Invasion by rare mutants in a spatial two-type Fisher-Wright system with selection

Abstract

We consider a meanfield system of interacting Fisher-Wright diffusions with selection and rare mutation on the geographic space \1,2,...,N\. The type 1 has fitness 0, type 2 has fitness 1 and (rare) mutation occurs from type 1 to 2 at rate m...N-1, selection is at rate s>0. The system starts in the state concentrated on type 1, the state of low fitness. We investigate this system for N ∞ on the original and large time scales. We show that for some α ∈ (0,s) at times α-1 N+t, t ∈ , N ∞ the emergence of type 2 (positive global type-2 intensity) at a global level occurs, while at times α-1 N+tN, with tN ∞ we get fixation on type 2 and on the other hand with tN -∞ as N ∞ asymptotically only type 1 is present. We describe the transition from emergence to fixation in the time scale α-1 N+t, t ∈ in the limit N ∞ by a McKean-Vlasov random entrance law. This entrance law behaves for t -∞ like e-α |t| for a positive random variable . The formation of small droplets of type-2 dominated sites in times o( N), or γ... N, γ ∈ (0,α-1) is described in the limit N ∞ by a measure-valued process following a stochastic equation driven by Poissonian type noise which we identify explicitly. The total mass of this limiting (N ∞) droplet process grows like eα t as t ∞. We prove that exit behaviour from the small time scale equals the entrance behaviour in the large time scale, namely [] =[].