母体效应在新环境和稳定环境中的益处。
The benefits of maternal effects in novel and in stable environments.
机构信息
Department of Mathematics, University of Surrey, Guildford, Surrey GU2 7XH, UK.
出版信息
J R Soc Interface. 2012 Oct 7;9(75):2403-13. doi: 10.1098/rsif.2012.0183. Epub 2012 May 9.
Abstract
Natural selection favours phenotypes that match prevailing ecological conditions. A rapid process of adaptation is therefore required in changing environments. Maternal effects can facilitate such responses, but it is currently poorly understood under which circumstances maternal effects may accelerate or slow down the rate of phenotypic evolution. Here, we use a quantitative genetic model, including phenotypic plasticity and maternal effects, to suggest that the relationship between fitness and phenotypic variance plays an important role. Intuitive expectations that positive maternal effects are beneficial are supported following an extreme environmental shift, but, if too strong, that shift can also generate oscillatory dynamics that overshoot the optimal phenotype. In a stable environment, negative maternal effects that slow phenotypic evolution actually minimize variance around the optimum phenotype and thus maximize population mean fitness.
摘要
自然选择有利于与流行生态条件相匹配的表型。因此,在不断变化的环境中需要快速的适应过程。母体效应可以促进这种反应,但目前尚不清楚在什么情况下母体效应可以加速或减缓表型进化的速度。在这里,我们使用一个包括表型可塑性和母体效应的数量遗传模型,表明适应性和表型方差之间的关系起着重要作用。在经历极端环境变化后,人们普遍认为积极的母体效应是有益的,但如果母体效应过于强烈,这种变化也会产生超过最佳表型的振荡动态。在稳定的环境中,减缓表型进化的负母体效应实际上会使最优表型周围的方差最小化,从而使种群平均适应性最大化。
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