Temporal and region‐specific variations in genome‐wide inbreeding effects on female size and reproduction traits of rainbow trout

Paul, Katy; d'Ambrosio, Jonathan; Phocas, Florence

doi:10.1111/eva.13308

Cited by 12 publications

(15 citation statements)

References 171 publications

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“…Similarly, the first application of genomic selection and genome‐wide association studies for growth traits in rock bream ( Oplegnathus fasciatus ), a valued species for marine aquaculture in Asia, has been recently reported (Gong et al, 2021 ). Incorporation of genomic information can also be a useful approach to assess the levels of inbreeding, their effect on economically important traits and even the genomic regions affecting changes in performance of breeding populations, as it has been recently demonstrated for female size and reproduction traits in rainbow trout (Paul et al, 2021 ).…”

Section: Modern Selective Breedingmentioning

confidence: 99%

Genomics applied to livestock and aquaculture breeding

Yáñez

Carvalheiro

et al. 2022

Evolutionary Applications

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The increasing global demand for food, due to the continuous growth of human population, requires improvements in the efficiency and sustainability of animal production systems. In addition, several challenges facing farming of aquatic and terrestrial organisms need to be overcome to ensure food security in the upcoming decades, e.g. adaptation to climate change, reduced availability of conventional animal feed ingredients, emerging infectious and parasitic diseases, among others. Genomic technologies such as massive parallel sequencing, high‐throughput genotyping, genome selection and gene editing, combined with highly efficient computational methods can accelerate the rate of genetic progress in animal breeding. Thus, such technologies can help us meet the needs for protein sources for human consumption in the upcoming years. This Special Issue aims at presenting current advancements in the field of genomic tools applied to aquatic and terrestrial farmed animal populations.

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Section: Modern Selective Breedingmentioning

confidence: 99%

Genomics applied to livestock and aquaculture breeding

Yáñez

Carvalheiro

et al. 2022

Evolutionary Applications

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“…Loss of genetic variability influences the long-term survival of populations associated with reduced fitness and an eventual higher risk of extinction. For instance, in a small population of rainbow trout, in successive generations and without gene flow, the probability of mating with closely related individuals is very high, leading to inbreeding and specifically a decrease in the population structure [ 43 , 44 , 45 , 46 , 47 ]. The assessment of reproductive values in all generations showed that multi-leaf selection (with a low rate of inbreeding) has brought an average of 7% genetic gain per generation in the development of rainbow trout of market size [ 48 ].…”

Section: Rainbow Trout Farming Biological Aspects and Effects Of Clim...mentioning

confidence: 99%

“…is needed in the context of a circular economy. Aquaponics, in combination with selective breeding and thermal acclimation, are promising management strategies that may contribute to the development of a new form of rainbow trout farming [ 47 , 48 , 155 , 156 , 157 ]. Nevertheless, climate change remains a difficult obstacle for examining the genetic diversity of rainbow trout populations, a species sensitive to climate change.…”

Section: The Potential Of Rainbow Trout Farming In Aquaponicsmentioning

confidence: 99%

Aquaponics as a Promising Strategy to Mitigate Impacts of Climate Change on Rainbow Trout Culture

Vasdravanidis

Alvanou

Lattos

et al. 2022

Animals

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The impact of climate change on both terrestrial and aquatic ecosystems tends to become more progressively pronounced and devastating over the years. The sector of aquaculture is severely affected by natural abiotic factors, on account of climate change, that lead to various undesirable phenomena, including aquatic species mortalities and decreased productivity owing to oxidative and thermal stress of the reared organisms. Novel innovative technologies, such as aquaponics that are based on the co-cultivation of freshwater fish with plants in a sustainable manner under the context of controlled abiotic factors, represent a promising tool for mitigating the effect of climate change on reared fish. The rainbow trout (Oncorhynchus mykiss) constitutes one of the major freshwater-reared fish species, contributing to the national economies of numerous countries, and more specifically, to regional development, supporting mountainous areas of low productivity. However, it is highly vulnerable to climate change effects, mainly due to the concrete raceways, in which it is reared, that are constructed on the flow-through of rivers and are, therefore, dependent on water’s physical properties. The current review study evaluates the suitability, progress, and challenges of developing innovative and sustainable aquaponic systems to rear rainbow trout in combination with the cultivation of plants. Although not commercially developed to a great extent yet, research has shown that the rainbow trout is a valuable experimental model for aquaponics that may be also commercially exploited in the future. In particular, abiotic factors required in rainbow trout farming along, with the high protein proportion required in the ratios due to the strict carnivorous feeding behavior, result in high nitrate production that can be utilized by plants as a source of nitrogen in an aquaponic system. Intensive farming of rainbow trout in aquaponic systems can be controlled using digital monitoring of the system parameters, mitigating the obstacles originating from extreme temperature fluctuations.

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“…A first commercial medium-density Axiom ® Trout Genotyping array (hereafter termed 57 K chip) has then been developed ( Palti et al, 2015 ) and produced by Affymetrix (Thermofisher). Since then it has been largely used in population genetics studies ( Larson et al, 2018 ; D’Ambrosio et al, 2019 ; Paul et al, 2021 ), GWAS and GS accuracy works for various traits in farmed populations ( Gonzalez-Pena et al, 2016 ; Vallejo et al, 2017 ; Vallejo et al, 2019 ; Reis Neto et al, 2019 ; Rodríguez et al, 2019 ; Yoshida et al, 2019 ; Fraslin et al, 2019 ; Fraslin et al, 2020 ; Karami et al, 2020 ; D’Ambrosio et al, 2020 ; Blay et al, 2021a ; Blay et al, 2021b ). However, out of the 57,501 SNPs included in this chip, nearly 20,000 were found to be unusable because they were either duplicated due to the ancestral genome duplication or showing primer polymorphism in five French commercial or experimental lines ( D’Ambrosio et al, 2019 ).…”

Section: Introductionmentioning

confidence: 99%

Development of a High-Density 665 K SNP Array for Rainbow Trout Genome-Wide Genotyping

et al. 2022

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Single nucleotide polymorphism (SNP) arrays, also named « SNP chips », enable very large numbers of individuals to be genotyped at a targeted set of thousands of genome-wide identified markers. We used preexisting variant datasets from USDA, a French commercial line and 30X-coverage whole genome sequencing of INRAE isogenic lines to develop an Affymetrix 665 K SNP array (HD chip) for rainbow trout. In total, we identified 32,372,492 SNPs that were polymorphic in the USDA or INRAE databases. A subset of identified SNPs were selected for inclusion on the chip, prioritizing SNPs whose flanking sequence uniquely aligned to the Swanson reference genome, with homogenous repartition over the genome and the highest Minimum Allele Frequency in both USDA and French databases. Of the 664,531 SNPs which passed the Affymetrix quality filters and were manufactured on the HD chip, 65.3% and 60.9% passed filtering metrics and were polymorphic in two other distinct French commercial populations in which, respectively, 288 and 175 sampled fish were genotyped. Only 576,118 SNPs mapped uniquely on both Swanson and Arlee reference genomes, and 12,071 SNPs did not map at all on the Arlee reference genome. Among those 576,118 SNPs, 38,948 SNPs were kept from the commercially available medium-density 57 K SNP chip. We demonstrate the utility of the HD chip by describing the high rates of linkage disequilibrium at 2–10 kb in the rainbow trout genome in comparison to the linkage disequilibrium observed at 50–100 kb which are usual distances between markers of the medium-density chip.

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Temporal and region‐specific variations in genome‐wide inbreeding effects on female size and reproduction traits of rainbow trout

Cited by 12 publications

References 171 publications

Genomics applied to livestock and aquaculture breeding

Genomics applied to livestock and aquaculture breeding

Aquaponics as a Promising Strategy to Mitigate Impacts of Climate Change on Rainbow Trout Culture

Development of a High-Density 665 K SNP Array for Rainbow Trout Genome-Wide Genotyping

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