“超级杀手”突变抑制酿酒酵母中影响双链RNA杀手质粒复制的染色体突变。
"Superkiller" mutations suppress chromosomal mutations affecting double-stranded RNA killer plasmid replication in saccharomyces cerevisiae.
作者信息
Toh-E A, Wickner R B
出版信息
Proc Natl Acad Sci U S A. 1980 Jan;77(1):527-30. doi: 10.1073/pnas.77.1.527.
Abstract
Saccharomyces cerevisiae strains carrying a 1.5 x 10(6)-dalton double-stranded RNA genome in virus-like particles (killer plasmid) secrete a protein toxin that kills strains not carrying this plasmid. At least 28 chromosomal genes (mak genes) are required to maintain or replicate this plasmid. Recessive mutations in any of four other chromosomal genes (ski for superkiller) result in enhanced toxin production. We report that many ski- mak- double mutants are able to maintain the killer plasmid, indicating that the SKI products have an effect on plasmid replication. The ski1-1 mutation suppresses (bypasses) all mak mutations tested except mak16-1. A variant killer plasmid is described that confers the superkiller phenotype and, like chromosomal ski mutations, makes several mak genes dispensable for plasmid replication.
摘要
携带病毒样颗粒(杀伤性质粒)中1.5×10⁶道尔顿双链RNA基因组的酿酒酵母菌株会分泌一种蛋白质毒素,该毒素能杀死不携带此质粒的菌株。维持或复制该质粒至少需要28个染色体基因(mak基因)。其他四个染色体基因(ski代表超杀伤)中任何一个的隐性突变都会导致毒素产量增加。我们报告说,许多ski-mak双突变体能够维持杀伤性质粒,这表明SKI产物对质粒复制有影响。ski1-1突变能抑制(绕过)除mak16-1之外测试的所有mak突变。描述了一种变异的杀伤性质粒,它赋予超杀伤表型,并且与染色体ski突变一样,使几个mak基因对于质粒复制变得可有可无。
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本文引用的文献
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A mutant killer plasmid whose replication depends on a chromosomal "superkiller" mutation.一种依赖于染色体“超级杀手”突变进行复制的突变杀手质粒。
Genetics. 1979 Apr;91(4):673-82. doi: 10.1093/genetics/91.4.673.
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Dominant chromosomal mutation bypassing chromosomal genes needed for killer RNA plasmid replication in yeast.酵母中用于杀伤性 RNA 质粒复制的染色体基因发生显性染色体突变。
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Deletion of mitochondrial DNA bypassing a chromosomal gene needed for maintenance of the killer plasmid of yeast.线粒体 DNA 的缺失绕过了酵母杀伤质粒维持所需的染色体基因。
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Somatic segregation of the killer (k) and neutral (n) cytoplasmic genetic determinants in yeast.酵母中杀伤型(k)和中性(n)细胞质遗传决定因子的体细胞分离
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