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DNA连接酶III和DNA连接酶IV在人类体细胞中执行基因上不同形式的末端连接。

DNA ligase III and DNA ligase IV carry out genetically distinct forms of end joining in human somatic cells.

作者信息

Oh Sehyun, Harvey Adam, Zimbric Jacob, Wang Yongbao, Nguyen Thanh, Jackson Pauline J, Hendrickson Eric A

机构信息

Department of Biochemistry, Molecular Biology, and Biophysics, University of Minnesota Medical School, Minneapolis, MN 55455, United States.

Department of Biochemistry, Molecular Biology, and Biophysics, University of Minnesota Medical School, Minneapolis, MN 55455, United States.

出版信息

DNA Repair (Amst). 2014 Sep;21:97-110. doi: 10.1016/j.dnarep.2014.04.015. Epub 2014 May 16.

DOI:10.1016/j.dnarep.2014.04.015
PMID:24837021
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4125535/
Abstract

Ku-dependent C-NHEJ (classic non-homologous end joining) is the primary DNA EJing (end joining) repair pathway in mammals. Recently, an additional EJing repair pathway (A-NHEJ; alternative-NHEJ) has been described. Currently, the mechanism of A-NHEJ is obscure although a dependency on LIGIII (DNA ligase III) is often implicated. To test the requirement for LIGIII in A-NHEJ we constructed a LIGIII conditionally-null human cell line using gene targeting. Nuclear EJing activity appeared unaffected by a deficiency in LIGIII as, surprisingly, so were random gene targeting integration events. In contrast, LIGIII was required for mitochondrial function and this defined the gene's essential activity. Human Ku:LIGIII and Ku:LIGIV (DNA ligase IV) double knockout cell lines, however, demonstrated that LIGIII is required for the enhanced A-NHEJ activity that is observed in Ku-deficient cells. Most unexpectedly, however, the majority of EJing events remained LIGIV-dependent. In conclusion, although human LIGIII has an essential function in mitochondrial maintenance, it is dispensable for most types of nuclear DSB repair, except for the A-NHEJ events that are normally suppressed by Ku. Moreover, we describe that a robust Ku-independent, LIGIV-dependent repair pathway exists in human somatic cells.

摘要

依赖 Ku 的 C-NHEJ(经典非同源末端连接)是哺乳动物中主要的 DNA 末端连接修复途径。最近,一种额外的末端连接修复途径(A-NHEJ;替代非同源末端连接)已被描述。目前,A-NHEJ 的机制尚不清楚,尽管通常认为它依赖于 LIGIII(DNA 连接酶 III)。为了测试 A-NHEJ 中对 LIGIII 的需求,我们使用基因靶向构建了一种 LIGIII 条件性敲除的人类细胞系。核末端连接活性似乎不受 LIGIII 缺陷的影响,令人惊讶的是,随机基因靶向整合事件也是如此。相比之下,LIGIII 是线粒体功能所必需的,这确定了该基因的基本活性。然而,人类 Ku:LIGIII 和 Ku:LIGIV(DNA 连接酶 IV)双敲除细胞系表明,LIGIII 是 Ku 缺陷细胞中观察到的增强的 A-NHEJ 活性所必需的。然而,最出乎意料的是,大多数末端连接事件仍然依赖于 LIGIV。总之,尽管人类 LIGIII 在线粒体维持中具有重要功能,但对于大多数类型的核双链断裂修复来说它是可有可无的,除了通常被 Ku 抑制的 A-NHEJ 事件。此外,我们描述了在人类体细胞中存在一种强大的不依赖 Ku、依赖 LIGIV 的修复途径。

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