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构巢曲霉bimD基因的突变导致条件性有丝分裂阻滞并对DNA损伤剂敏感。

Mutation in the bimD gene of Aspergillus nidulans confers a conditional mitotic block and sensitivity to DNA damaging agents.

作者信息

Denison S H, Käfer E, May G S

机构信息

Department of Cell Biology, Baylor College of Medicine, Houston, Texas 77030.

出版信息

Genetics. 1993 Aug;134(4):1085-96. doi: 10.1093/genetics/134.4.1085.

DOI:10.1093/genetics/134.4.1085
PMID:8375649
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1205577/
Abstract

Mutation in the bimD gene of Aspergillus nidulans results in a mitotic block in anaphase characterized by a defective mitosis. Mutation in bimD also confers, at temperatures permissive for the mitotic arrest phenotype, an increased sensitivity to DNA damaging agents, including methyl methanesulfonate and ultraviolet light. In order to better understand the relationship between DNA damage and mitotic progression, we cloned the bimD gene from Aspergillus. A cosmid containing the bimD gene was identified among pools of cosmids by cotransformation with the nutritional selective pyrG gene of a strain carrying the recessive, temperature-sensitive lethal bimD6 mutation. The bimD gene encodes a predicted polypeptide of 166,000 daltons in mass and contains amino acid sequence motifs similar to those found in some DNA-binding transcription factors. These sequences include a basic domain followed by a leucine zipper, which together are called a bZIP motif, and a carboxyl-terminal domain enriched in acidic amino acids. Overexpression of the wild-type bimD protein resulted in an arrest of the nuclear division cycle that was reversible and determined to be in either the G1 or S phase of the cell cycle. Our data suggest that bimD may play an essential regulatory role relating to DNA metabolism which is required for a successful mitosis.

摘要

构巢曲霉bimD基因的突变会导致有丝分裂后期出现有丝分裂阻滞,其特征是有丝分裂存在缺陷。在允许出现有丝分裂停滞表型的温度条件下,bimD基因的突变还会使构巢曲霉对包括甲磺酸甲酯和紫外线在内的DNA损伤剂的敏感性增加。为了更好地理解DNA损伤与有丝分裂进程之间的关系,我们从构巢曲霉中克隆了bimD基因。通过与携带隐性温度敏感致死bimD6突变的菌株的营养选择型pyrG基因共转化,在黏粒文库中鉴定出了一个含有bimD基因的黏粒。bimD基因编码一个预测分子量为166,000道尔顿的多肽,并且包含与一些DNA结合转录因子中发现的氨基酸序列基序相似的序列。这些序列包括一个碱性结构域,后面跟着一个亮氨酸拉链,二者合称为bZIP基序,以及一个富含酸性氨基酸的羧基末端结构域。野生型bimD蛋白的过表达导致核分裂周期停滞,这种停滞是可逆的,并且确定处于细胞周期的G1期或S期。我们的数据表明,bimD可能在与DNA代谢相关的过程中发挥重要的调节作用,而DNA代谢是成功进行有丝分裂所必需的。

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