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叉形回归是噬菌体T4中一种由解旋酶驱动的活跃途径。

Fork regression is an active helicase-driven pathway in bacteriophage T4.

作者信息

Long David T, Kreuzer Kenneth N

机构信息

Department of Biochemistry, Duke University Medical Center, Box 3711, Durham, North Carolina 27710, USA.

出版信息

EMBO Rep. 2009 Apr;10(4):394-9. doi: 10.1038/embor.2009.13. Epub 2009 Mar 6.

DOI:10.1038/embor.2009.13
PMID:19270717
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2672904/
Abstract

Reactivation of stalled replication forks requires specialized mechanisms that can recognize the fork structure and promote downstream processing events. Fork regression has been implicated in several models of fork reactivation as a crucial processing step that supports repair. However, it has also been suggested that regressed forks represent pathological structures rather than physiological intermediates of repair. To investigate the biological role of fork regression in bacteriophage T4, we tested several mechanistic models of regression: strand exchange-mediated extrusion, topology-driven fork reversal and helicase-mediated extrusion. Here, we report that UvsW, a T4 branch-specific helicase, is necessary for the accumulation of regressed forks in vivo, and that UvsW-catalysed regression is the dominant mechanism of origin-fork processing that contributes to double-strand end formation. We also show that UvsW resolves purified fork intermediates in vitro by fork regression. Regression is therefore part of an active, UvsW-driven pathway of fork processing in bacteriophage T4.

摘要

停滞复制叉的重新激活需要特定机制,该机制能够识别叉状结构并促进下游加工事件。在几种叉重新激活模型中,叉回归被认为是支持修复的关键加工步骤。然而,也有人提出,回归的叉代表病理结构而非修复的生理中间体。为了研究叉回归在噬菌体T4中的生物学作用,我们测试了几种回归机制模型:链交换介导的挤压、拓扑驱动的叉反转和螺旋酶介导的挤压。在此,我们报告,UvsW(一种T4分支特异性螺旋酶)是体内回归叉积累所必需的,并且UvsW催化的回归是起源-叉加工的主要机制,有助于双链末端形成。我们还表明,UvsW在体外通过叉回归解析纯化的叉中间体。因此,回归是噬菌体T4中由UvsW驱动的活跃叉加工途径的一部分。

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