一个对酿酒酵母中串联重复基因的序列重组具有特异性和全局性影响的基因。
A gene with specific and global effects on recombination of sequences from tandemly repeated genes in Saccharomyces cerevisiae.
作者信息
Keil R L, McWilliams A D
机构信息
Department of Biological Chemistry, Milton S. Hershey Medical Center, Hershey, Pennsylvania 17033.
出版信息
Genetics. 1993 Nov;135(3):711-8. doi: 10.1093/genetics/135.3.711.
Abstract
The preservation of sequence homogeneity and copy number of tandemly repeated genes may require specific mechanisms or regulation of recombination. We have identified mutations that specifically affect recombination among natural repetitions in the yeast Saccharomyces cerevisiae. The rrm3 mutation stimulates mitotic recombination in the naturally occurring tandem repeats of the rDNA and copper chelatin (CUP1) genes. This mutation does not affect recombination of several other types of repeated genes tested including Ty elements, mating type information and duplications created by transformation. In addition to stimulating exchange among the multiple CUP1 repeats at their natural chromosomal location, rrm3 also increases recombination of a duplication of CUP1 units present at his4. This suggests that the RRM3 gene may encode a sequence-specific factor that contributes to a global suppression of mitotic exchange in sequences that can be maintained as tandem arrays.
摘要
串联重复基因序列同质性和拷贝数的维持可能需要特定的机制或重组调控。我们已经鉴定出了一些特异性影响酿酒酵母天然重复序列间重组的突变。rrm3突变会刺激核糖体DNA(rDNA)和铜螯合蛋白(CUP1)基因天然存在的串联重复序列中的有丝分裂重组。该突变不影响所测试的其他几种重复基因的重组,包括Ty元件、交配型信息以及转化产生的重复序列。除了刺激多个CUP1重复序列在其天然染色体位置之间的交换外,rrm3还增加了位于his4的CUP1单位重复序列的重组。这表明RRM3基因可能编码一种序列特异性因子,该因子有助于全局抑制那些可作为串联阵列维持的序列中的有丝分裂交换。
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