Abstract
BackgroundSelective breeding is a relatively recent practice in aquaculture species compared to terrestrial livestock. Nevertheless, the genetic variability of farmed salmonid lines, which have been selected for several generations, should be assessed. Indeed, a significant decrease in genetic variability due to high selection intensity could have occurred, potentially jeopardizing the long-term genetic progress as well as the adaptive capacities of populations facing change(s) in the environment. Thus, it is important to evaluate the impact of selection practices on genetic diversity to limit future inbreeding. The current study presents an analysis of genetic diversity within and between six French rainbow trout (Oncorhynchus mykiss) experimental or commercial lines based on a medium-density single nucleotide polymorphism (SNP) chip and various molecular genetic indicators: fixation index (FST), linkage disequilibrium (LD), effective population size (Ne) and inbreeding coefficient derived from runs of homozygosity (ROH).ResultsOur results showed a moderate level of genetic differentiation between selected lines (FST ranging from 0.08 to 0.15). LD declined rapidly over the first 100 kb, but then remained quite high at long distances, leading to low estimates of Ne in the last generation ranging from 24 to 68 depending on the line and methodology considered. These results were consistent with inbreeding estimates that varied from 10.0% in an unselected experimental line to 19.5% in a commercial line, and which are clearly higher than corresponding estimates in ruminants or pigs. In addition, strong variations in LD and inbreeding were observed along the genome that may be due to differences in local rates of recombination or due to key genes that tended to have fixed favorable alleles for domestication or production.ConclusionsThis is the first report on ROH for any aquaculture species. Inbreeding appeared to be moderate to high in the six French rainbow trout lines, due to founder effects at the start of the breeding programs, but also likely to sweepstakes reproductive success in addition to selection for the selected lines. Efficient management of inbreeding is a major goal in breeding programs to ensure that populations can adapt to future breeding objectives and SNP information can be used to manage the rate at which inbreeding builds up in the fish genome.
Highlights
Selective breeding is a relatively recent practice in aquaculture species compared to terrestrial live‐ stock
Selective breeding can contribute to a significant decrease in the genetic variability of farmed populations, jeopardizing long-term genetic progress as well as reducing the adaptive capacities of populations in the event of a change in the environment [7]
Our findings provide the breeding companies a better understanding of the genetic diversity in their rainbow trout lines in order to implement efficient breeding programs
Summary
Selective breeding is a relatively recent practice in aquaculture species compared to terrestrial live‐ stock. The current study presents an analysis of genetic diversity within and between six French rainbow trout (Oncorhynchus mykiss) experimental or commercial lines based on a medium-density single nucleotide polymorphism (SNP) chip and various molecular genetic indicators: fixation index (FST), linkage disequilib‐ rium (LD), effective population size (Ne) and inbreeding coefficient derived from runs of homozygosity (ROH). Rainbow trout (Oncorhynchus mykiss) is native to the Pacific drainages of North America and to Kamchatka in Russia This fish was introduced at the end of the nineteenth century to waters on all continents except Antarctica, for recreational angling and aquaculture purposes. Selective breeding can contribute to a significant decrease in the genetic variability of farmed populations, jeopardizing long-term genetic progress as well as reducing the adaptive capacities of populations in the event of a change in the environment [7]. Greater genetic variability within a population increases the likelihood that some of its individuals will have alleles that are better adapted to environmental fluctuations and are likely to survive and to transmit to their offspring alleles and favorable genetic characteristics
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