DNA损伤重新定位至核孔复合体。

Relocalization of DNA lesions to the nuclear pore complex.

作者信息

Freudenreich Catherine H, Su Xiaofeng A

出版信息

FEMS Yeast Res. 2016 Dec 1;16(8). doi: 10.1093/femsyr/fow095.

DOI:10.1093/femsyr/fow095

PMID:27799300

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5113167/

Abstract

Early screens in yeast for mutations exhibiting sensitivity to DNA damage identified nuclear pore components, but their role in DNA repair was not well understood. Over the last decade, studies have revealed that several types of persistent DNA lesions relocate to either the nuclear pore complex (NPC) or nuclear envelope (NE). Of these two sites, the nuclear pore appears to be crucial for DNA repair of persistent double-strand breaks, eroded telomeres and sites of fork collapse at expanded CAG repeats. Using a combination of cell biological imaging techniques and yeast genetic assays for DNA repair, researchers have begun to understand both the how and why of lesion relocation to the NPC. Here we review the types of lesions that relocate to the NPC, mediators of relocation and the functional consequences of relocation understood to date. The emerging theme is that relocation to the NPC regulates recombination to influence repair pathway choice and provide a rescue mechanism for lesions or DNA structures that are resistant to repair.

摘要

早期在酵母中针对对DNA损伤敏感的突变进行的筛选鉴定出了核孔组件，但其在DNA修复中的作用尚未得到很好的理解。在过去十年中，研究表明几种类型的持续性DNA损伤会重新定位到核孔复合体（NPC）或核膜（NE）。在这两个位点中，核孔对于持续性双链断裂、侵蚀的端粒以及扩展CAG重复序列处的叉状塌陷位点的DNA修复似乎至关重要。通过结合细胞生物学成像技术和用于DNA修复的酵母遗传分析，研究人员已开始了解损伤重新定位到NPC的方式及原因。在此，我们综述了重新定位到NPC的损伤类型、重新定位的介导因子以及迄今为止所了解的重新定位的功能后果。新出现的主题是，重新定位到NPC会调节重组，以影响修复途径的选择，并为对修复有抗性的损伤或DNA结构提供一种挽救机制。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/7a41/5113167/8a6e0822debf/fow095fig1.jpg

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DNA损伤重新定位至核孔复合体。

Relocalization of DNA lesions to the nuclear pore complex.

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