利用酵母转化对克隆基因进行精细结构重组分析。

Fine structure recombinational analysis of cloned genes using yeast transformation.

作者信息

Kunes S, Ma H, Overbye K, Fox M S, Botstein D

出版信息

Genetics. 1987 Jan;115(1):73-81. doi: 10.1093/genetics/115.1.73.

DOI:10.1093/genetics/115.1.73

PMID:3549444

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1203065/

Abstract

We describe a general method for analyzing the genetic fine structure of plasmid-borne genes in yeast. Previously we had reported that a linearized plasmid is efficiently rescued by recombination with a homologous restriction fragment when these are co-introduced by DNA-mediated transformation of yeast. Here, we show that a mutation can be localized to a small DNA interval when members of a deletion series of wild-type restriction fragments are used in the rescue of a linearized mutant plasmid. The resolution of this method is to at least 30 base pairs and is limited by the loss of a wild-type marker with proximity to a free DNA end. As a means for establishing the nonidentity of two mutations, we determined the resolution of two-point crosses with a mutant linearized plasmid and a mutant homologous restriction fragment. Recombination between mutations separated by as little as 100 base pairs was detected. Moreover, the results indicate that exchange within a marked interval results primarily from one of two single crossovers that repair the linearized plasmid. These approaches to mapping the genetic fine structure of plasmids should join existing methods in a robust approach to the mutational analysis of gene structure in yeast.

摘要

我们描述了一种分析酵母中质粒携带基因遗传精细结构的通用方法。此前我们曾报道，当通过酵母的DNA介导转化共导入线性化质粒和同源限制性片段时，线性化质粒可通过与同源限制性片段的重组而高效拯救。在此，我们表明，当使用野生型限制性片段缺失系列的成员来拯救线性化突变体质粒时，突变可定位到一个小的DNA区间。该方法的分辨率至少为30个碱基对，并且受靠近游离DNA末端的野生型标记丢失的限制。作为确定两个突变非同一性的一种手段，我们测定了突变线性化质粒与突变同源限制性片段两点杂交的分辨率。检测到相隔仅100个碱基对的突变之间的重组。此外，结果表明，标记区间内的交换主要源于修复线性化质粒的两个单交换之一。这些绘制质粒遗传精细结构的方法应与现有方法结合，形成一种强有力的酵母基因结构突变分析方法。

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