Genetic resilience of Daphnia populations following experimental removal of introduced fish

Dramatic changes in environmental conditions or community composition may impose severe selective pressures on resident populations. These changes in the selective regime can lead to demographic bottlenecks or local extinction. The consequence of demographic contraction is often a reduction of stand...

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Bibliographic Details
Published in:Conservation genetics 2010-10, Vol.11 (5), p.1737-1745
Main Authors: Latta, Leigh C. IV, Fisk, Debra L, Knapp, Roland A, Pfrender, Michael E
Format: Article
Language:English
Subjects:
Animal Genetics and Genomics
Biodiversity
Community composition
Conservation biology
Conservation Biology/Ecology
Crustaceans
Ecology
Egg bank
Environmental changes
Environmental conditions
Evolutionary Biology
Fish
Fish populations
Genetic diversity
Genetic markers
Genetic resilience
Hatching
Introduced fish
Life Sciences
Local extinction
microsatellite repeats
mitochondrial DNA
Plant Genetics and Genomics
Population genetics
quantitative genetics
Research Article
Reservoirs
Zooplankton
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Summary:Dramatic changes in environmental conditions or community composition may impose severe selective pressures on resident populations. These changes in the selective regime can lead to demographic bottlenecks or local extinction. The consequence of demographic contraction is often a reduction of standing genetic variation. Since the level of adaptive genetic variation in populations plays an important role in persistence and adaptive response, understanding genetic resilience and the time course for re-establishment of genetic diversity following demographic perturbations is a critical component of assessing the consequences of changing environments. The introduction of nonnative fish into historically fishless lakes is a particularly dramatic environmental change frequently contributing to demographic bottlenecks and local extinction of native populations. We examine the quantitative- and molecular-genetic recovery of two alpine populations of the zooplankton Daphnia melanica from the Sierra Nevada, California, USA. These populations were extirpated by introduced salmonids and subsequently re-established following the experimental removal of nonnative fish. We obtained data for nuclear and mitochondrial markers and conducted a common-garden experiment to assess the levels of molecular- and quantitative-genetic variation following experimental fish removal. Reestablished D. melanica populations attained levels of nuclear genetic diversity only slightly lower than surrounding fishless populations in the first year following fish removal and substantial mitochondrial and quantitative-genetic diversity within 8 years. This high level of genetic resilience was likely facilitated by multiple sources of genetic variation, including immigration from neighboring populations and hatching from a local reservoir of diapausing eggs. Our results highlight the genetic resilience of taxa with reservoirs of genetic variation in seed or egg banks.
ISSN:1566-0621
1572-9737
DOI:10.1007/s10592-010-0067-y