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在时间变化的环境中保护单倍体多态性。

Protecting haploid polymorphisms in temporally variable environments.

作者信息

Dean Antony M

机构信息

BioTechnology Institute and Department of Ecology Evolution and Behavior, University of Minnesota, St. Paul, Minnesota 55108-6106, USA.

出版信息

Genetics. 2005 Feb;169(2):1147-56. doi: 10.1534/genetics.104.036053. Epub 2004 Nov 15.

DOI:10.1534/genetics.104.036053
PMID:15545644
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1449120/
Abstract

Analysis of a continuous-time model shows that a protected polymorphism can arise in a haploid population subject to temporal fluctuations in selection. The requirements are that population size is regulated in a density-dependent manner and that an allele's arithmetic mean relative growth rate is greater than one when rare and that its harmonic mean relative growth rate is less than one when common. There is no requirement that relative growth rate be frequency dependent. Comparisons with discrete-time models show that the standard formalism used by population genetics ignores forced changes in generation time as rare advantageous alleles sweep into a population. In temporally variable environments, frequency-dependent changes in generation times tend to counteract these invasions. Such changes can prevent fixation and protect polymorphisms.

摘要

对一个连续时间模型的分析表明,在一个受到选择随时间波动影响的单倍体种群中,可能会出现受保护的多态性。其要求是种群大小以密度依赖的方式进行调节,并且一个等位基因在罕见时的算术平均相对增长率大于1,而在常见时其调和平均相对增长率小于1。并不要求相对增长率依赖于频率。与离散时间模型的比较表明,群体遗传学所使用的标准形式忽略了随着罕见的有利等位基因席卷种群而导致的世代时间的强制变化。在随时间变化的环境中,世代时间的频率依赖性变化往往会抵消这些入侵。这种变化可以阻止固定并保护多态性。

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