Role of selection versus neutral processes determining genetic variation in a small mammal along a climatic gradient in southern Africa

Empirical evidence is accumulating that pathogens drive selection and explain common patterns of high immune gene (major histocompatibility complex, MHC) polymorphism. While most previous studies have identified that selection has acted over large time scales on the MHC, there still is a paucity of information in mammal species that demonstrates how processes operate on MHC genes in extant generations. Here we investigated 439 striped mouse individuals (Rhabdomys pumilio), trapped across seven different locations along a climatic gradient in southern Africa. Data from a previous study, conducted in the same study system, revealed that gastro-intestinal nematode infections were higher in individuals from study sites located within wetter climates compared to those from drier ones. In order to improve our understanding about the role of parasite-driven selection on the MHC in contemporary generations we tested for population divergences based on seven neutral microsatellite markers and the MHC DRB exon II locus. If divergences exist, we wanted to know if they are influenced by the spatial variation in parasite pressure mediated by different climatic conditions along the study site transect. Our analysis revealed an extensive polymorphism of 249 different MHC alleles and isolation-by-distance showed significant correlations at the microsatellite loci but not at the MHC. Nematode pressure was lowest at the driest site (Fish River Canyon, Namibia) and specifically this population revealed the highest divergence between MHC and microsatellite loci. We conclude that spatial variation in parasite pressure can facilitate local immune gene adaptations and thus mediate interactions of directional and balancing selection shaping MHC polymorphism in contemporary generations.