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大肠杆菌的RdgC蛋白可结合DNA，并对抗RecFOR在缺乏复制重启蛋白PriA的菌株中的毒性作用。

The RdgC protein of Escherichia coli binds DNA and counters a toxic effect of RecFOR in strains lacking the replication restart protein PriA.

作者信息

Moore Timothy, McGlynn Peter, Ngo Hien-Ping, Sharples Gary J, Lloyd Robert G

机构信息

Institute of Genetics, University of Nottingham, Queen's Medical Centre, Nottingham NG7 2UH, UK.

出版信息

EMBO J. 2003 Feb 3;22(3):735-45. doi: 10.1093/emboj/cdg048.

DOI:10.1093/emboj/cdg048

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC140733/

Abstract

PriA protein provides a means to load the DnaB replicative helicase at DNA replication fork and D loop structures, and is therefore a key factor in the rescue of stalled or broken forks and subsequent replication restart. We show that the nucleoid-associated RdgC protein binds non-specifically to single-stranded (ss) DNA and double-stranded DNA. It is also essential for growth of a strain lacking PriA, indicating that it might affect replication fork progression or fork rescue. dnaC suppressors of priA overcome this inviability, especially when RecF, RecO or RecR is inactivated, indicating that RdgC avoids or counters a toxic effect of these proteins. Mutations modifying ssDNA-binding (SSB) protein also negate this toxic effect, suggesting that the toxicity reflects inappropriate loading of RecA on SSB-coated ssDNA, leading to excessive or untimely RecA activity. We suggest that binding of RdgC to DNA limits RecA loading, avoiding problems at replication forks that would otherwise require PriA to promote replication restart. Mutations in RNA polymerase also reduce the toxic effect of RecFOR, providing a further link between DNA replication, transcription and repair.

摘要

PriA蛋白提供了一种在DNA复制叉和D环结构上加载DnaB复制解旋酶的方式，因此是挽救停滞或断裂的复制叉以及随后重新启动复制的关键因素。我们发现，类核相关的RdgC蛋白能非特异性地结合单链（ss）DNA和双链DNA。它对于缺乏PriA的菌株的生长也是必不可少的，这表明它可能会影响复制叉的推进或复制叉的挽救。priA的dnaC抑制子能克服这种不可生存性，尤其是当RecF、RecO或RecR失活时，这表明RdgC可避免或对抗这些蛋白的毒性作用。修饰单链DNA结合（SSB）蛋白的突变也能消除这种毒性作用，这表明这种毒性反映了RecA在SSB包被的单链DNA上的不适当加载，导致RecA活性过高或过早出现。我们认为，RdgC与DNA的结合限制了RecA的加载，避免了复制叉处出现问题，否则这些问题将需要PriA来促进复制重新启动。RNA聚合酶中的突变也会降低RecFOR的毒性作用，这进一步建立了DNA复制、转录和修复之间的联系。