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从单雌系进行祖先种群重建作为实验进化的一种工具。

Ancestral population reconstitution from isofemale lines as a tool for experimental evolution.

作者信息

Nouhaud Pierre, Tobler Ray, Nolte Viola, Schlötterer Christian

机构信息

Institut für Populationsgenetik Vetmeduni Vienna Vienna Austria.

Institut für Populationsgenetik Vetmeduni Vienna Vienna Austria; Present address: Ray Tobler, Australian Centre for Ancient DNA School of Biological Sciences University of Adelaide Adelaide SA Australia.

出版信息

Ecol Evol. 2016 Aug 30;6(20):7169-7175. doi: 10.1002/ece3.2402. eCollection 2016 Oct.

DOI:10.1002/ece3.2402
PMID:27895897
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5114691/
Abstract

Experimental evolution is a powerful tool to study adaptation under controlled conditions. Laboratory natural selection experiments mimic adaptation in the wild with better-adapted genotypes having more offspring. Because the selected traits are frequently not known, adaptation is typically measured as fitness increase by comparing evolved populations against an unselected reference population maintained in a laboratory environment. With adaptation to the laboratory conditions and genetic drift, however, it is not clear to what extent such comparisons provide unbiased estimates of adaptation. Alternatively, ancestral variation could be preserved in isofemale lines that can be combined to reconstitute the ancestral population. Here, we assess the impact of selection on alleles segregating in newly established isofemale lines. We reconstituted two populations from isofemale lines and compared them to two original ancestral populations (AP) founded from the same lines shortly after collection. No significant allele frequency changes could be detected between both AP and simulations showed that drift had a low impact compared to Pool-Seq-associated sampling effects. We conclude that laboratory selection on segregating variation in isofemale lines is too weak to have detectable effects, which validates ancestral population reconstitution from isofemale lines as an unbiased approach for measuring adaptation in evolved populations.

摘要

实验进化是在可控条件下研究适应性的有力工具。实验室自然选择实验模拟野外的适应性,适应度更高的基因型会产生更多后代。由于所选性状通常并不明确,适应性通常通过将进化后的种群与在实验室环境中维持的未选择的参考种群进行比较,以适应度增加来衡量。然而,随着对实验室条件的适应和遗传漂变,尚不清楚这种比较在多大程度上能提供对适应性的无偏估计。另外,可以在同雌系中保留祖先变异,这些同雌系可以组合起来重建祖先种群。在这里,我们评估选择对新建立的同雌系中分离等位基因的影响。我们从同雌系中重建了两个种群,并将它们与采集后不久从相同品系建立的两个原始祖先种群(AP)进行比较。在两个AP之间未检测到显著的等位基因频率变化,模拟结果表明,与Pool-Seq相关的抽样效应相比,漂变的影响较小。我们得出结论,对同雌系中分离变异进行实验室选择的作用太弱,以至于无法产生可检测到的影响,这验证了从同雌系重建祖先种群作为一种衡量进化种群适应性的无偏方法的有效性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3b7a/5114691/31833a14a318/ECE3-6-7169-g002.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3b7a/5114691/a757a5f234c4/ECE3-6-7169-g001.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3b7a/5114691/31833a14a318/ECE3-6-7169-g002.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3b7a/5114691/a757a5f234c4/ECE3-6-7169-g001.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3b7a/5114691/31833a14a318/ECE3-6-7169-g002.jpg

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