Genomic selection signatures in farmed <i>Colossoma macropomum</i> from tropical and subtropical regions in South America

Agudelo, John F.G.; Mastrochirico-Filho, Vito A.; Borges, Carolina Heloisa de Souza; Ariede, Raquel B.; Lira, Lieschen V.G.; Neto, Rubens Ricardo de Oliveira; Freitas, Milena V.; Sucerquia, Gustavo Adolfo Lenis; Vera, Manuel; Berrocal, Milthon Honorio Muñoz; Hashimoto, Diogo Teruo

doi:10.1111/eva.13351

Cited by 5 publications

(4 citation statements)

References 92 publications

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“…Some individual signals were placed in/or cover genes that indicated a very specific selective process such as the top DCMS hit (interferon‐inducible very large GTPase 1‐like) which might be a result of pressure due to pathogenic agents (Kim et al, 2012 ; Meunier & Broz, 2016 ; Pilla‐Moffett et al, 2016 ). Notably, genomic regions harbouring genes with immunity‐related functions have been recently pinpointed as putative selection signatures through the application of high‐density genotyping technologies in various farmed fish like Atlantic salmon ( Salmo salar ) (Gutierrez et al, 2016 ; López et al, 2019 ), coho salmon ( Oncorhynchus kisutch ) (López et al, 2021 ), rainbow trout ( Oncorhynchus mykiss ) (Cádiz et al, 2021 ), tambaqui ( Colossoma macropomum ) (Agudelo et al, 2022 ) and Nile tilapia ( Oreochromis niloticus ) (Cádiz et al, 2020 ). Such pattern, consistent across several different species, could be influenced by the fact that usually farmed fish are either directly selected for traits associated with disease resistance or due to the exposure to high levels of pathogens, strong selective pressure is applied in those genomic regions (López et al, 2015 ; Zueva et al, 2014 ).…”

Section: Discussionmentioning

confidence: 99%

Whole‐genome re‐sequencing provides key genomic insights in farmed Arctic charr (Salvelinus alpinus) populations of anadromous and landlocked origin from Scandinavia

Pappas

Kurta

Vanhala

et al. 2023

Evolutionary Applications

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Arctic charr (Salvelinus alpinus) is a niche‐market high‐value species for Nordic aquaculture. Similar to other salmonids, both anadromous and landlocked populations are encountered. Whole‐genome re‐sequencing (22X coverage) was performed on two farmed populations of anadromous (Sigerfjord; n = 24) and landlocked (Arctic Superior; n = 24) origin from Norway and Sweden respectively. More than 5 million SNPs were used to study their genetic diversity and to scan for selection signatures. The two populations were clearly distinguished through principal component analysis, with the mean fixation index being ~0.12. Furthermore, the levels of genomic inbreeding estimated from runs of homozygosity were 6.23% and 8.66% for the Norwegian and the Swedish population respectively. Biological processes that could be linked to selection pressure associated primarily with the anadromous background and/or secondarily with domestication were suggested. Overall, our study provided insights regarding the genetic composition of two main strains of farmed Arctic charr from Scandinavia. At the same time, ample genomic resources were produced in the magnitude of millions of SNPs that could assist the transition of Nordic Arctic charr farming in the genomics era.

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Section: Discussionmentioning

confidence: 99%

Whole‐genome re‐sequencing provides key genomic insights in farmed Arctic charr (Salvelinus alpinus) populations of anadromous and landlocked origin from Scandinavia

Pappas

Kurta

Vanhala

et al. 2023

Evolutionary Applications

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“…Finally, tambaqui or cachama ( Colossoma macropomum ), one of the most important neotropical freshwater fish used for aquaculture in South America, was investigated using the ddRAD sequencing approach in farmed populations from Brazil, Colombia and Peru to study the effects of recent artificial selection and domestication. Agudelo et al 232 identified several genomic regions potentially associated with stress tolerance and immunity, suggesting local adaptation to the culture environment.…”

Section: Signatures Of Domestication and Selectionmentioning

confidence: 99%

Genome‐wide association and genomic selection in aquaculture

Yáñez

Barría

López

et al. 2022

Reviews in Aquaculture

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Recent advancements in genomic technologies have led to the discovery and application of DNA-markers [e.g. single nucleotide polymorphisms (SNPs)] for the genetic improvement of several aquaculture species. The identification of specific genomic regions associated with economically important traits, using, for example, genome-wide association studies (GWAS), has allowed the discovery and incorporation of markers linked to quantitative trait loci (QTL) into aquaculture breeding programs through marker-assisted selection (MAS). However, most of the traits of economic relevance are expected to be controlled by many QTLs, each one explaining only a small proportion of the genetic variation. For traits under polygenic control, prediction of the genetic merit of animals based on the sum of effects at positions across the entire genome (i.e. genomic estimated breeding values, GEBV, which are used for what has become known as genomic selection), has been demonstrated to speed the rate of genetic gain for several traits in aquaculture breeding. The aim of this review was to provide an overview of the development and application of genomic technologies in uncovering the genetic basis of complex traits and accelerating the genetic progress in aquaculture species, as well as providing future perspectives about the deployment of novel molecular technologies for selective breeding in coming years.

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“…History of domestication and artificial selection in aquaculture species is much more recent, and in some cases very incipient (López et al, 2015 ). Selection signatures, generated during the early domestication and recent selective breeding, have been assessed at a genome‐wide scale in important farmed fish species, including Atlantic salmon (Gutierrez et al, 2016 ; López, Benestan, et al, 2019 ; López, Linderoth, et al, 2019 ; Naval‐Sanchez et al, 2020 ), rainbow trout (Cádiz et al, 2021 ), coho salmon (López et al, 2021 ), Nile tilapia ( Oreochromis niloticus ; Cádiz et al, 2020 ; Hong Xia et al, 2015 ), channel catfish (Sun et al, 2014 ), common carp ( Cyprinus carpio ; Xu et al, 2019 ), turbot ( Scophthalmus maximus ; Aramburu et al, 2020 ), Australasian snapper ( Chrysophrys auratus ; Baesjou & Wellenreuther, 2021 ), gilthead seabream ( Sparus aurata ; Gkagkavouzis et al, 2021 ) tambaqui ( Colossoma macropomum ; Agudelo et al, 2022 ), as well as in shellfish farmed populations, including bay scallop ( Argopecten irradians ; Wang et al, 2021 ), Yesso scallop ( Mizuhopecten yessoensis ; Lv et al, 2022 ), European flat oyster ( Ostrea edulis ; Vera et al, 2019 ) and Pacific oyster ( Crassostrea gigas ; Hu et al, 2021 ; Jiao et al, 2021 ). These studies have used dense genome‐wide genotypes to identify genomic regions harboring genes affecting important phenotypes in farmed fish and shellfish.…”

Section: Domestication and Artificial Selectionmentioning

confidence: 99%

“…, common carp (Cyprinus carpio;Xu et al, 2019), turbot (Scophthalmus maximus;Aramburu et al, 2020), Australasian snapper (Chrysophrys auratus;Baesjou & Wellenreuther, 2021), gilthead seabream (Sparus aurata;Gkagkavouzis et al, 2021) tambaqui (Colossoma macropomum;Agudelo et al, 2022), as well as in shellfish farmed populations, including bay scallop (Argopecten irradians;Wang et al, 2021), Yesso scallop (Mizuhopecten yessoensis;Lv et al, 2022), European flat oyster (Ostrea edulis;Vera et al, 2019) and Pacific oyster (Crassostrea gigas;Hu et al, 2021;Jiao et al, 2021).These studies have used dense genome-wide genotypes to identify genomic regions harboring genes affecting important phenotypes in farmed fish and shellfish. In general, studies on genomic footprints of domestication and artificial selection in aquaculture species have identified loci, which are putatively associated to adaptation to different biotic and abiotic conditions imposed by farming and management practices, as well as traits improved by selective breeding.Genes enriched within the loci underlying selection aquaculture populations are generally associated with growth, immune response, behavior and reproduction, indicating that these processes are important during the adaptation to captivity and also favored by recent human-driven selection.…”

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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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Genomic selection signatures in farmed Colossoma macropomum from tropical and subtropical regions in South America

Cited by 5 publications

References 92 publications

Whole‐genome re‐sequencing provides key genomic insights in farmed Arctic charr (Salvelinus alpinus) populations of anadromous and landlocked origin from Scandinavia

Whole‐genome re‐sequencing provides key genomic insights in farmed Arctic charr (Salvelinus alpinus) populations of anadromous and landlocked origin from Scandinavia

Genome‐wide association and genomic selection in aquaculture

Genomics applied to livestock and aquaculture breeding

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