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大肠杆菌K-12中组成型稳定DNA复制过程中复制重启蛋白的要求。

Requirements for replication restart proteins during constitutive stable DNA replication in Escherichia coli K-12.

作者信息

Sandler Steven J

机构信息

Department of Microbiology, University of Massachusetts, Amherst, 01003, USA.

出版信息

Genetics. 2005 Apr;169(4):1799-806. doi: 10.1534/genetics.104.036962. Epub 2005 Feb 16.

DOI:10.1534/genetics.104.036962
PMID:15716497
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1449598/
Abstract

Constitutive stable DNA replication (cSDR) is a mechanism for replisome loading in Escherichia coli K-12. This occurs in a dnaA-independent fashion in an rnhA mutant. cSDR is dependent on recA, priA, and transcription. In this report, it is shown that dnaA rnhA mutants using cSDR for initiation of their DNA replication additionally require priB, but not priC, for viability. Two subtle priA missense mutations either eliminated the ability to grow using cSDR (priA301 C479Y) or resulted in very small colonies (priA300 K230R). DnaC809, a priA suppressor, failed to allow priA or priB mutants to grow using cSDR to initiate DNA replication. Furthermore, unlike dnaC(+) strains, dnaC809 strains require priC for cSDR. DnaC809,820, a priC-independent suppressor of priA2::kan phenotypes, allowed priA and priC (but not priB) mutants to grow using cSDR to initiate DNA replication. It is also shown that rep and rnhA mutations are synthetically lethal. DnaC809 and dnaC809,820 mutations suppress this lethality. Rep is further shown to be required for cSDR in a dnaC809 strain. A model whereby these different sets of replication restart proteins interact preferentially with substrates associated with either RecA or SSB during replication restart and cSDR, respectively, is proposed.

摘要

组成型稳定DNA复制(cSDR)是大肠杆菌K-12中复制体加载的一种机制。这在rnhA突变体中以不依赖DnaA的方式发生。cSDR依赖于RecA、PriA和转录。在本报告中,研究表明,使用cSDR起始DNA复制的dnaA rnhA突变体在生存能力方面还需要PriB,但不需要PriC。两个细微的PriA错义突变要么消除了使用cSDR生长的能力(priA301 C479Y),要么导致菌落非常小(priA300 K230R)。PriA抑制子DnaC809不能使PriA或PriB突变体利用cSDR起始DNA复制来生长。此外,与dnaC(+)菌株不同,dnaC809菌株的cSDR需要PriC。PriA2::kan表型的不依赖PriC的抑制子DnaC809,820能使PriA和PriC(但不是PriB)突变体利用cSDR起始DNA复制来生长。研究还表明,rep和rnhA突变是合成致死的。DnaC809和dnaC809,820突变可抑制这种致死性。进一步研究表明,在dnaC809菌株中,cSDR需要Rep。本文提出了一个模型,即在复制重启和cSDR过程中,这些不同组的复制重启蛋白分别优先与与RecA或SSB相关的底物相互作用。

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