慢-快种群的协同进化：进化滑动、进化伪平衡与复杂的红皇后动态

Coevolution of slow-fast populations: evolutionary sliding, evolutionary pseudo-equilibria and complex Red Queen dynamics.

作者信息

Dercole F, Ferrière R, Gragnani A, Rinaldi S

机构信息

DEI, Politecnico di Milano Via Ponzio 34/5, 20133 Milano, Italy.

出版信息

Proc Biol Sci. 2006 Apr 22;273(1589):983-90. doi: 10.1098/rspb.2005.3398.

DOI:10.1098/rspb.2005.3398

PMID:16627284

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1560249/

Abstract

We study the interplay of ecological and evolutionary dynamics in communities composed of populations with contrasting time-scales. In such communities, genetic variation of individual traits can cause population transitions between stationary and cyclic ecological regimes, hence abrupt variations in fitness. Such abrupt variations raise ridges in the adaptive landscape, where the populations are poised between equilibrium and cyclic coexistence and along which evolutionary trajectories can remain sliding for long times or halt at special points called evolutionary pseudo-equilibria. These novel phenomena should be generic to all systems in which ecological interactions cause fitness to vary discontinuously. They are demonstrated by the analysis of a predator-prey community, with one adaptive trait for each population. The eco-evolutionary dynamics of the system show a number of other distinctive features, including evolutionary extinction and two forms of Red Queen dynamics. One of them is characterized by intermittent bouts of cyclic oscillations of the two populations.

摘要

我们研究了由具有不同时间尺度的种群组成的群落中生态和进化动力学的相互作用。在这样的群落中，个体性状的遗传变异可导致种群在稳定和周期性生态状态之间转变，从而使适合度发生突然变化。这种突然变化在适应性景观中形成了脊，种群在平衡和周期性共存之间保持平衡，沿着这些脊，进化轨迹可以长时间滑动，或者在称为进化伪平衡的特殊点停止。这些新现象对于所有生态相互作用导致适合度不连续变化的系统来说应该是普遍存在的。通过对一个捕食者-猎物群落的分析得到了证明，每个种群都有一个适应性性状。该系统的生态进化动力学还表现出许多其他独特特征，包括进化灭绝和两种形式的红皇后动力学。其中一种特征是两个种群间歇性地出现周期性振荡。

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