叶绿体和细菌基因组内的偏向性基因转换、拷贝数及表观突变率差异
Biased gene conversion, copy number, and apparent mutation rate differences within chloroplast and bacterial genomes.
作者信息
Birky C W, Walsh J B
机构信息
Department of Molecular Genetics, Ohio State University, Columbus 43210.
出版信息
Genetics. 1992 Mar;130(3):677-83. doi: 10.1093/genetics/130.3.677.
Abstract
We investigate the possibility that differences between synonymous substitution rates of organelle and bacterial genes differing only in copy number may be due to conversion bias. We find that the rather large observed difference in the synonymous rates between genes in the single copy and inverted-repeat regions of chloroplasts can be accounted for by a very small bias against new mutants. More generally, differences in the within-organelle fixation probability result in different apparent mutation rates as measured by the expected rate of appearance of cells homoplasmic for new mutants. Thus, differences in intracellular population parameters rather than molecular mechanisms can account for some variation in the apparent mutation rates of organelle genes, and possibly in other systems with variable numbers of gene copies. On the other hand, our analysis suggests that conversion bias is not a likely explanation for relatively low mutation rates observed near the replication origin of bacterial chromosomes.
摘要
我们研究了一种可能性,即仅在拷贝数上存在差异的细胞器基因和细菌基因的同义替换率之间的差异可能是由于转换偏向所致。我们发现,叶绿体单拷贝和反向重复区域中基因间所观察到的相当大的同义率差异,可以由对新突变体非常小的偏向来解释。更普遍地说,细胞器内固定概率的差异导致了通过新突变体纯质细胞出现的预期速率所衡量的不同表观突变率。因此,细胞内群体参数的差异而非分子机制,可以解释细胞器基因表观突变率的一些变化,并且可能在其他具有可变基因拷贝数的系统中也是如此。另一方面,我们的分析表明,转换偏向不太可能是细菌染色体复制起点附近观察到的相对较低突变率的解释。
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