Natural selection and climate change in chipmunks\' evolutionary history (Sciuridae:Tamias)

The aim of this study was to understand how natural selection acts on phenotypic variation to determine species\' response to environmental change. I used chipmunks of the genus Tamias (subgenus Neotamias; family Sciuridae) as a model at both a macro and micro-evolutionary scales. This set of 23 species is part of a recent radiation that occupy a wide range of habitats with marked niche partitioning among co-distributed members. As climate variation is an essential aspect believed to shape phenotypic evolution, in the first chapter I examined how phenotypic differences among these species were related to climatic differences among the habitats occupied. Several climatic variables were significantly correlated with morphological attributes differentiating taxa, suggesting a possible causal link between climate, through selection, and species divergence. As a consequence, it is reasonable to suggest that climate change within historic times (the Anthropocene) has also affected cranial morphological variation within species at a microevolutionary scale. In the second chapter, therefore, I examined this expectation using specimens from six different species, each collected about 100 generations apart (one century). Here, no relationship was found between the degree of climate change over this period and the magnitude of observed morphological change, or in a measure of selection strength. Nevertheless, the estimates of selection strength varied substantially among these species: those for the alpine chipmunk (Tamias alpinus) were the strongest and nearly twice that of the co-distributed lodgepole chipmunk (Tamias speciosus). As a result, to assess the impact of directional selection on the observed patterns of phenotypic (co)variation, in the third chapter I contrasted these two species, since they represent the extremes in the estimated strength of selection among all the species\' populations I examined. Theory predicts that, under directional selection, patterns of phenotypic (co)variation might evolve in order to match the subjacent adaptive landscape. This prediction was upheld in the populations of alpine chipmunks, as perhaps expected since they exhibited the strong selective response. Equally importantly, I also observed changes in the overall correlation between traits for the alpine chipmunk in a pattern consistent with that expected under theoretical models that consider the evolution of the genotype-phenotype map in response to directional selection (AU)