A small noise approximation for Muller's Ratchet

Abstract

We consider an infinite system of SDEs with Fleming-Viot noise indexed by k=0,1,2,…, whose parameters α,λ, and ν are the (deleterious) selection coefficient, the (uni-directional) mutation rate, and a quantity which determines the size of the system's fluctuations. The SDE's unique weak solution X(t) = (Xk(t))k=0,1,2,... models what is known in population genetics as Muller's ratchet. Here, Xk(t) stands for the frequency of individuals carrying k deleterious mutations. Since the mutation process is uni-directional, t ∈f\k: Xk(t)> 0\ is non-decreasing for almost every path of X, and we refer to an increase as a click of Muller's ratchet. A long standing question concerns the clicking rate of Muller's ratchet. Using Duhamel's principle for semigroups, we give a partial answer by approximating E(Σk=1∞ kXk(t) ) and E(X0(t)) up to O(1/ν2) for fixed α, λ and t>0. Our results suggest that ψ:=ναe-λ/α is a crucial quantity also when the mutation/selection ratio θ= λ/α is moderately large: for large να, clicking of the ratchet on the time scale 1α θ becomes rare as soon as ψ becomes large.