Importance of spatial habitat structure on establishment of host defenses against brood parasitism

We used metapopulation dynamics to develop a mathematical simulationmodel for brood parasites and their hosts in order to investigatethe validity of the "spatial habitat structure hypothesis,"which states that a low level of parasite egg rejection in hostpopulations is due to the immigration of acceptor individualsfrom nonparasitized populations. In our model, we varied dispersalrate and the relative carrying capacity of host individualsin parasitized and unparasitized patches. When both the relativecarrying capacity in the parasite-free patch and the dispersalrate increase, the nonparasitized patch will provide more acceptorindividuals to the parasite-prone patch. As the relative carryingcapacity in the parasite-free patch increases, the equilibriumfrequency of rejecters both in the parasite-prone and in theparasite-free patch decreases toward zero for intermediate levelsof the dispersal rate. Although the rejecter strategy is moreadaptive than the acceptor strategy in the parasite-prone patch,large numbers of acceptors are produced in the parasite-freepatch dispersing to the parasitized patch. As the number ofindividuals in the parasite-free patch increases, parasitismrate can be maintained stable at a high equilibrium level inthe parasite-prone patch.