酿酒酵母亚端粒Y'重复序列间的有丝分裂重组。

Mitotic recombination among subtelomeric Y' repeats in Saccharomyces cerevisiae.

作者信息

Louis E J, Haber J E

机构信息

Rosenstiel Basic Medical Sciences Research Center, Brandeis University, Waltham, Massachusetts 02254.

出版信息

Genetics. 1990 Mar;124(3):547-59. doi: 10.1093/genetics/124.3.547.

DOI:10.1093/genetics/124.3.547

PMID:2179053

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1203948/

Abstract

Y's are a dispersed family of repeats that vary in copy number, location and restriction fragment lengths between strains but exhibit within-strain homogeneity. We have studied mitotic recombination between members of the subtelomeric Y' repeated sequence family of Saccharomyces cerevisiae. Individual copies of Y's were marked with SUP11 and URA3 which allowed for the selection of duplications and losses of the marked Y's. Duplications occurred by ectopic recombinational interactions between Y's at different chromosome ends as well as by unequal sister chromatid exchange. Several of the ectopic duplications resulted in an originally Y'-less chromosome end acquiring a marked Y'. Among losses, most resulted from ectopic exchange or conversion in which only the marker sequence was lost. In some losses, the chromosome end became Y'-less. Although the two subsets of Y's, Y'-longs (6.7 kb) and Y'-shorts (5.2 kb), share extensive sequence homology, a marked Y' recombines highly preferentially within its own subset. These mitotic interactions can in part explain the maintenance of Y's and their subsets, the homogeneity among Y's within a strain, as well as diversity between strains.

摘要

Y序列是一个分散的重复序列家族，其拷贝数、位置以及不同菌株间的限制性片段长度各不相同，但在同一菌株内具有同质性。我们研究了酿酒酵母亚端粒Y'重复序列家族成员之间的有丝分裂重组。用SUP11和URA3标记Y序列的各个拷贝，这使得我们能够筛选出标记Y序列的重复和缺失情况。重复通过不同染色体末端的Y序列之间的异位重组相互作用以及不等姐妹染色单体交换而发生。一些异位重复导致原本没有Y序列的染色体末端获得一个标记的Y序列。在缺失情况中，大多数是由于异位交换或转换，其中只有标记序列丢失。在一些缺失中，染色体末端变成没有Y序列的状态。尽管Y序列的两个亚类，即长Y'（6.7 kb）和短Y'（5.2 kb），具有广泛的序列同源性，但一个标记的Y序列在其自身亚类内的重组具有高度优先性。这些有丝分裂相互作用可以部分解释Y序列及其亚类的维持、同一菌株内Y序列的同质性以及不同菌株间的多样性。

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