滑脱的(CTG)*(CAG)重复序列可被正确修复、逃避修复或进行易出错修复。

Slipped (CTG)*(CAG) repeats can be correctly repaired, escape repair or undergo error-prone repair.

作者信息

Panigrahi Gagan B, Lau Rachel, Montgomery S Erin, Leonard Michelle R, Pearson Christopher E

机构信息

Program of Genetics & Genomic Biology, The Hospital for Sick Children, 555 University Avenue, Elm Wing 11-135, Toronto, Ontario M5G 1X8, Canada.

出版信息

Nat Struct Mol Biol. 2005 Aug;12(8):654-62. doi: 10.1038/nsmb959. Epub 2005 Jul 17.

DOI:10.1038/nsmb959

PMID:16025129

Abstract

Expansion of (CTG)(CAG) repeats, the cause of 14 or more diseases, is presumed to arise through escaped repair of slipped DNAs. We report the fidelity of slipped-DNA repair using human cell extracts and DNAs with slip-outs of (CAG)(20) or (CTG)(20). Three outcomes occurred: correct repair, escaped repair and error-prone repair. The choice of repair path depended on nick location and slip-out composition (CAG or CTG). A new form of error-prone repair was detected whereby excess repeats were incompletely excised, constituting a previously unknown path to generate expansions but not deletions. Neuron-like cell extracts yielded each of the three repair outcomes, supporting a role for these processes in (CTG)(CAG) instability in patient post-mitotic brain cells. Mismatch repair (MMR) and nucleotide excision repair (NER) proteins hMSH2, hMSH3, hMLH1, XPF, XPG or polymerase beta were not required-indicating that their role in instability may precede that of slip-out processing. Differential processing of slipped repeats may explain the differences in mutation patterns between various disease loci or tissues.

摘要

（CTG）（CAG）重复序列的扩增是14种或更多疾病的病因，据推测是由于滑动DNA的修复逃逸所致。我们报告了使用人类细胞提取物和具有（CAG）20或（CTG）20滑出序列的DNA进行滑动DNA修复的保真度。出现了三种结果：正确修复、修复逃逸和易出错修复。修复途径的选择取决于切口位置和滑出序列组成（CAG或CTG）。检测到一种新的易出错修复形式，即多余的重复序列未被完全切除，这构成了一种以前未知的产生扩增而非缺失的途径。神经元样细胞提取物产生了三种修复结果中的每一种，支持了这些过程在患者有丝分裂后脑细胞中（CTG）（CAG）不稳定性中的作用。错配修复（MMR）和核苷酸切除修复（NER）蛋白hMSH2、hMSH3、hMLH1、XPF、XPG或聚合酶β不是必需的，这表明它们在不稳定性中的作用可能先于滑出序列的处理。滑动重复序列的差异处理可能解释了不同疾病位点或组织之间突变模式的差异。

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滑脱的(CTG)*(CAG)重复序列可被正确修复、逃避修复或进行易出错修复。

Slipped (CTG)*(CAG) repeats can be correctly repaired, escape repair or undergo error-prone repair.

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