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通过表达一种新型人类叉头cDNA在酵母中重建不依赖MEC1的检查点。

Reconstitution of a MEC1-independent checkpoint in yeast by expression of a novel human fork head cDNA.

作者信息

Pati D, Keller C, Groudine M, Plon S E

机构信息

Texas Children's Cancer Center, Department of Pediatrics, Baylor College of Medicine, Houston 77030, USA.

出版信息

Mol Cell Biol. 1997 Jun;17(6):3037-46. doi: 10.1128/MCB.17.6.3037.

DOI:10.1128/MCB.17.6.3037
PMID:9154802
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC232156/
Abstract

A novel human cDNA, CHES1 (checkpoint suppressor 1), has been isolated by suppression of the mec1-1 checkpoint mutation in Saccharomyces cerevisiae. CHES1 suppresses a number of DNA damage-activated checkpoint mutations in S. cerevisiae, including mec1, rad9, rad24, dun1, and rad53. CHES1 suppression of sensitivity to DNA damage is specific for checkpoint-defective strains, in contrast to DNA repair-defective strains. Presence of CHES1 but not a control vector resulted in G2 delay after UV irradiation in checkpoint-defective strains, with kinetics, nuclear morphology, and cycloheximide resistance similar to those of a wild-type strain. CHES1 can also suppress the lethality, UV sensitivity, and G2 checkpoint defect of a mec1 null mutation. In contrast to this activity, CHES1 had no measurable effect on the replication checkpoint as assayed by hydroxyurea sensitivity of a mec1 strain. Sequence analysis demonstrates that CHES1 is a novel member of the fork head/Winged Helix family of transcription factors. Suppression of the checkpoint-defective phenotype requires a 200-amino-acid domain in the carboxy terminus of the protein which is distinct from the DNA binding site. Analysis of CHES1 activity is most consistent with activation of an alternative MEC1-independent checkpoint pathway in budding yeast.

摘要

一种新的人类cDNA,CHES1(检查点抑制因子1),已通过抑制酿酒酵母中的mec1-1检查点突变而被分离出来。CHES1可抑制酿酒酵母中一些DNA损伤激活的检查点突变,包括mec1、rad9、rad24、dun1和rad53。与DNA修复缺陷型菌株不同,CHES1对DNA损伤敏感性的抑制作用对检查点缺陷型菌株具有特异性。在检查点缺陷型菌株中,存在CHES1而非对照载体导致紫外线照射后G2期延迟,其动力学、核形态和对环己酰亚胺的抗性与野生型菌株相似。CHES1还可抑制mec1缺失突变的致死性、紫外线敏感性和G2检查点缺陷。与这种活性相反,通过mec1菌株对羟基脲的敏感性测定,CHES1对复制检查点没有可测量的影响。序列分析表明,CHES1是叉头/翼状螺旋转录因子家族的一个新成员。抑制检查点缺陷型表型需要蛋白质羧基末端一个200个氨基酸的结构域,该结构域与DNA结合位点不同。对CHES1活性的分析与在芽殖酵母中激活一条独立于MEC1的替代检查点途径最为一致。

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