English

Fixation and absorption in a fluctuating environment

Populations and Evolution 2017-10-25 v1

Abstract

A fundamental problem in the fields of population genetics, evolution, and community ecology, is the fate of a single mutant, or invader, introduced in a finite population of wild types. For a fixed-size community of NN individuals, with Markovian, zero-sum dynamics driven by stochastic birth-death events, the mutant population eventually reaches either fixation or extinction. The classical analysis, provided by Kimura and his coworkers, is focused on the neutral case, [where the dynamics is only due to demographic stochasticity (drift)], and on \emph{time-independent} selective forces (deleterious/beneficial mutation). However, both theoretical arguments and empirical analyses suggest that in many cases the selective forces fluctuate in time (temporal environmental stochasticity). Here we consider a generic model for a system with demographic noise and fluctuating selection. Our system is characterized by the time-averaged (log)-fitness s0s_0 and zero-mean fitness fluctuations. These fluctuations, in turn, are parameterized by their amplitude γ\gamma and their correlation time δ\delta. We provide asymptotic (large NN) formulas for the chance of fixation, the mean time to fixation and the mean time to absorption. Our expressions interpolate correctly between the constant selection limit γ0\gamma \to 0 and the time-averaged neutral case s0=0s_0=0.

Keywords

Cite

@article{arxiv.1710.08807,
  title  = {Fixation and absorption in a fluctuating environment},
  author = {Matan Danino and Nadav M. Shnerb},
  journal= {arXiv preprint arXiv:1710.08807},
  year   = {2017}
}
R2 v1 2026-06-22T22:24:09.838Z