Diffusion approximations of Markov chains with two time scales and applications to population genetics

Abstract

ForN= 1, 2, ···, let {(X^N(k),Y^N(k)),k= 0, 1, ···} be a homogeneous Markov chain in ℝ^mx ℝⁿ. Suppose that, asymptotically asN→ ∞, the ‘infinitesimal’ covariances and means ofX^N([·/∊_N]) area_ij(x, y) andb_i(x, y), and those ofY^N([·/δ_N]) are 0 andc_l(x, y). Assume lim_N→∞δ_N= lim_N→∞∊_N/δ_N= 0 and the zero solution ofý=c(x, y) is globally asymptotically stable. Then, under some technical conditions, it is shown that (i)X^N([·/∊_N]) converges weakly to a diffusion process with coefficientsa_ij(x, 0) andb_i(x, 0), and (ii)Y^N([t/∊_N]) → 0 in probability for everyt> 0. (The case lim_N→∞δ_N= δ_∞> 0 = lim_N→∞∊_Nis also treated.) The proof is based on the discrete-parameter analogue of a generalization of Kurtz's limit theorems for perturbed operator semigroups.The results are applied to three classes of stochastic models for random genetic drift at a multiallelic locus in a finite diploid population. The three classes involve multinomial sampling, overlapping generations, and general progeny distributions. Within each class, the monoecious, dioecious autosomal, and X-linked cases are analyzed. It is found that results for a monoecious population obtained from a diffusion approximation can be applied at once to the dioecious cases by using the appropriate effective population size and averaging allelic frequencies, selection intensities, and mutation rates, weighting each sex by the number of genes carried by an individual at the locus under consideration.