Abstract
Understanding the spatial scale at which selection acts upon adaptive genetic variation in natural populations is fundamental to our understanding of evolutionary ecology, and has important ramifications for conservation. The environmental factors to which individuals of a population are exposed can vary at fine spatial scales, potentially generating localized patterns of adaptation. Here, we compared patterns of neutral and major histocompatibility complex (MHC) variation within an island population of Berthelot's pipit (Anthus berthelotii) to assess whether landscape-level differences in pathogen-mediated selection generate fine-scale spatial structuring in these immune genes. Specifically, we tested for spatial associations between the distribution of avian malaria, and the factors previously shown to influence that distribution, and MHC variation within resident individuals. Although we found no overall genetic structure across the population for either neutral or MHC loci, we did find localized associations between environmental factors and MHC variation. One MHC class I allele (ANBE48) was directly associated with malaria infection risk, while the presence of the ANBE48 and ANBE38 alleles within individuals correlated (positively and negatively, respectively) with distance to the nearest poultry farm, an anthropogenic factor previously shown to be an important determinant of disease distribution in the study population. Our findings highlight the importance of considering small spatial scales when studying the patterns and processes involved in evolution at adaptive loci.
Highlights
Understanding the spatial scale at which selection acts upon adaptive genetic variation in natural populations provides information on the degree of local adaptation of populations, and potentially, on initial steps in the speciation process (Chave 2013)
We assessed fine-scale structure at neutral markers and at major histocompatibility complex (MHC) class I loci in relation to environmental factors within a population of Berthelot’s pipit
We found no evidence of consistent population-wide genetic structure for either set of markers
Summary
Understanding the spatial scale at which selection acts upon adaptive genetic variation in natural populations provides information on the degree of local adaptation of populations, and potentially, on initial steps in the speciation process (Chave 2013). Assessment of the spatial scale of evolutionary processes provides information on the epidemiology of wildlife. Pathogens can be strong selective agents in wild host populations (Haldane 1949; Fumagalli et al 2011), and their distribution is highly dependent on environmental factors (Ostfeld et al 2005). Both climatic and anthropogenic factors can affect the distribution of pathogenic disease Assessment of the scale of selection pressures exerted by pathogens on immune genes is important for understanding the patterns of disease epidemiology and transmission in the landscape
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