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DNA双链断裂的重新连接与悬垂长度的关系。

Rejoining of DNA double-strand breaks as a function of overhang length.

作者信息

Daley James M, Wilson Thomas E

机构信息

Department of Pathology, University of Michigan Medical School, Medical Science I M4214/0602, 1301 Catherine Road, Ann Arbor, MI 48109-0602, USA.

出版信息

Mol Cell Biol. 2005 Feb;25(3):896-906. doi: 10.1128/MCB.25.3.896-906.2005.

DOI:10.1128/MCB.25.3.896-906.2005
PMID:15657419
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC544009/
Abstract

The ends of spontaneously occurring double-strand breaks (DSBs) may contain various lengths of single-stranded DNA, blocking lesions, and gaps and flaps generated by end annealing. To investigate the processing of such structures, we developed an assay in which annealed oligonucleotides are ligated onto the ends of a linearized plasmid which is then transformed into Saccharomyces cerevisiae. Reconstitution of a marker occurs only when the oligonucleotides are incorporated and repair is in frame, permitting rapid analysis of complex DSB ends. Here, we created DSBs with compatible overhangs of various lengths and asked which pathways are required for their precise repair. Three mechanisms of rejoining were observed, regardless of overhang polarity: nonhomologous end joining (NHEJ), a Rad52-dependent single-strand annealing-like pathway, and a third mechanism independent of the first two mechanisms. DSBs with overhangs of less than 4 bases were mainly repaired by NHEJ. Repair became less dependent on NHEJ when the overhangs were longer or had a higher GC content. Repair of overhangs greater than 8 nucleotides was as much as 150-fold more efficient, impaired 10-fold by rad52 mutation, and highly accurate. Reducing the microhomology extent between long overhangs reduced their repair dramatically, to less than NHEJ of comparable short overhangs. These data support a model in which annealing energy is a primary determinant of the rejoining efficiency and mechanism.

摘要

自发产生的双链断裂(DSB)末端可能包含各种长度的单链DNA、阻断性损伤以及由末端退火产生的缺口和瓣状结构。为了研究此类结构的加工过程,我们开发了一种检测方法,即将退火的寡核苷酸连接到线性化质粒的末端,然后将其转化到酿酒酵母中。只有当寡核苷酸被整合且修复读框正确时,标记物才会重建,从而能够快速分析复杂的DSB末端。在此,我们创建了具有不同长度兼容突出端的DSB,并探究其精确修复需要哪些途径。无论突出端的极性如何,均观察到三种重新连接机制:非同源末端连接(NHEJ)、一种依赖Rad52的单链退火样途径以及第三种独立于前两种机制的途径。突出端少于4个碱基的DSB主要通过NHEJ修复。当突出端更长或GC含量更高时,修复对NHEJ的依赖性降低。大于8个核苷酸的突出端的修复效率高达150倍,rad52突变使其受损10倍,且高度准确。减少长突出端之间的微同源性程度会显著降低其修复,降至低于可比短突出端的NHEJ修复水平。这些数据支持了一种模型,即退火能量是重新连接效率和机制的主要决定因素。

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