High genetic diversity in the blue-listed British Columbia population of the purple martin maintained by multiple sources of immigrants

To assess genetic diversity in the blue-listed purple martin (Progne subis) population in British Columbia, we analysed mitochondrial control region sequences of 93 individuals from British Columbia and 121 individuals collected from seven localities of the western and eastern North American subspec...

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Bibliographic Details
Published in:Conservation genetics 2008-06, Vol.9 (3), p.495-505
Main Authors: Baker, Allan J, Greenslade, Annette D, Darling, Laura M, Finlay, J. Cam
Format: Article
Language:English
Subjects:
Animal Genetics and Genomics
Animal populations
Biodiversity
Biomedical and Life Sciences
Birds
Blue-listed population
Conservation Biology/Ecology
Ecology
Evolutionary Biology
Gene flow
Genetic diversity
genetic variation
Haplotypes
Immigrants
Inbreeding
Life Sciences
Migrant-pool recolonization
Migrants
Nest box recovery
Plant Genetics and Genomics
Progne subis
Purple martin
Recolonization
Research Article
Studies
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Summary:To assess genetic diversity in the blue-listed purple martin (Progne subis) population in British Columbia, we analysed mitochondrial control region sequences of 93 individuals from British Columbia and 121 individuals collected from seven localities of the western and eastern North American subspecies P. s. arboricola and P. s. subis, respectively. Of the 47 haplotypes we detected, 34 were found exclusively in western populations, and 12 were found only in eastern populations. The most common eastern haplotype (25) was also found in three nestlings in British Columbia and one in Washington. Another British Columbia nestling had a haplotype (35) that differed by a C to T transition from haplotype 25. Coalescent analysis indicated that these five nestlings are probably descendents of recent immigrants dispersing from east to the west, because populations were estimated to have diverged about 200,000-400,000 ybp, making ancestral polymorphism a less likely explanation. Maximum likelihood estimates of gene flow among all populations detected asymmetrical gene flow into British Columbia not only of rare migrants from the eastern subspecies in Alberta but also a substantial number of migrants from the adjacent Washington population, and progressively lower numbers from Oregon in an isolation-by distance pattern. The influx of migrants from different populations is consistent with the migrant-pool model of recolonization which has maintained high genetic diversity in the small recovering population in British Columbia. Thus, the risk to this population is not from genetic erosion or inbreeding following a severe population crash, but from demographic stochasticity and extinction in small populations.
ISSN:1566-0621
1572-9737
DOI:10.1007/s10592-007-9358-3