Dynamics of genetic rescue in inbred Drosophila melanogaster populations

Dynamics of genetic rescue in inbred Drosophila melanogaster populations

Genetic rescue has been proposed as a management strategy to improve the fitness of genetically eroded populations by alleviating inbreeding depression. We studied the dynamics of genetic rescue in inbred populations of Drosophila. Using balancer chromosomes, we show that the force of heterosis that...

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Bibliographic Details
Published in:Conservation genetics Vol. 11; no. 2; pp. 449 - 462
Main Authors: Bijlsma, R, Westerhof, M. D. D, Roekx, L. P, Pen, I
Format: Journal Article
Language:English
Published: Dordrecht Dordrecht : Springer Netherlands 01-04-2010
Springer Netherlands
Springer Nature B.V
Subjects:
Animal Genetics and Genomics
Biodiversity
Biomedical and Life Sciences
Chromosomes
Conservation biology
Conservation Biology/Ecology
Conservation genetics
Ecology
Evolutionary Biology
Genetics
Immigrants
Inbreeding
Insects
Life Sciences
Plant Genetics and Genomics
Population genetics
Research Article
Genetic drift
Inbreeding
Gene flow
Inbreeding depression
Genetic load
Genetic rescue
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Summary:Genetic rescue has been proposed as a management strategy to improve the fitness of genetically eroded populations by alleviating inbreeding depression. We studied the dynamics of genetic rescue in inbred populations of Drosophila. Using balancer chromosomes, we show that the force of heterosis that accompanies genetic rescue is large and allows even a recessive lethal to increase substantially in frequency in the rescued populations, particularly at stress temperatures. This indicates that deleterious alleles present in the immigrants can increase significantly in frequency in the recipient population when they are in linkage disequilibrium with genes responsible for the heterosis. In a second experiment we rescued eight inbred Drosophila populations with immigrants from two other inbred populations and observe: (i) there is a significant increase in viability both 5 and 10 generations after the rescue event, showing that the increase in fitness is not transient but persists long-term. (ii) The lower the fitness of the recipient population the larger the fitness increase. (iii) The increase in fitness depends significantly on the origin of the rescuers. The immigrants used were fixed for a conditional lethal that was mildly deleterious at 25°C but lethal at 29°C. By comparing fitness at 25°C (the temperature during the rescue experiment) and 29°C, we show that the lethal allele reached significant frequencies in most rescued populations, which upon renewed inbreeding became fixed in part of the inbred lines. In conclusion, in addition to the fitness increase genetic rescue can easily result in a substantial increase in the frequency of mildly deleterious alleles carried by the immigrants. This can endanger the rescued population greatly when it undergoes recurrent inbreeding. However, using a sufficient number of immigrants and to accompany the rescue event with the right demographic measures will overcome this problem. As such, genetic rescue still is a viable option to manage genetically eroded populations.
Bibliography:http://dx.doi.org/10.1007/s10592-010-0058-z
ISSN:1566-0621
1572-9737
DOI:10.1007/s10592-010-0058-z