Genetic discrimination of wild versus farmed gilthead sea bream <i>Sparus aurata</i> using microsatellite markers associated with candidate genes

Žužul, Iva; Grubišić, Leon; Šegvić-Bubić, Tanja

doi:10.1051/alr/2022009

Cited by 2 publications

(2 citation statements)

References 59 publications

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“…Reared fish may exhibit large genetic differences from adjacent wild populations mainly due to the different genetic background of broodstocks (i.e., different broodstock origins) or due to the application of selective breeding programs that aim to enhance specific traits [5,15,23]. Our results (F ST = 0.014-0.038) are in agreement with the existing literature, which has mainly shown weak genetic divergence between reared and wild Gilthead seabream populations along its distribution range, with F ST s ranging between 0.006-0.069 [3,5,15,18,121,122]. The genetic admixture of escapees with local wild populations could potentially introduce foreign DNA into the wild gene pool and damage local adaptations, but this stands for species with strong genetic structure like salmonids (F ST = 0.034-0.2, [123][124][125]).…”

Section: Discussionsupporting

confidence: 89%

Stock Discrimination of Gilthead Seabream (Sparus aurata Linnaeus, 1758) through the Examination of Otolith Morphology and Genetic Structure

Geladakis

Batargias

Somarakis

et al. 2023

Fishes

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Reliable stock identification constitutes an integral component of effective fishery management. Current methods for the identification of putative stock units comprise the analysis of both phenotypic and genetic variability. The present study examined the spatial variation in otolith morphology (shape and asymmetry) and genetic composition of 395 wild-caught Gilthead seabream (Sparus aurata) specimens, collected from the Aegean and Ionian Seas (eastern Mediterranean) between 2014–2018. The degree of scale regeneration (SRD, % of regenerated scales) was used as an indicator to assess the potential presence of aquaculture escapees in the wild-caught samples. Otolith shape and asymmetry analyses showed a phenotypic discrimination between northwestern Aegean and Ionian Gilthead seabream populations. Genetic analyses of nine microsatellite markers revealed higher levels of genetic variation in the wild compared with samples obtained from aquaculture farms. Despite the absence of genetic structure among the wild-caught seabream populations, a low but statistically significant genetic differentiation was found between reared fish and fish collected in the field. The SRD was considered effective in detecting the presence of aquaculture escapees that may have escaped in either early or late rearing phases.

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Section: Discussionsupporting

confidence: 89%

Stock Discrimination of Gilthead Seabream (Sparus aurata Linnaeus, 1758) through the Examination of Otolith Morphology and Genetic Structure

Geladakis

Batargias

Somarakis

et al. 2023

Fishes

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“…Hybridization of escapees in natural populations has been observed. Microsatellites were also used in the identification of escaped farmed gilthead sea bream in the Mediterranean area [ 273 , 336 , 337 , 338 ]. Escaped farmed cod, G. morhua , were identified in wild populations in Norway [ 339 , 340 ].…”

Section: Escapees’ Impact On Natural Populationsmentioning

confidence: 99%

Microsatellites as Molecular Markers with Applications in Exploitation and Conservation of Aquatic Animal Populations

Wenne

2023

Genes

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A large number of species and taxa has been studied for genetic polymorphism. Microsatellites have been known as hypervariable neutral molecular markers with the highest resolution power in comparison with any other markers. However, the discovery of a new type of molecular marker—single nucleotide polymorphism (SNP) has put the existing applications of microsatellites to the test. To ensure good resolution power in studies of populations and individuals, a number of microsatellite loci from 14 to 20 was often used, which corresponds to about 200 independent alleles. Recently, these numbers have tended to be increased by the application of genomic sequencing of expressed sequence tags (ESTs), and the choice of the most informative loci for genotyping depends on the aims of research. Examples of successful applications of microsatellite molecular markers in aquaculture, fisheries, and conservation genetics in comparison with SNPs have been summarized in this review. Microsatellites can be considered superior markers in such topics as kinship and parentage analysis in cultured and natural populations, the assessment of gynogenesis, androgenesis and ploidization. Microsatellites can be coupled with SNPs for mapping QTL. Microsatellites will continue to be used in research on genetic diversity in cultured stocks, and also in natural populations as an economically advantageous genotyping technique.

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Genetic discrimination of wild versus farmed gilthead sea bream Sparus aurata using microsatellite markers associated with candidate genes

Cited by 2 publications

References 59 publications

Stock Discrimination of Gilthead Seabream (Sparus aurata Linnaeus, 1758) through the Examination of Otolith Morphology and Genetic Structure

Stock Discrimination of Gilthead Seabream (Sparus aurata Linnaeus, 1758) through the Examination of Otolith Morphology and Genetic Structure

Microsatellites as Molecular Markers with Applications in Exploitation and Conservation of Aquatic Animal Populations

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