 1097-2765 Impact factor: 17.970

51 in total

1. DNA polymerase stabilization at stalled replication forks requires Mec1 and the RecQ helicase Sgs1.

Authors: Jennifer A Cobb; Lotte Bjergbaek; Kenji Shimada; Christian Frei; Susan M Gasser
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Review 2. The DNA damage response pathways: at the crossroad of protein modifications.

Authors: Michael S Y Huen; Junjie Chen
Journal: Cell Res Date: 2008-01 Impact factor: 25.617

3. ATR prohibits replication catastrophe by preventing global exhaustion of RPA.

Authors: Luis Ignacio Toledo; Matthias Altmeyer; Maj-Britt Rask; Claudia Lukas; Dorthe Helena Larsen; Lou Klitgaard Povlsen; Simon Bekker-Jensen; Niels Mailand; Jiri Bartek; Jiri Lukas
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Review 4. DNA replication and oncogene-induced replicative stress.

Authors: Stephanie A Hills; John F X Diffley
Journal: Curr Biol Date: 2014-05-19 Impact factor: 10.834

5. Fast gapped-read alignment with Bowtie 2.

Authors: Ben Langmead; Steven L Salzberg
Journal: Nat Methods Date: 2012-03-04 Impact factor: 28.547

6. Chromatin Constrains the Initiation and Elongation of DNA Replication.

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8. Regulation of DNA replication fork progression through damaged DNA by the Mec1/Rad53 checkpoint.

Authors: J A Tercero; J F Diffley
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Review 9. Causes and consequences of replication stress.

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10. Increased Rrm2 gene dosage reduces fragile site breakage and prolongs survival of ATR mutant mice.

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28 in total

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6. A mechanism for Rad53 to couple leading- and lagging-strand DNA synthesis under replication stress in budding yeast.

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7. High density of unrepaired genomic ribonucleotides leads to Topoisomerase 1-mediated severe growth defects in absence of ribonucleotide reductase.

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