Are there Ubiquitous Parasite-driven Major Histocompatibility Complex Selection Mechanisms in Gray Mouse Lemurs?

摘要

A major goal of evolutionary biology is to understand how selection drives local adaptation. For example, the major histocompatibility complex (MHC) plays an important role in the immune system, and high levels of MHC variation are thought to be a form of adaptation in natural populations. Individual MHC composition may influence parasite resistance via advantages associated with 1) heterozygosity, because heterozygotes recognize a broader range of different antigens than homozygotes (heterozygote advantage); 2) highly variable amino acid sequences in MHC alleles, allowing individuals to bind a broader spectrum of parasite-derived peptides (divergent-alleles advantage, a mechanistic variant of the heterozygote advantage model); or 3) specific MHC alleles (rare allele advantage or frequency dependent selection). We investigated relationships between gastrointestinal nematode burden and both adaptive immune gene variability (MHC class II DRB) and neutral microsatellites in free-living gray mouse lemurs (Microcebus murinus) native to a dry deciduous forest population in western Madagascar to test these hypotheses. The individual MHC composition was related to parasite infestation. Specific MHC alleles were involved in parasite resistance and the presence of common alleles negatively influenced infestation intensity. We found no support for the heterozygote advantage hypothesis, but we did find support for the divergent-MHC allele advantage hypothesis: Individuals with very divergent MHC alleles carried fewer and less intense nematode infestations than individuals with more similar alleles in the more variable dry deciduous forest population. These results indicate that intestinal parasites are important selection pressures under natural conditions and suggest that different selection mechanisms are not mutually exclusive. In contrast, we detected no association between neutral overall individual genetic diversity (measured via 17 microsatellites) and parasite load. Finally, we investigated the ubiquity of parasite-driven selection mechanisms by comparing our results with a previous study of a mouse lemur population from the climatically different littoral forest in southeastern Madagascar, ca. 500 km away. This revealed that different specific MHC alleles were involved in parasite resistance in the 2 habitats, showing that gene-parasite associations are not consistent between populations.