Diffusion model of intergroup selection, with special reference to evolution of an altruistic character

Abstract

Assume a diploid species consisting of an infinite number of competing demes, each having N _e reproducing members and in which mating is at random. Then consider a locus at which a pair of alleles A and A ′ are segregating, where A ′ is the “altruistic allele,” which has selective disadvantage s ′ relative to A with respect to individual selection, but which is beneficial for a deme in competition with other demes; namely, a deme having A ′ with frequency x has the advantage c ( x — ¯x ) relative to the average deme, where c is a positive constant and ¯x is the average of x over the species. Let ϕ = ϕ( x;t ) be the distribution function of x among demes in the species at time t . Then, we have ∂ϕ/∂ t = L (ϕ) + c ( x — ¯x )ϕ, where L is the Kolmogorov forward differential operator commonly used in population genetics [i.e., L = (1/2) (∂ ² /∂ x ² ) V _{δ x} — (∂/∂ x ) M _{δ x} ], and M _{δ x} and V _{δ x} stand for the mean and variance of the change in x per generation within demes. As to migration, assume Wright's island model and denote by m the migration rate per deme per generation. By investigating the steady state, in which mutation, migration, random drift, and intra- and interdeme selection balance each other, it is shown that the index D = c/m — 4 N _e s′ serves as a good indicator for predicting which of the two forces (i.e., group selection or individual selection) prevails; if D > 0, the altruistic allele predominates, but if D < 0, it becomes rare and cannot be established in the species.