杂合性会增加微卫星突变率。
Heterozygosity increases microsatellite mutation rate.
作者信息
Amos William
机构信息
Department of Zoology, Downing Street, Cambridge CB2 3EJ, UK
出版信息
Biol Lett. 2016 Jan;12(1):20150929. doi: 10.1098/rsbl.2015.0929.
Abstract
Whole genome sequencing of families of Arabidopsis has recently lent strong support to the heterozygote instability (HI) hypothesis that heterozygosity locally increases mutation rate. However, there is an important theoretical difference between the impact on base substitutions, where mutation rate increases in regions surrounding a heterozygous site, and the impact of HI on sequences such as microsatellites, where mutations are likely to occur at the heterozygous site itself. At microsatellite loci, HI should create a positive feedback loop, with heterozygosity and mutation rate mutually increasing each other. Direct support for HI acting on microsatellites is limited and contradictory. I therefore analysed AC microsatellites in 1163 genome sequences from the 1000 genomes project. I used the presence of rare alleles, which are likely to be very recent in origin, as a surrogate measure of mutation rate. I show that rare alleles are more likely to occur at locus-population combinations with higher heterozygosity even when all populations carry exactly the same number of alleles.
摘要
拟南芥家族的全基因组测序最近为杂合子不稳定性(HI)假说提供了有力支持,该假说认为杂合性会局部提高突变率。然而,对碱基替换的影响(杂合位点周围区域的突变率增加)与HI对微卫星等序列的影响之间存在重要的理论差异,在微卫星序列中,突变很可能发生在杂合位点本身。在微卫星位点,HI应该会形成一个正反馈循环,杂合性和突变率相互增加。对HI作用于微卫星的直接支持有限且相互矛盾。因此,我分析了来自千人基因组计划的1163个基因组序列中的AC微卫星。我将稀有等位基因的存在(其起源可能非常新)用作突变率的替代指标。我发现,即使所有群体携带的等位基因数量完全相同,稀有等位基因也更有可能出现在杂合性较高的位点 - 群体组合中。
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