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外切酶1依赖性诱变突变:用于研究错配修复中功能相互作用的模型系统

exo1-Dependent mutator mutations: model system for studying functional interactions in mismatch repair.

作者信息

Amin N S, Nguyen M N, Oh S, Kolodner R D

机构信息

Ludwig Institute for Cancer Research, University of California, San Diego School of Medicine, La Jolla, California 92093-0660, USA.

出版信息

Mol Cell Biol. 2001 Aug;21(15):5142-55. doi: 10.1128/MCB.21.15.5142-5155.2001.

DOI:10.1128/MCB.21.15.5142-5155.2001
PMID:11438669
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC87239/
Abstract

EXO1 interacts with MSH2 and MLH1 and has been proposed to be a redundant exonuclease that functions in mismatch repair (MMR). To better understand the role of EXO1 in mismatch repair, a genetic screen was performed to identify mutations that increase the mutation rates caused by weak mutator mutations such as exo1Delta and pms1-A130V mutations. In a screen starting with an exo1 mutation, exo1-dependent mutator mutations were obtained in MLH1, PMS1, MSH2, MSH3, POL30 (PCNA), POL32, and RNR1, whereas starting with the weak pms1 allele pms1-A130V, pms1-dependent mutator mutations were identified in MLH1, MSH2, MSH3, MSH6, and EXO1. These mutations only cause weak MMR defects as single mutants but cause strong MMR defects when combined with each other. Most of the mutations obtained caused amino acid substitutions in MLH1 or PMS1, and these clustered in either the ATP-binding region or the MLH1-PMS1 interaction regions of these proteins. The mutations showed two other types of interactions: specific pairs of mutations showed unlinked noncomplementation in diploid strains, and the defect caused by pairs of mutations could be suppressed by high-copy-number expression of a third gene, an effect that showed allele and overexpressed gene specificity. These results support a model in which EXO1 plays a structural role in MMR and stabilizes multiprotein complexes containing a number of MMR proteins. A similar role is proposed for PCNA based on the data presented.

摘要

EXO1与MSH2和MLH1相互作用,并且有人提出它是一种在错配修复(MMR)中发挥作用的冗余核酸外切酶。为了更好地理解EXO1在错配修复中的作用,进行了一项遗传筛选,以鉴定那些增加由弱诱变突变(如exo1Δ和pms1 - A130V突变)引起的突变率的突变。在以exo1突变开始的筛选中,在MLH1、PMS1、MSH2、MSH3、POL30(PCNA)、POL32和RNR1中获得了exo1依赖性诱变突变,而从弱pms1等位基因pms1 - A130V开始,在MLH1、MSH2、MSH3、MSH6和EXO1中鉴定出了pms1依赖性诱变突变。这些突变作为单突变体仅引起微弱的MMR缺陷,但相互组合时会引起强烈的MMR缺陷。获得的大多数突变导致MLH1或PMS1中的氨基酸替换,并且这些替换聚集在这些蛋白质的ATP结合区域或MLH1 - PMS1相互作用区域。这些突变还表现出另外两种类型的相互作用:特定的突变对在二倍体菌株中表现出非连锁非互补性,并且由突变对引起的缺陷可以通过第三个基因的高拷贝数表达来抑制,这种效应表现出等位基因和过表达基因的特异性。这些结果支持了一个模型,即EXO1在MMR中起结构作用,并稳定包含多种MMR蛋白的多蛋白复合物。基于所呈现的数据,对PCNA也提出了类似的作用。

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