Population connectivity in voles (Microtus sp.) as a gauge for tall grass prairie restoration in midwestern North America

• Published in: PloS one Vol. 16; no. 12; p. e0260344
• Main Authors: Douglas, Marlis R, Mussmann, Steven M, Chafin, Tyler K, Anthonysamy, Whitney J B, Davis, Mark A, Mulligan, Matthew P, Schooley, Robert L, Louis, Wade, Douglas, Michael E
• Format: Journal Article
• Language: English
• Published: United States Public Library of Science 09.12.2021; Public Library of Science (PLoS)
• Subjects: Agricultural land; Analysis; Animals; Anthropogenic factors; Arvicolinae - classification; Arvicolinae - genetics; Arvicolinae - physiology; Bayes Theorem; Bayesian analysis; Biodiversity; Biology and Life Sciences; Clustering; Connectivity; Conservation; Demographics; Deoxyribonucleic acid; Dispersal; Dispersion; DNA; Earth Sciences; Ecological restoration; Ecology and Environmental Sciences; Environmental protection; Environmental restoration; Environmental Restoration and Remediation; Estimates; Evaluation; Female; Gauges; Gene Flow; Genetic structure; Genetic Variation; Genetics, Population; Grasses; Grassland; Grasslands; Growth; Habitats; Landscape; Methods; Microsatellite Repeats; Microtus ochrogaster; Natural resources; North America; Permeability; Population; Population (statistical); Population Density; Population Dynamics; Population genetics; Population number; Recolonization; Restoration; Seasons; Social behavior; Statistical methods; Voles; Wildlife conservation; North America; United States; United States > US; Arkansas; Illinois
• ISSN: 1932-6203; 1932-6203
• DOI: 10.1371/journal.pone.0260344

Ecological restoration can promote biodiversity conservation in anthropogenically fragmented habitats, but effectiveness of these management efforts need to be statistically validated to determine 'success.' One such approach is to gauge the extent of recolonization as a measure of landscape permeability and, in turn, population connectivity. In this context, we estimated dispersal and population connectivity in prairie vole (Microtus ochrogaster; N = 231) and meadow vole (M. pennsylvanicus; N = 83) within five tall-grass prairie restoration sites embedded within the agricultural matrix of midwestern North America. We predicted that vole dispersal would be constrained by the extent of agricultural land surrounding restored habitat patches, spatially isolating vole populations and resulting in significant genetic structure. We first employed genetic assignment tests based on 15 microsatellite DNA loci to validate field-derived species-designations, then tested reclassified samples with multivariate and Bayesian clustering to assay for spatial and temporal genetic structure. Population connectivity was further evaluated by calculating pairwise FST, then potential demographic effects explored by computing migration rates, effective population size (Ne), and average relatedness (r). Genetic species assignments reclassified 25% of initial field identifications (N = 11 M. ochrogaster; N = 67 M. pennsylvanicus). In M. ochrogaster population connectivity was high across the study area, reflected in little to no spatial or temporal genetic structure. In M. pennsylvanicus genetic structure was detected, but relatedness estimates identified it as kin-clustering instead, underscoring social behavior among populations rather than spatial isolation as the cause. Estimates of Ne and r were stable across years, reflecting high dispersal and demographic resilience. Combined, these metrics suggest the agricultural matrix is highly permeable for voles and does not impede dispersal. High connectivity observed confirms that the restored landscape is productive and permeable for specific management targets such as voles and also demonstrates population genetic assays as a tool to statistically evaluate effectiveness of conservation initiatives.