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对捕食者的跨代反应中的局部适应性。

Local adaptation in transgenerational responses to predators.

作者信息

Walsh Matthew R, Castoe Todd, Holmes Julian, Packer Michelle, Biles Kelsey, Walsh Melissa, Munch Stephan B, Post David M

机构信息

Department of Biology, University of Texas at Arlington, Arlington, TX 76019, USA

Department of Biology, University of Texas at Arlington, Arlington, TX 76019, USA.

出版信息

Proc Biol Sci. 2016 Jan 27;283(1823). doi: 10.1098/rspb.2015.2271.

DOI:10.1098/rspb.2015.2271
PMID:26817775
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4795015/
Abstract

Environmental signals can induce phenotypic changes that span multiple generations. Along with phenotypic responses that occur during development (i.e. 'within-generation' plasticity), such 'transgenerational plasticity' (TGP) has been documented in a diverse array of taxa spanning many environmental perturbations. New theory predicts that temporal stability is a key driver of the evolution of TGP. We tested this prediction using natural populations of zooplankton from lakes in Connecticut that span a large gradient in the temporal dynamics of predator-induced mortality. We reared more than 120 clones of Daphnia ambigua from nine lakes for multiple generations in the presence/absence of predator cues. We found that temporal variation in mortality selects for within-generation plasticity while consistently strong (or weak) mortality selects for increased TGP. Such results provide us the first evidence for local adaptation in TGP and argue that divergent ecological conditions select for phenotypic responses within and across generations.

摘要

环境信号能够诱发跨越多个世代的表型变化。除了发育过程中出现的表型反应(即“代内”可塑性),这种“跨代可塑性”(TGP)已在众多受多种环境干扰的分类群中得到记载。新理论预测,时间稳定性是TGP进化的关键驱动因素。我们利用来自康涅狄格州湖泊的浮游动物自然种群对这一预测进行了测试,这些湖泊在捕食者诱导死亡率的时间动态方面存在很大梯度。我们在有/无捕食者线索的情况下,将来自九个湖泊的120多个模糊水蚤克隆培养了多代。我们发现,死亡率的时间变化选择了代内可塑性,而持续强烈(或微弱)的死亡率则选择了增强的TGP。这些结果为TGP中的局部适应性提供了首个证据,并表明不同的生态条件选择了代内和代间的表型反应。

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