Genotype diversity promotes the persistence of Daphnia populations exposed to severe copper stress

When environmental stressors of high intensity are sustained for long periods of time, populations face high probabilities of being extirpated. However, depending on the intensity of the stressor, large populations with sufficient genetic diversity may persist. We report the results of an experiment...

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Bibliographic Details
Published in:Journal of evolutionary biology 2022-02, Vol.35 (2), p.265-277
Main Authors: Loria, Alessandra, Cristescu, Melania E., Gonzalez, Andrew
Format: Article
Language:English
Subjects:
adaptation
Animals
Biological Evolution
Carrying capacity
Contamination
Copper
Copper - toxicity
Daphnia
Daphnia - genetics
Environmental stress
Evolution
Experiments
extirpation
Genetic diversity
Genetic Variation
Genotype
Genotypes
persistence
pollution
Population
Population genetics
Populations
Species extinction
Survival analysis
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Summary:When environmental stressors of high intensity are sustained for long periods of time, populations face high probabilities of being extirpated. However, depending on the intensity of the stressor, large populations with sufficient genetic diversity may persist. We report the results of an experiment that tracked the persistence of Daphnia populations exposed to copper contamination. We assessed whether genotypic diversity reduced the risk of extinction. We created monoclonal and multiclonal populations and monitored their population sizes during a 32‐week experiment. Cu was applied at a sub‐lethal concentration and then increased every week until the population sizes dropped to about 10% of the carrying capacity (Cu at 180 μg/L). The concentration was then increased up to 186 μg/L and held stable until the end of the experiment. A survival analysis showed that clonal diversity extended the persistence of Daphnia populations, but copper contamination caused a substantial genetic erosion followed by population extirpation. However, some Cu‐treated populations, mostly multiclonal, showed U‐shaped patterns of growth consistent with evolutionary rescue but these did not lead to lasting population recovery. These results highlight the importance of genetic variation for population persistence, but they also show how quickly it can be lost in contaminated environments. Genetic diversity extends survival time in Daphnia populations but it is negatively affected by Cu contamination which may lead to a substantial genetic erosion followed by populations' extirpation.
ISSN:1010-061X
1420-9101
DOI:10.1111/jeb.13979