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Mre11磷酸二酯酶基序I中的突变,除了会损害核酸酶活性外,还会破坏酿酒酵母Mre11-Rad50-Xrs2复合物的稳定性。

Mutations in Mre11 phosphoesterase motif I that impair Saccharomyces cerevisiae Mre11-Rad50-Xrs2 complex stability in addition to nuclease activity.

作者信息

Krogh Berit O, Llorente Bertrand, Lam Alicia, Symington Lorraine S

机构信息

Institute of Cancer Research and Department of Microbiology, Columbia University Medical Center, 701 W. 168th Street, New York, NY 10032, USA.

出版信息

Genetics. 2005 Dec;171(4):1561-70. doi: 10.1534/genetics.105.049478. Epub 2005 Sep 2.

DOI:10.1534/genetics.105.049478
PMID:16143598
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1456084/
Abstract

The Mre11-Rad50-Xrs2 complex is involved in DNA double-strand break repair, telomere maintenance, and the intra-S phase checkpoint. The Mre11 subunit has nuclease activity in vitro, but the role of the nuclease in DNA repair and telomere maintenance remains controversial. We generated six mre11 alleles with substitutions of conserved residues within the Mre11-phosphoesterase motifs and compared the phenotypes conferred, as well as exonuclease activity and complex formation, by the mutant proteins. Substitutions of Asp16 conferred the most severe DNA repair and telomere length defects. Interactions between Mre11-D16A or Mre11-D16N and Rad50 or Xrs2 were severely compromised, whereas the mre11 alleles with greater DNA repair proficiency also exhibited stable complex formation. At all of the targeted residues, alanine substitution resulted in a more severe defect in DNA repair compared to the more conservative asparagine substitutions, but all of the mutant proteins exhibited <2% of the exonuclease activity observed for wild-type Mre11. Our results show that the structural integrity of the Mre11-Rad50-Xrs2 complex is more important than the catalytic activity of the Mre11 nuclease for the overall functions of the complex in vegetative cells.

摘要

Mre11-Rad50-Xrs2复合物参与DNA双链断裂修复、端粒维持和S期内检查点。Mre11亚基在体外具有核酸酶活性,但该核酸酶在DNA修复和端粒维持中的作用仍存在争议。我们生成了六个mre11等位基因,其Mre11-磷酸二酯酶基序内的保守残基被替换,并比较了突变蛋白赋予的表型、外切核酸酶活性和复合物形成情况。Asp16的替换导致最严重的DNA修复和端粒长度缺陷。Mre11-D16A或Mre11-D16N与Rad50或Xrs2之间的相互作用严重受损,而具有更高DNA修复能力的mre11等位基因也表现出稳定的复合物形成。在所有靶向残基处,与更保守的天冬酰胺替换相比,丙氨酸替换导致DNA修复缺陷更严重,但所有突变蛋白的外切核酸酶活性均低于野生型Mre11的2%。我们的结果表明,对于营养细胞中复合物的整体功能而言,Mre11-Rad50-Xrs2复合物的结构完整性比Mre11核酸酶的催化活性更重要。

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