Recent theory suggests that animals should switch facultatively among canonical movement modes as a complex function of internal state, landscape characteristics, motion capacity, and navigational capacity. We tested the generality of this paradigm for free-ranging elk (Cervus elaphus) over 5 orders of magnitude in time (minutes to years) and space (meters to 100 km). At the coarsest spatiotemporal scale, elk shifted from a dispersive to a home-ranging phase over the course of 1-3 years after introduction into a novel environment. At intermediate spatiotemporal scales, elk continued to alternate between movement modes. During the dispersive phase, elk alternated between encamped and exploratory modes, possibly linked to changes in motivational goals from foraging to social bonding. During the home-ranging phase, elk movements were characterized by a complex interplay between attraction to preferred habitat types and memory of previous movements across the home-range. At the finest temporal and spatial scale, elk used area-restricted search while browsing, interspersed with less sinuous paths when not browsing. Encountering a patch of high-quality food plants triggered the switch from one mode to the next, creating biphasic movement dynamics that were reinforced by local resource heterogeneity. These patterns suggest that multiphasic structure is fundamental to the movement patterns of elk at all temporal and spatial scales tested.elk ͉ foraging ͉ group formation ͉ motivation
Species differing in life history attributes vary in their responses to features within a shared landscape. We evaluated genetic structure of sympatric gartersnake species in Southwestern Ontario, Canada and south-east Michigan, U.S.A., where habitat fragmentation is high due to agriculture and urbanization. We surveyed genetic structure of the habitat specialist, Butler’s gartersnake (Thamnophis butleri; Cope, 1889) and habitat generalist, eastern gartersnake (Thamnophis sirtalis sirtalis; Linnaeus, 1758) using DNA microsatellites. Bayesian clustering, Discriminant Analysis of Principal Components, and pairwise population comparisons revealed genetic differentiation among three major regional clusters of Butler’s gartersnake with evidence of further division within one. Genetic clustering of Butler’s gartersnake suggest that inhospitable habitat limits dispersal. Eastern gartersnakes showed less structure, with assignment tests implying a single genetic cluster. We found positive significant Mantel’s r for both species in the smallest distance class (<15 kms), but significant isolation by distance for Thamnophis butleri only. These findings together imply that connectivity for eastern gartersnakes is less impacted by habitat loss and fragmentation or that we were less able to detect their effects. Our study shows the value of multispecies comparisons in studies seeking to understand the underlying causes of genetic structure in natural populations.
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