Rapid parallel evolutionary changes of gene transcription profiles in farmed Atlantic salmon

Roberge, Christian; Einum, Sigurd; Guderley, Helga; Bernatchez, Louis

doi:10.1111/j.1365-294x.2005.02807.x

Cited by 125 publications

(204 citation statements)

References 51 publications

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“…This suggests that diversifying selection between wild and hatchery strain trout involves different loci than those under selection among wild populations. Although this latter point is based on analysis of relatively few loci, it does receive support from an analysis of transcriptome differences between farmed and wild Atlantic salmon (Roberge et al, 2006). Here, farmed and wild salmon showed considerable divergence, but different farmed strains of European and North American origin showed convergence at the transcriptome level, indicating parallel evolution during the domestication process.…”

Section: Diversifying Selection In Hatchery Versus Wild Troutmentioning

confidence: 99%

An assessment of the spatial scale of local adaptation in brown trout (Salmo trutta L.): footprints of selection at microsatellite DNA loci

et al. 2011

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Local adaptation is considered a paradigm in studies of salmonid fish populations. Yet, little is known about the geographical scale of local adaptation. Is adaptive divergence primarily evident at the scale of regions or individual populations? Also, many salmonid populations are subject to spawning intrusion by farmed conspecifics that experience selection regimes fundamentally different from wild populations. This prompts the question if adaptive differences between wild populations and hatchery strains are more pronounced than between different wild populations? We addressed these issues by analyzing variation at 74 microsatellite loci (including anonymous and expressed sequence tag-and quantitative trait locus-linked markers) in 15 anadromous wild brown trout (Salmo trutta L.) populations, representing five geographical regions, along with two lake populations and two hatchery strains used for stocking some of the populations. F ST -based outlier tests revealed more outlier loci between different geographical regions separated by 522 ± 228 km (mean ± s.d.) than between populations within regions separated by 117±79 km (mean±s.d.). A significant association between geographical distance and number of outliers between regions was evident. There was no evidence for more outliers in comparisons involving hatchery trout, but the loci under putative selection generally were not the same as those found to be outliers between wild populations. Our study supports the notion of local adaption being increasingly important at the scale of regions as compared with individual populations, and suggests that loci involved in adaptation to captive environments are not necessarily the same as those involved in adaptive divergence among wild populations.

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Section: Diversifying Selection In Hatchery Versus Wild Troutmentioning

confidence: 99%

An assessment of the spatial scale of local adaptation in brown trout (Salmo trutta L.): footprints of selection at microsatellite DNA loci

et al. 2011

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“…Therefore, it is not surprising that RNA-seq has become the technology of choice for quantifying differential gene expression (Deng et al, 2011;Smith et al, 2013). Gene expression analyses have allowed the identification of key molecular mechanisms underlying desired traits in farmed fish (Roberge et al, 2006;Ferraresso et al, 2008Ferraresso et al, , 2013, but have also been successfully applied to natural populations of marine fishes (Whitehead and Crawford, 2006;Larsen et al, 2007Larsen et al, , 2011Pujolar et al, 2012Pujolar et al, , 2013bCôté et al, 2014). Finally, transcriptomic analyses can be complemented and integrated with protein expression analysis to investigate the responses at the proteomic level for a deeper understanding of functional implications (Nie et al, 2007;Dalziel and Schulte, 2012).…”

Section: Linking Genotype and Phenotypementioning

confidence: 99%

Population Genomics of Marine Fishes: Next-Generation Prospects and Challenges

Hemmer‐Hansen

Therkildsen

Pujolar

2014

The Biological Bulletin

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“…Moreover, relaxed selection resulting from absence of predators, constant supply of food and medical treatment, as well as increased genetic drift caused by small effective population sizes may favor the accumulation of deleterious alleles. Furthermore, genetic changes unrelated to adaptation to captivity are bound to occur as a result of founder effects in the farmed populations (Roberge et al, 2006). Consequently, change in the genetic composition of captive populations has been observed in many studies on farmed Atlantic salmon of northern Europe (Skaala et al, 2004).…”

Section: Introductionmentioning

confidence: 99%

Temporal change in genetic integrity suggests loss of local adaptation in a wild Atlantic salmon (Salmo salar) population following introgression by farmed escapees

Bourret

O’Reilly

Carr³

et al. 2011

Heredity

115

101

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In some wild Atlantic salmon populations, rapid declines in numbers of wild returning adults has been associated with an increase in the prevalence of farmed salmon. Studies of phenotypic variation have shown that interbreeding between farmed and wild salmon may lead to loss of local adaptation. Yet, few studies have attempted to assess the impact of interbreeding at the genome level, especially among North American populations. Here, we document temporal changes in the genetic makeup of the severely threatened Magaguadavic River salmon population (Bay of Fundy, Canada), a population that might have been impacted by interbreeding with farmed salmon for nearly 20 years. Wild and farmed individuals caught entering the river from 1980 to 2005 were genotyped at 112 single-nucleotide polymorphisms (SNPs), and/or eight microsatellite loci, to scan for potential shifts in adaptive genetic variation. No significant temporal change in microsatellite-based estimates of allele richness or gene diversity was detected in the wild population, despite its precipitous decline in numbers over the last two decades. This might reflect the effect of introgression from farmed salmon, which was corroborated by temporal change in linkage-disequilibrium. Moreover, SNP genome scans identified a temporal decrease in candidate loci potentially under directional selection. Of particular interest was a SNP previously shown to be strongly associated with an important quantitative trait locus for parr mark number, which retained its genetic distinctiveness between farmed and wild fish longer than other outliers. Overall, these results indicate that farmed escapees have introgressed with wild Magaguadavic salmon resulting in significant alteration of the genetic integrity of the native population, including possible loss of adaptation to wild conditions.

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Rapid parallel evolutionary changes of gene transcription profiles in farmed Atlantic salmon

Cited by 125 publications

References 51 publications

An assessment of the spatial scale of local adaptation in brown trout (Salmo trutta L.): footprints of selection at microsatellite DNA loci

An assessment of the spatial scale of local adaptation in brown trout (Salmo trutta L.): footprints of selection at microsatellite DNA loci

Population Genomics of Marine Fishes: Next-Generation Prospects and Challenges

Temporal change in genetic integrity suggests loss of local adaptation in a wild Atlantic salmon (Salmo salar) population following introgression by farmed escapees

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