异源双链修复作为酵母中紫外线诱变的中间步骤。

Heteroduplex repair as an intermediate step of UV mutagenesis in yeast.

作者信息

Eckardt F, Teh S J, Haynes R H

出版信息

Genetics. 1980 May;95(1):63-80. doi: 10.1093/genetics/95.1.63.

DOI:10.1093/genetics/95.1.63

PMID:7000619

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1214222/

Abstract

We have measured UV-induced mutation frequencies in yeast in a forward, nonselective assay system by scoring white adex ade2 double auxotrophs among parental red-pigmented ade2 clones. The frequencies of sectored and pure mutant clones were determined separately. In excision-defective strains carrying the genes rad1-1, rad3-2 and rad4-4, as well as in the double mutants, rad 1-1 rad 3-2 and rad 1-1 rad 4-4, considerably more sectored than pure clones are induced in the low-dose range; in repair-competent strains, pure mutant clones substantially outnumber the sectored clones. These results can be explained on the basis of known differences in the timing of error-prone repair during the cell division cycle; that is, we assume that error-prone repair occurs primarily before replication in RAD wild-type strains but after replication in excision-deficient mutants. It has been suggested that excision deficiency has a pleiotropic effect on heteroduplex repair and nucleotide excision repair; however, the high percentage (36.6%) of half-sectored clones found in the rad1-1 strain is hard to reconcile with this hypothesis. We propose that heteroduplex repair occurs subsequent to error-prone repair in both excision-proficient and excision-deficient strains.

摘要

我们通过在亲代红色色素ade2克隆中对白色adex ade2双营养缺陷型进行评分，在正向非选择性检测系统中测量了酵母中紫外线诱导的突变频率。扇形和纯突变克隆的频率分别测定。在携带rad1-1、rad3-2和rad4-4基因的切除缺陷型菌株以及双突变体rad 1-1 rad 3-2和rad 1-1 rad 4-4中，低剂量范围内诱导出的扇形克隆比纯克隆多得多；在具有修复能力的菌株中，纯突变克隆的数量大大超过扇形克隆。这些结果可以根据细胞分裂周期中易错修复时间的已知差异来解释；也就是说，我们假设在RAD野生型菌株中，易错修复主要发生在复制之前，而在切除缺陷型突变体中发生在复制之后。有人提出切除缺陷对异源双链修复和核苷酸切除修复有多效性影响；然而，在rad1-1菌株中发现的高比例（36.6%）半扇形克隆很难与这一假设相协调。我们提出，在切除 proficient和切除缺陷型菌株中，异源双链修复都发生在易错修复之后。

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异源双链修复作为酵母中紫外线诱变的中间步骤。

Heteroduplex repair as an intermediate step of UV mutagenesis in yeast.

作者信息

Eckardt F, Teh S J, Haynes R H

出版信息

Genetics. 1980 May;95(1):63-80. doi: 10.1093/genetics/95.1.63.

DOI:10.1093/genetics/95.1.63

PMID:7000619

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1214222/

Abstract

摘要

异源双链修复作为酵母中紫外线诱变的中间步骤。

Heteroduplex repair as an intermediate step of UV mutagenesis in yeast.

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出版信息

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异源双链修复作为酵母中紫外线诱变的中间步骤。

Heteroduplex repair as an intermediate step of UV mutagenesis in yeast.

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出版信息