Dispersal in a Plain Landscape: Short-Distance Genetic Differentiation in Southwestern Manitoba Wolves, Canada

The effects of human-caused fragmentation require further study in landscapes where physical dispersal barriers and natural ecological transitions can be discounted as causes for population genetic structure. We predict that fragmentation can reduce dispersal across such barrier-free landscapes because dispersal also is limited by a perception of risk. Considerable fragmentation has occurred in the Riding Mountain National Park (RMNP) region in Manitoba, Canada, during the past 60 years. We examine data from 13 autosomal microsatellites to determine whether fragmentation is correlated with genetic population structure in wolves (Canis lupus). Moderate and significant differentiation between RMNP and a genetic cluster identified 30 km farther north (FST = 0.053, 95% CI [0.031–0.073]) is consistent with predicted effects of fragmentation. The RMNP population cluster represents at least seven wolf packs followed weekly by radio tracking during 2003–2006. Distinct mtDNA haplotypes have been identified in the Park and no successful wolf dispersal from RMNP has been documented in several multi-year tracking studies since 1974. Tracking data also indicate that some wolves might be reluctant to leave RMNP. Although the influence of behaviour and local adaptation require investigation, human-caused fragmentation appears to have caused cryptic genetic structure on fine spatiotemporal scales in a vagile species that is: (1) not influenced by physical movement barriers or historical ecological discontinuities in our study area, and; (2) able to live relatively close to humans. The Great Plains is now an intensely human-managed landscape. Detection of cryptic genetic structure could therefore function as an important indicator in conservation management

Wolf Body Mass, Skull Morphology, and Mitochondrial DNA Haplotypes in the Riding Mountain National Park Region of Manitoba, Canada

Two types of wolves, gray (Canis lupus L., 1758) and eastern (Canis lupus lycaon Schreber, 1775 or Canis lycaon) or Great Lakes wolves, representing Old World (OW) and New World (NW) mitochondrial DNA (mtDNA) haplotypes, have been reported in eastern Canada and the Great Lakes region. Both haplotypes were found in Duck Mountain Provincial Park and Forest, Manitoba. Only OW haplotypes have been reported from the isolated Riding Mountain National Park (RMNP), 30 km to the south. Wolves with NW haplotypes hybridize with C. lupus and coyotes (Canis latrans Say, 1823) and could mediate gene flow between canids. We examined available data on wolf body mass, skull morphology, and mtDNA from the RMNP region, as well as mtDNA from Manitoba and Saskatchewan, to assess the occurrence of NW haplotypes in wolves and possible canid hybridization. Mean body mass of female (n = 54) and male (n = 42) RMNP wolves during 1985–1987 was higher than that of females (n = 12) and males (n = 8) during 1999–2004. Thirteen skull measures from 29 wolf skulls did not suggest significant differences between RMNP and Duck Mountain wolves. Nineteen of 20 RMNP samples had OW haplotypes, whereas one clustered together with NW haplotypes

Canid hybridization:Contemporary evolution in human-modified landscapes

Contemporary evolution through human-induced hybridization occurs throughout the taxonomic range. Formerly allopatric species appear especially susceptible to hybridization. Consequently, hybridization is expected to be more common in regions with recent sympatry owing to human activity than in areas of historical range overlap. Coyotes (Canis latrans) and gray wolves (C. lupus) are historically sympatric in western North America. Following European settlement gray wolf range contracted, whereas coyote range expanded to include eastern North America. Furthermore, wolves with New World (NW) mitochondrial DNA (mtDNA) haplotypes now extend from Manitoba to Québec in Canada and hybridize with gray wolves and coyotes. Using mtDNA and 12 microsatellite markers, we evaluated levels of wolf-coyote hybridization in regions where coyotes were present (the Canadian Prairies, n = 109 samples) and absent historically (Québec, n = 154). Wolves with NW mtDNA extended from central Saskatchewan (51°N, 69°W) to northeastern Québec (54°N, 108°W). On the Prairies, 6.3% of coyotes and 9.2% of wolves had genetic profiles suggesting wolf-coyote hybridization. In contrast, 12.6% of coyotes and 37.4% of wolves in Québec had profiles indicating hybrid origin. Wolves with NW and Old World (C. lupus) mtDNA appear to form integrated populations in both regions. Our results suggest that hybridization is more frequent in historically allopatric populations. Range shifts, now expected across taxa following climate change and other human influence on the environment, might therefore promote contemporary evolution by hybridization

Noble Magnificence: Cultures of the Performing Arts in Rome, 1644-1740

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