34 results on '"Westgaard, Jon‐Ivar"'
Search Results
2. Taxonomic and genetic confirmed findings of snow crab (Chionoecetes opilio) larvae in the Barents Sea
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Hjelset, Ann Merete, Danielsen, Hanna Ellerine Helle, Westgaard, Jon-Ivar, and Agnalt, Ann-Lisbeth
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- 2021
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3. Scrutinizing the current management units of the greater argentine in the light of genetic structure.
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Quintela, María, Seljestad, Gaute W, Dahle, Geir, Hallfredsson, Elvar H, Enberg, Katja, Langbehn, Tom J, Jansson, Eeva, Glover, Kevin A, and Westgaard, Jon-Ivar
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FISH food ,PROCESSED foods ,SINGLE nucleotide polymorphisms ,LOCUS (Genetics) ,COASTS - Abstract
The greater argentine is a benthopelagic fish with a northern amphi-Atlantic and southern Arctic distribution. Landings of this species have been steadily increasing since the early 2000s, mainly for ultra-processed fish food. The rising economic importance of this species begs for an accurate delineation of the management units needed to ensure the sustainability of the fishery. The alignment between management and biological units was investigated on three of the ICES stocks in the NE Atlantic (123a4, 5a14, and 5b6a) by genotyping 88 ad hoc- developed SNPs on 1299 individuals sampled along the Norwegian coast, north of Shetland, around the Faroe Islands, and in the Denmark Strait within Icelandic waters. Candidate loci to positive selection were particularly crucial for units' delineation and supported the current ICES 5b6a and 5a14 stocks around the Faroe Islands and Iceland, respectively. However, within the third stock investigated, 123a4, which corresponded mainly to the Norwegian coast, the sample from area 3a (Skagerrak) was significantly different from all the remaining in the same stock. This differentiation advocates for reconsideration of the present policy and suggests considering ICES Area 3a (Skagerrak) as an independent management unit. The environmental conditions in the Skagerrak area have left a genetic print on other marine taxa, which could putatively be the case in the greater argentine. [ABSTRACT FROM AUTHOR]
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- 2024
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4. Maximizing sampling efficiency to detect differences in fish community composition using environmental DNA metabarcoding in subarctic fjords.
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Guri, Gledis, Westgaard, Jon‐Ivar, Yoccoz, Nigel, Wangensteen, Owen S., Præbel, Kim, Ray, Jessica Louise, Kelly, Ryan P., Shelton, Andrew Olaf, Hanebrekke, Tanja, and Johansen, Torild
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- 2024
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5. Boreal marine fauna from the Barents Sea disperse to Arctic Northeast Greenland
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Andrews, Adam J., Christiansen, Jørgen S., Bhat, Shripathi, Lynghammar, Arve, Westgaard, Jon-Ivar, Pampoulie, Christophe, and Præbel, Kim
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- 2019
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6. Contaminants reach everywhere: Fish dietary samples should be surface decontaminated prior to molecular diet analysis.
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Rijal, Dilli Prasad, Hanebrekke, Tanja, Arneberg, Per, Johansen, Torild, Sint, Daniela, Traugott, Michael, Skern‐Mauritzen, Mette, and Westgaard, Jon‐Ivar
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POLLUTANTS ,ECOSYSTEM dynamics ,GASTROINTESTINAL contents ,DIET ,ECOLOGICAL disturbances ,FECAL contamination ,DECONTAMINATION (From gases, chemicals, etc.) - Abstract
Knowledge of trophic interaction is necessary to understand the dynamics of ecosystems and develop ecosystem‐based management. The key data to measure these interactions should come from large‐scale diet analyses with good taxonomic resolution. To that end, molecular methods that analyze prey DNA from guts and feces provide high‐resolution dietary taxonomic data. However, molecular diet analysis may also produce unreliable results if the samples are contaminated by external sources of DNA. Employing the freshwater European whitefish (Coregonus lavaretus) as a tracer for sample contamination, we studied the possible route of whitefish in beaked redfish (Sebastes mentella) guts sampled in the Barents Sea. We used whitefish‐specific COI primers for diagnostic analysis, and fish‐specific 12S and metazoa‐specific COI primers for metabarcoding analyses of intestine and stomach contents of fish samples that were either not cleaned, water cleaned, or bleach cleaned after being in contact with whitefish. Both the diagnostic and COI metabarcoding revealed clear positive effects of cleaning samples as whitefish were detected in significantly higher numbers of uncleaned samples compared to water or bleach‐cleaned samples. Stomachs were more susceptible to contamination than intestines and bleach cleaning reduced the frequency of whitefish contamination. Also, the metabarcoding approach detected significantly more reads of whitefish in the stomach than in intestine samples. The diagnostic analysis and COI metabarcoding detected contaminants in a higher and comparable number of gut samples than the 12S‐based approach. Our study underlines thus the importance of surface decontamination of aquatic samples to obtain reliable diet information from molecular data. [ABSTRACT FROM AUTHOR]
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- 2023
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7. Genetic population structure in Norway lobster (Nephrops norvegicus): management regime under panmixia.
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Westgaard, Jon-Ivar, Søvik, Guldborg, and Johansen, Torild
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MICROSATELLITE repeats , *LOBSTERS , *OCEAN currents , *GENETIC markers , *GENETIC testing - Abstract
Investigations of genetic stock structure sometimes reveal a mismatch between management units and biological units. In Scandinavian waters, Norway lobster (Nephrops norvegicus) is divided into two management units (the Skagerrak–Kattegat and the Norwegian Deep). We have tested the population genetic structure of Nephrops within this region using microsatellite DNA markers, and compared the structure with the present management units. Our study suggests no population genetic structure of Nephrops within the Skagerrak, Kattegat, and Norwegian Deep region, whereas a shallow genetic structure was detected on a larger geographical scale when comparing outgroup samples from Scotland and Iceland. We found indications of sex-biased dispersal as the overall genetic differences were larger for females. Ocean current patterns suggest that Nephrops stocks in the region may be connected by larval drift. The two areas differ in fishing pressure, monitoring, assessment, and regulations, which is an argument for maintaining the present two-areas management regime despite the evidence for one biological population. [ABSTRACT FROM AUTHOR]
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- 2023
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8. Genetic population structure in Greenland halibut (Reinhardtius hippoglossoides) and its relevance to fishery management
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Westgaard, Jon-Ivar, Saha, Atal, Kent, Matthew, Hansen, Hanne Hellerud, Knutsen, Halvor, Hauser, Lorenz, Cadrin, Steven X., Albert, Ole Thomas, and Johansen, Torild
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Fishery management -- Methods ,Halibuts -- Genetic aspects ,Gene expression -- Observations ,Earth sciences - Abstract
Exploited marine resources can be managed more effectively when accurate information on geographic population structure is available. Genetic markers offer a powerful tool for fisheries management, because they reveal biologically sound management units. Single nucleotide polymorphisms (SNPs) markers derived from restriction-site associated DNA sequencing (RAD-seq) were developed and used to investigate the stock structure of Greenland halibut (Reinhardtius hippoglossoides). A total of 96 SNPs were analyzed from 384 individuals and eight locations across the Atlantic. Our results suggest a subdivision of Greenland halibut into two populations, an eastern Atlantic population and a western Atlantic population, with a proposed border across the Denmark Strait. In general, Greenland halibut display weak but significant population structure (overall [F.sub.ST] = 0.003; p < 0.001), which can be explained by connectivity among populations owing to the migratory behavior or egg and larval drift. Les ressources marines exploitees peuvent etre gerees plus efficacement quand de l'information exacte sur la structure geographique de leurs populations est disponible. Les marqueurs genetiques constituent un puissant outil pour la gestion des peches parce qu'ils font ressortir des unites de gestion coherentes sur le plan biologique. Des marqueurs de polymorphismes mononucleotidiques (SNPs) derives du sequenqage d'ADN associe a un site de restriction (RAD-seq) ont ete developpes et utilises pour etudier la structure des stocks de fletan noir (Reinhardtius hippoglossoides). Un total de 96 SNP ont ete analyses de 384 individus et huit emplacements dans l'Atlantique. Nos resultats semblent indiquer le regroupement des fletans noirs en deux populations, une de l'est de l'Atlantique et l'autre de l'ouest de l'Atlantique, la frontiere proposee entre les deux traversant le detroit du Danemark. En general, les fletans noirs presentent une structure de populations faible mais significative ([F.sub.ST] global = 0,003; p < 0,001) qui peut s'expliquer par la connectivite des populations decoulant du comportement migratoire ou de la derive des reufs et des larves. [Traduit par la Redaction], Introduction Marine fish populations typically consist of large numbers of individuals with high dispersal potential in one or several life-history stages (Conover et al. 2006), which can result in a [...]
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- 2017
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9. Farmed cod escapees and net-pen spawning left no clear genetic footprint in the local wild cod population
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Varne, Rebekka, Kunz, Kristina L., Johansen, Torild, Westgaard, Jon-Ivar, Uglem, Ingebrigt, and Mork, Jarle
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- 2015
10. Analysis of coastal cod (Gadus morhua L.) sampled on spawning sites reveals a genetic gradient throughout Norway’s coastline
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Dahle, Geir, Quintela, María, Johansen, Torild, Westgaard, Jon-Ivar, Besnier, François, Aglen, Asgeir, Jørstad, Knut E., and Glover, Kevin A.
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- 2018
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11. Settling-depth vs. genotype and size vs. genotype correlations at the Pan I locus in 0-group Atlantic cod Gadus morhua
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Fevolden, Svein-Erik, Westgaard, Jon-Ivar, Pedersen, Torstein, and Præbel, Kim
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- 2012
12. Benthic invertebrates in Svalbard fjords--when metabarcoding does not outperform traditional biodiversity assessment.
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Willassen, Endre, Westgaard, Jon-Ivar, Kongsrud, Jon Anders, Hanebrekke, Tanja, Buhl-Mortensen, Pål, and Holte, Børge
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GENETIC barcoding ,FJORDS ,EUPHOTIC zone ,MARINE sciences ,INVERTEBRATES ,BIODIVERSITY - Abstract
To protect and restore ecosystems and biodiversity is one of the 10 challenges identified by the United Nations's Decade of the Ocean Science. In this study we used eDNA from sediments collected in two fjords of the Svalbard archipelago and compared the taxonomic composition with traditional methods through metabarcoding, targeting mitochondrial CO1, to survey benthos. Clustering of 21.6 mill sequence reads with a d value of 13 in swarm, returned about 25 K OTU reads. An identification search with the BOLD database returned 12,000 taxonomy annotated sequences spanning a similarity range of 50% to 100%. Using an acceptance filter of minimum 90% similarity to the CO1 reference sequence, we found that 74% of the ca 100 taxon identified sequence reads were Polychaeta and 22% Nematoda. Relatively few other benthic invertebrate species were detected. Many of the identified sequence reads were extra-organismal DNA from terrestrial, planktonic, and photic zone sources. For the species rich Polychaeta, we found that, on average, only 20.6% of the species identified from morphology were also detected with DNA. This discrepancy was not due to missing reference sequences in the search database, because 90-100% (mean 96.7%) of the visually identified species at each station were represented with barcodes in Boldsystems. The volume of DNA samples is small compared with the volume searched in visual sorting, and the replicate DNA-samples in sum covered only about 2% of the surface area of a grab. This may considerably reduce the detection rate of species that are not uniformly distributed in the sediments. Along with PCR amplification bias and primer mismatch, this may be an important reason for the limited congruence of species identified with the two approaches. However, metabarcoding also identified 69 additional species that are usually overlooked in visual sample sorting, demonstrating how metabarcoding can complement traditional methodology by detecting additional, less conspicuous groups of organisms. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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13. Geographic variation in gene flow from a genetically distinct migratory ecotype drives population genetic structure of coastal Atlantic cod (Gadus morhua L.).
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Breistein, Bjoerghild, Dahle, Geir, Johansen, Torild, Besnier, Francois, Quintela, Maria, Jorde, Per Erik, Knutsen, Halvor, Westgaard, Jon‐Ivar, Nedreaas, Kjell, Farestveit, Eva, and Glover, Kevin Alan
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ATLANTIC cod ,GENE flow ,LIFE history theory ,SUSTAINABLE fisheries ,POPULATION differentiation ,FISHERY management - Abstract
Identifying how physical and biotic factors shape genetic connectivity among populations in time and space is essential to our understanding of the evolutionary trajectory as well as the management of marine species. Atlantic cod is a widespread and commercially important marine species displaying several ecotypes with different life history strategies. Using three sets of SNPs: neutral, informative, and genome‐inversion linked, we studied population genetic structure of ~2500 coastal Atlantic cod (CC) from 40 locations along Norway's 2500 km coastline, including nine fjords. We observed: (1) a genetic cline, suggesting a mechanism of isolation by distance, characterized by a declining FST between CC and North East Arctic Cod (NEAC—genetically distinct migratory ecotype) with increasing latitude, (2) that in the north, samples of CC from outer‐fjord areas were genetically more similar to NEAC than were samples of CC from their corresponding inner‐fjord areas, (3) greater population genetic differentiation among CC sampled from outer‐fjord areas along the coast, than among CC sampled from their corresponding inner‐fjord areas, (4) genetic differentiation among samples of CC from both within and among fjords. Collectively, these results permit us to draw two main conclusions. First, that differences in the relative presence of the genetically highly distinct, migratory ecotype NEAC, declining from north to south and from outer to inner fjord, plays the major role in driving population genetic structure of the Norwegian CC. Second, that there is limited connectivity between CC from different fjords. These results suggest that the current management units implemented for this species in Norway should be divided into smaller entities. Furthermore, the situation where introgression from one ecotype drives population genetic structure of another, as is the case here, may exist in other species and geographical regions, thus creating additional challenges for sustainable fisheries management. [ABSTRACT FROM AUTHOR]
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- 2022
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14. Isolation and characterization of nuclear microsatellite loci in the northern shrimp, Pandalus borealis
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Pereyra, Ricardo T., Westgaard, Jon-Ivar, Dahl, Mikael, Johansen, Torild, Knutsen, Halvor, Ring, Anna-Karin, Søvik, Guldborg, and André, Carl
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- 2012
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15. Development of ten new EST-derived microsatellites in Atlantic cod (Gadus morhua L.)
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Westgaard, Jon-Ivar, Tafese, Tekle, Wesmajervi, Mette Serine, Nilsen, Frank, Fjalestad, Kjersti Turid, Damsgård, Børge, and Delghandi, Madjid
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- 2007
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16. Genetic investigation of swimbladder inflation anomalies in the European sea bass, Dicentrarchus labrax L.
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Peruzzi, Stefano, Westgaard, Jon-Ivar, and Chatain, Béatrice
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- 2007
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17. Simultaneous Analysis of Six Microsatellite Markers in Atlantic Cod (Gadus morhua): A Novel Multiplex Assay System for Use in Selective Breeding Studies
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Delghandi, Madjid, Mortensen, Atle, and Westgaard, Jon-Ivar
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- 2003
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18. Characterization of polymorphic microsatellite markers for the bearded goby Sufflogobius bibarbatus
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Gunawickrama, K. B. Suneetha, Westgaard, Jon-Ivar, Salvanes, Anne Gro Vea, and Johansen, Torild
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- 2012
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19. Genetic differentiation between inshore and offshore populations of northern shrimp (Pandalus borealis).
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Hansen, Agneta, Westgaard, Jon-Ivar, Søvik, Guldborg, Hanebrekke, Tanja, Nilssen, Einar Magnus, Jorde, Per Erik, Albretsen, Jon, and Johansen, Torild
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SHRIMP populations , *FISHERIES , *SMALL-scale fisheries , *FJORDS , *SHRIMPS - Abstract
Many marine organisms have a permanent presence both inshore and offshore and spawn in multiple areas, yet their status as separate populations or stocks remain unclear. This is the situation for the northern shrimp (Pandalus borealis) around the Arctic Ocean, which in northern Norway represents an important income for a small-scale coastal fishery and a large-vessel offshore fleet. In Norwegian waters, we uncovered two distinct genetic clusters, viz. a Norwegian coastal and a Barents Sea cluster. Shrimps with a mixed heritage from the Norwegian coastal and the Barents Sea clusters, and genetically different from both, inhabit the fjords at the northernmost coast (Finnmark). Genetic structure between fjords did not display any general trend, and only the Varangerfjord in eastern Finnmark displayed significant genetic structure within the fjord. Shrimps in the Finnmark fjords differed in some degree from shrimps both in the adjacent Barents Sea and along the rest of the coast and should probably be considered a separate management unit. [ABSTRACT FROM AUTHOR]
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- 2021
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20. Identification and characterisation of thirteen new microsatellites for Atlantic cod (Gadus morhua L.) from a repeat-enriched library
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Westgaard, Jon-Ivar, Tafese, Tekle, Wesmajervi, Mette Serine, Stenvik, Jørgen, Fjalestad, Kjersti Turid, Damsgård, Børge, and Delghandi, Madjid
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- 2007
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21. Hierarchical genetic structure in an evolving species complex: Insights from genome wide ddRAD data in Sebastes mentella.
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Saha, Atal, Kent, Matthew, Hauser, Lorenz, Drinan, Daniel P., Nielsen, Einar E., Westgaard, Jon-Ivar, Lien, Sigbjørn, and Johansen, Torild
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GENETIC variation ,MARINE ecology ,MARINE biology ,SPECIES ,GENOMES - Abstract
The diverse biology and ecology of marine organisms may lead to complex patterns of intraspecific diversity for both neutral and adaptive genetic variation. Sebastes mentella displays a particular life-history as livebearers, for which existence of multiple ecotypes has been suspected to complicate the genetic population structure of the species. Double digest restriction-site associated DNA was used to investigate genetic population structure in S. mentella and to scan for evidence of selection. In total, 42,288 SNPs were detected in 277 fish, and 1,943 neutral and 97 tentatively adaptive loci were selected following stringent filtration. Unprecedented levels of genetic differentiation were found among the previously defined 'shallow pelagic', 'deep pelagic' and 'demersal slope' ecotypes, with overall mean F
ST = 0.05 and 0.24 in neutral and outlier SNPs, respectively. Bayesian computation estimated a concurrent and historical divergence among these three ecotypes and evidence of local adaptation was found in the S. mentella genome. Overall, these findings imply that the depth-defined habitat divergence of S. mentella has led to reproductive isolation and possibly adaptive radiation among these ecotypes. Additional sub-structuring was detected within the 'shallow' and 'deep' pelagic ecotypes. Population assignment of individual fish showed more than 94% agreement between results based on SNP and previously generated microsatellite data, but the SNP data provided a lower estimate of hybridization among the ecotypes than that by microsatellite data. We identified a SNP panel with only 21 loci to discriminate populations in mixed samples based on a machine-learning algorithm. This first SNP based investigation clarifies the population structure of S. mentella, and provides novel and high-resolution genomic tools for future investigations. The insights and tools provided here can readily be incorporated into the management of S. mentella and serve as a template for other exploited marine species exhibiting similar complex life history traits. [ABSTRACT FROM AUTHOR]- Published
- 2021
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22. Genetic structuring in Atlantic haddock contrasts with current management regimes.
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Berg, Paul R, Jorde, Per E, Glover, Kevin A, Dahle, Geir, Taggart, John B, Korsbrekke, Knut, Dingsør, Gjert E, Skjæraasen, Jon E, Wright, Peter J, Cadrin, Steven X, Knutsen, Halvor, and Westgaard, Jon-Ivar
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SINGLE nucleotide polymorphisms ,GENETIC markers ,SUSTAINABLE fisheries ,OFFSHORE structures ,CONTINENTAL shelf - Abstract
The advent of novel genetic methods has made it possible to investigate population structure and connectivity in mobile marine fish species: knowledge of which is essential to ensure a sustainable fishery. Haddock (Melanogrammus aeglefinus) is a highly exploited marine teleost distributed along the coast and continental shelf on both sides of the North Atlantic Ocean. However, little is known about its population structure. Here, we present the first study using single-nucleotide polymorphism (SNP) markers to assess the genetic population structure of haddock at multiple geographic scales, from the trans-Atlantic to the local (fjord) level. Genotyping 138 SNP loci in 1329 individuals from 19 locations across the North Atlantic revealed three main genetic clusters, consisting of a Northwest Atlantic cluster, a Northeast Arctic cluster, and a Northeast Atlantic cluster. We also observed a genetically distinct fjord population and a pattern of isolation by distance in the Northeast Atlantic. Our results contrast with the current management regime for this species in the Northeast Atlantic, as we found structure within some management areas. The study adds to the growing recognition of population structuring in marine organisms in general, and fishes in particular, and is of clear relevance for the management of haddock in the Northeast Atlantic. [ABSTRACT FROM AUTHOR]
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- 2021
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23. Genomic analysis reveals neutral and adaptive patterns that challenge the current management regime for East Atlantic cod Gadus morhua L.
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Johansen, Torild, Besnier, François, Quintela, María, Jorde, Per Erik, Glover, Kevin A., Westgaard, Jon‐Ivar, Dahle, Geir, Lien, Sigbjørn, and Kent, Matthew P.
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GENOMICS ,ATLANTIC cod ,MORPHOLOGY ,FISHERY management ,FISH genetics ,SUBSPECIES - Abstract
Challenging long‐held perceptions of fish management units can help to protect vulnerable stocks. When a fishery consisting of multiple genetic stocks is managed as a single unit, overexploitation and depletion of minor genetic units can occur. Atlantic cod (Gadus morhua) is an economically and ecologically important marine species across the North Atlantic. The application of new genomic resources, including SNP arrays, allows us to detect and explore novel structure within specific cod management units. In Norwegian waters, coastal cod (i.e. those not undertaking extensive migrations) are divided into two arbitrary management units defined by ICES: one between 62° and 70°N (Norwegian coastal cod; NCC) and one between 58° and 62°N (Norwegian coastal south; NCS). Together, these capture a fishery area of >25,000 km2 containing many spawning grounds. To assess whether these geographic units correctly represent genetic stocks, we analysed spawning cod of NCC and NCS for more than 8,000 SNPs along with samples of Russian White Sea cod, north‐east Arctic cod (NEAC: the largest Atlantic stock), and outgroup samples representing the Irish and Faroe Sea's. Our analyses revealed large differences in spatial patterns of genetic differentiation across the genome and revealed a complex biological structure within NCC and NCS. Haplotype maps from four chromosome sets show regional specific SNP indicating a complex genetic structure. The current management plan dividing the coastal cod into only two management units does not accurately reflect the genetic units and needs to be revised. Coastal cod in Norway, while highly heterogenous, is also genetically distinct from neighbouring stocks in the north (NEAC), west (Faroe Island) and the south. The White Sea cod are highly divergent from other cod, possibly yielding support to the earlier notion of subspecies rank. [ABSTRACT FROM AUTHOR]
- Published
- 2020
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24. Diet and prey consumption of grey seals (Halichoerus grypus) in Norway.
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Nilssen, Kjell Tormod, Lindstrøm, Ulf, Westgaard, Jon Ivar, Lindblom, Lotta, Blencke, Taija-Riitta, and Haug, Tore
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GRAY seal ,SEALING compounds ,BIOMASS energy ,ATLANTIC cod ,ANIMAL nutrition ,PELAGIC fishes ,SEALS (Animals) - Abstract
To obtain knowledge of feeding habits and prey consumption of grey seals, data were sampled in selected areas along the Norwegian coast. Prey were recovered from 182 grey seal gastrointestinal tracts and 199 faecal samples, collected during1999–2010 in Finnmark, Nordland and Rogaland counties. The most important prey were saithe Pollachius virens, cod Gadus morhua and wolffish Anarchichus spp. Wolffish was mainly eaten by seals ≥ five years old. Otherwise, the data did not suggest important temporal or spatial variations between the main prey items in the grey seal diet. However, capelin Mallotus villosus was eaten during spring in Finnmark suggesting that seasonally abundant pelagic fish species could be regionally important. Total annual grey seal consumption of various species was estimated using bio-energetic modelling. The input variables were seal numbers, energy demands, diet composition in terms of biomass and energy densities of prey species. Assuming the observed grey seals diet composition in the sampling areas were representative for the diet along the Norwegian coast, the mean total annual consumption by 3850 grey seals was estimated to be 8084 tons in Norwegian waters; saithe (3059 tons), cod (2598 tons) and wolffish (1364 tons) were consumed in highest quantities. [ABSTRACT FROM AUTHOR]
- Published
- 2019
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25. "Real-time" genetic monitoring of a commercial fishery on the doorstep of an MPA reveals unique insights into the interaction between coastal and migratory forms of the Atlantic cod.
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Johansen, Torild, Westgaard, Jon-Ivar, Seliussen, Bjørghild B., Nedreaas, Kjell, Dahle, Geir, Glover, Kevin A., Kvalsund, Roger, and Aglen, Asgeir
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FISHERY management , *AQUATIC resource management , *FISH population thinning , *ATLANTIC cod behavior , *MARINE parks & reserves - Abstract
With the decline of many of the world's fisheries, increased regulation, including marine protected areas (MPA), forms an increasingly important role in promoting sustainable resource use. Here, we present a novel "real-time" genetic monitoring programme used to protect the depleted Norwegian coastal cod stock (NCC) in an MPA during the spawning season, while a fishery targeted at the sustainable Northeast Arctic cod stock (NEAC) operates immediately outside. In the period 2009-2016,>6800 cod from the fishery were genotyped with the PanI locus that is discriminatory between these two stocks. The estimated fraction of NEAC increased during the study period until 2014; however, it did not exceed 70% for any sustained period. Therefore, the MPA remained closed for commercial harvest. Genetic analysis of eggs revealed a distinctly lower fraction of NEAC than in the catch from the adult stock, both immediately outside and within the MPA itself. We suggest that this discrepancy is likely to reflect differences in spawning areas used by NCC and NEAC. Estimated fractions of NEAC/NCC using PanI, otolith classification, and 39 single nucleotide polymorphisms were similar, thus validating the use of PanI to estimate NEAC/NCC composition. [ABSTRACT FROM AUTHOR]
- Published
- 2018
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26. Large and fine scale population structure in European hake (Merluccius merluccius) in the Northeast Atlantic.
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Westgaard, Jon-Ivar, Staby, Arved, Godiksen, Jane Aanestad, Geffen, Audrey J., Svensson, Anders, Svedäng, Henrik, Charrier, Gregory, and André, Carl
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DEMERSAL zone , *MARINE habitats , *EUROPEAN hake - Abstract
Recently, there have been reports of increased abundance and landings of European hake in the northern part of the species range. Biological studies are however scarce and information about finer scale population structure important for stock assessments and fishery management is largely lacking. Here, we report on a population genetic study using neutral and outlier SNP loci assessing population structure in hake in the north-eastern parts of its range in the Atlantic. Hake samples from localities along the west coast of Norway, the Kattegat, the northern North Sea, and one locality in the Bay of Biscay were analysed using 53 SNPs, six of which were outliers potentially influenced by natural selection. We detected small-scale structure among northern samples, all of which were also distinct from Bay of Biscay hake, with the exception of a few individuals from the North Sea and the coast of Norway who clustered genetically together with Bay of Biscay hake. Our findings suggest that the present management unit of a single northern stock of hake is not biologically correct, and that there is more detail in the fine-scale population structure indicating that independent population dynamics could be expected in response to fishing patterns or changing environmental conditions. [ABSTRACT FROM AUTHOR]
- Published
- 2017
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27. Geographic extent of introgression in Sebastes mentella and its effect on genetic population structure.
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Saha, Atal, Johansen, Torild, Hedeholm, Rasmus, Nielsen, Einar E., Westgaard, Jon-Ivar, Hauser, Lorenz, Planque, Benjamin, Cadrin, Steven X., and Boje, Jesper
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INTROGRESSION (Genetics) ,SEBASTES mentella ,POPULATION genetics ,BIOLOGICAL variation ,BIOLOGICAL divergence - Abstract
Genetic population structure is often used to identify management units in exploited species, but the extent of genetic differentiation may be inflated by geographic variation in the level of hybridization between species. We identify the genetic population structure of Sebastes mentella and investigate possible introgression within the genus by analyzing 13 microsatellites in 2,562 redfish specimens sampled throughout the North Atlantic. The data support an historical divergence between the 'shallow' and 'deep' groups, beyond the Irminger Sea where they were described previously. A third group , 'slope,' has an extended distribution on the East Greenland Shelf, in addition to earlier findings on the Icelandic slope. Furthermore, S. mentella from the Northeast Arctic and Northwest Atlantic waters are genetically different populations. In both areas, interspecific introgression may influence allele frequency differences among populations. Evidence of introgression was found for almost all the identified Sebastes gene pools, but to a much lower extent than suggested earlier. Greenland waters appear to be a sympatric zone for many of the genetically independent Sebastes groups. This study illustrates that the identified groups maintain their genetic integrity in this region despite introgression. [ABSTRACT FROM AUTHOR]
- Published
- 2017
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28. Genetically distinct populations of northern shrimp, Pandalus borealis, in the North Atlantic: adaptation to different temperatures as an isolation factor.
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Jorde, Per Erik, Søvik, Guldborg, Westgaard, Jon‐Ivar, Albretsen, Jon, André, Carl, Hvingel, Carsten, Johansen, Torild, Sandvik, Anne Dagrun, Kingsley, Michael, and Jørstad, Knut Eirik
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PANDALUS borealis ,POPULATION genetics ,SHRIMP populations ,WATER temperature ,BIODIVERSITY - Abstract
The large-scale population genetic structure of northern shrimp, Pandalus borealis, was investigated over the species' range in the North Atlantic, identifying multiple genetically distinct groups. Genetic divergence among sample localities varied among 10 microsatellite loci (range: F
ST = −0.0002 to 0.0475) with a highly significant average ( FST = 0.0149; P < 0.0001). In contrast, little or no genetic differences were observed among temporal replicates from the same localities ( FST = 0.0004; P = 0.33). Spatial genetic patterns were compared to geographic distances, patterns of larval drift obtained through oceanographic modelling, and temperature differences, within a multiple linear regression framework. The best-fit model included all three factors and explained approximately 29% of all spatial genetic divergence. However, geographic distance and larval drift alone had only minor effects (2.5-4.7%) on large-scale genetic differentiation patterns, whereas bottom temperature differences explained most (26%). Larval drift was found to promote genetic homogeneity in parts of the study area with strong currents, but appeared ineffective across large temperature gradients. These findings highlight the breakdown of gene flow in a species with a long pelagic larval phase (up to 3 months) and indicate a role for local adaptation to temperature conditions in promoting evolutionary diversification and speciation in the marine environment. [ABSTRACT FROM AUTHOR]- Published
- 2015
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29. Atlantic cod (Gadus morhua L.) in inner and outer coastal zones of northern Norway display divergent genetic signature at non-neutral loci
- Author
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Westgaard, Jon-Ivar and Fevolden, Svein-Erik
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MICROSATELLITE repeats , *COASTS , *GLACIAL landforms , *COMPARISON (Psychology) - Abstract
Abstract: A large majority of Atlantic cod (Gadus morhua) found all year round in outer parts of fjords and along outer coastal areas in general in northern Norway have a genetic signature at the pantophysin (Pan I) locus that distinguish them from Norwegian coastal cod (NCC) found further inside fjords in the same areas. The identity of these fish has been controversial and to examine if they represent a distinct coastal cod group, or are identical to the migratory North East Arctic cod (NEAC) of the Barents Sea, a comparison was conducted at 10 microsatellite loci for 15 samples comprising each of the three groups inner coastal NCC, outer coastal cod and NEAC. Spatial analysis of molecular variance revealed that the outer coastal samples cannot be discriminated from NEAC by means of microsatellite markers, supporting the similarity of the two groups at the Pan I locus. This implies that a portion of the otherwise migratory NEAC, at least in its premature stage, remains in coastal areas in close contact with the genetically quite distinct NCC group. Both the coalescent-based simulation approach and the lnRH test for selective sweeps proved two of the microsatellite loci, GMO 34 and GMO 132 to be non-neutral. Notwithstanding, these two loci, together with the acknowledged non-neutral Pan I locus, which displayed profound linkage disequilibrium to GMO 34 within NEAC, are as yet the only nuclear markers which unambiguously discriminate between NEAC and NCC. Although the relative contribution of restricted gene flow versus selection as a causative agent for the divergence between NEAC and NCC has not been assessed, we believe the magnitude of differentiation at the three loci provides rational for maintaining NEAC and NCC as separate management units. [Copyright &y& Elsevier]
- Published
- 2007
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30. Evaluation of a novel pentaplex microsatellite marker system for paternity studies in Atlantic cod ( Gadus morhua L.).
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Wesmajervi, Mette Serine, Westgaard, Jon-Ivar, and Delghandi, Madjid
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- *
ATLANTIC cod , *MICROSATELLITE repeats , *CHROMOSOMES , *MULTIPLEXING , *DATA transmission systems , *PSETTA maxima , *RAINBOW trout , *FISHES , *AQUATIC animals - Abstract
Five Atlantic cod ( Gadus morhua L.) microsatellites ( Gmo8, Gmo19, Gmo35, Gmo37 and Tch11) were selected for parentage assignment. All markers were co-amplified using dye-labelled primers and sized by automated sample processing in a 3130 xl Genetic Analyser. The genotyping of samples was reproducible and alleles from all loci could be genotyped confidently (precision and accuracy above 99.7 and 99.1% respectively). The number of alleles, observed allelic and genotypic frequencies were calculated. A population database was established for fish originating from randomly selected wild-caught Norwegian coastal- and North-East Arctic cod. Combined paternity exclusion and the probability of match were 99.97 and 1.5 × 10−9 respectively. The multiplex assay system was used successfully for parental assignment of 2336 juveniles from different mass spawning breeding tanks. Of all offspring, 91.2% were assigned to a single parental pair. In total, 523 different matings were recorded, and 69 of 70 dams and all of the 30 sires contributed to the offspring. [ABSTRACT FROM AUTHOR]
- Published
- 2006
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31. Analysis of coastal cod (<italic>Gadus morhua</italic> L.) sampled on spawning sites reveals a genetic gradient throughout Norway's coastline.
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Dahle, Geir, Quintela, María, Johansen, Torild, Westgaard, Jon-Ivar, Besnier, François, Aglen, Asgeir, Jørstad, Knut E., and Glover, Kevin A.
- Subjects
ATLANTIC salmon ,MICROSATELLITE repeats ,FISH populations ,POPULATION genetics ,ATLANTIC cod - Abstract
Background: Atlantic cod (
Gadus morhua L.) has formed the basis of many economically significant fisheries in the North Atlantic, and is one of the best studied marine fishes, but a legacy of overexploitation has depleted populations and collapsed fisheries in several regions. Previous studies have identified considerable population genetic structure for Atlantic cod. However, within Norway, which is the country with the largest remaining catch in the Atlantic, the population genetic structure of coastal cod (NCC) along the entire coastline has not yet been investigated. We sampled > 4000 cod from 55 spawning sites. All fish were genotyped with 6 microsatellite markers and Pan I (Dataset 1). A sub-set of the samples (1295 fish from 17 locations) were also genotyped with an additional 9 microsatellites (Dataset 2). Otoliths were read in order to exclude North East Arctic Cod (NEAC) from the analyses, as and where appropriate. Results: We found no difference in genetic diversity, measured as number of alleles, allelic richness, heterozygosity nor effective population sizes, in the north-south gradient. In both data sets, weak but significant population genetic structure was revealed (Dataset 1: global FST = 0.008,P < 0.0001. Dataset 2: global FST = 0.004,P < 0.0001). While no clear genetic groups were identified, genetic differentiation increased among geographically-distinct samples. Although the locus Gmo132 was identified as a candidate for positive selection, possibly through linkage with a genomic region under selection, overall trends remained when this locus was excluded from the analyses. The most common allele in loci Gmo132 and Gmo34 showed a marked frequency change in the north-south gradient, increasing towards the frequency observed in NEAC in the north. Conclusion: We conclude that Norwegian coastal cod displays significant population genetic structure throughout its entire range, that follows a trend of isolation by distance. Furthermore, we suggest that a gradient of genetic introgression between NEAC and NCC contributes to the observed population genetic structure. The current management regime for coastal cod in Norway, dividing it into two stocks at 62°N, represents a simplification of the level of genetic connectivity among coastal cod in Norway, and needs revision. [ABSTRACT FROM AUTHOR]- Published
- 2018
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32. Genetic management of mixed-stock fisheries “real-time”: The case of the largest remaining cod fishery operating in the Atlantic in 2007–2017.
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Dahle, Geir, Johansen, Torild, Westgaard, Jon-Ivar, Aglen, Asgeir, and Glover, Kevin A.
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- *
COD fisheries , *FISH population measurement , *FISHERY management , *FISH genetics , *FISH spawning , *BYCATCHES , *MANAGEMENT - Abstract
Fish stocks represent fundamental units in fisheries management, and their identification, especially in mixed-fisheries, represents one of the primary challenges to sustainable harvest. Here, we describe the first “real-time” genetic management program used to manage a mixed-stock fishery of a non-salmonid and commercially significant marine fish, the Atlantic cod ( Gadus morhua L). Based upon the analysis of >18 000 fish sampled from the commercial catch in Lofoten (Norway), which represents the largest remaining cod fishery in the Atlantic, we estimated the fraction of North East Arctic cod (NEAC), and Norwegian Coastal cod (NCC), just 24 h post-landing. These estimates, based upon the analysis of the Pantophysin gene, were performed weekly in the winter and spring of each year in the period 2007–2017. The program has successfully permitted the Norwegian Directorate of Fisheries to actively manage the commercial exploitation of the highly abundant NEAC stock, while simultaneously limiting exploitation of the fragile NCC stock, both of which overlap at the spawning grounds. Data from this program have also revealed a distinct temporal increase in the fraction of NEAC on the spawning grounds in this region, which is consistent with the overall increased abundance of this stock as estimated by ICES. [ABSTRACT FROM AUTHOR]
- Published
- 2018
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33. The pantophysin gene and its relationship with survival in early life stages of Atlantic cod.
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Otterå H, Johansen T, Folkvord A, Dahle G, Solvang Bingh MK, Westgaard JI, and Glover KA
- Abstract
Genetic markers are widely used in fisheries management around the world. While the genetic structure and markers selected are usually based on samples from the wild, very few controlled experiments have been carried out to investigate possible differences in influence on traits between markers. Here we examine the bi-allelic gene pantophysin (Pan I), widely used in the management of Atlantic cod, in a series of in vitro crosses under a range of temperatures. It has been proposed that this gene, or another tightly linked gene, may be under strong divergent selection. Resolving this issue is essential in order to interpret results when using this gene marker for stock management. We found no evidence of departure from the expected 1 : 2 : 1 Mendelian ratio for any of the three genotypes during the egg stage, while both the 6 and 12°C temperature regimes in tank experiments favoured the survival of the Pan I
AA genotype. No difference in genotype survival was, however, found in a more natural mesocosm environment. Collectively, these results suggest that for the early life stages of Atlantic cod, and under the current experimental conditions, there is no strong consistent influence of Pan I genotype on survival. The results also emphasize the importance of varied experimental studies to verify the importance of environmental factors influencing genotype selection., Competing Interests: We declare we have no competing interests., (© 2020 The Authors.)- Published
- 2020
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34. Geographic extent of introgression in Sebastes mentella and its effect on genetic population structure.
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Saha A, Johansen T, Hedeholm R, Nielsen EE, Westgaard JI, Hauser L, Planque B, Cadrin SX, and Boje J
- Abstract
Genetic population structure is often used to identify management units in exploited species, but the extent of genetic differentiation may be inflated by geographic variation in the level of hybridization between species. We identify the genetic population structure of Sebastes mentella and investigate possible introgression within the genus by analyzing 13 microsatellites in 2,562 redfish specimens sampled throughout the North Atlantic. The data support an historical divergence between the "shallow" and "deep" groups, beyond the Irminger Sea where they were described previously. A third group , "slope," has an extended distribution on the East Greenland Shelf, in addition to earlier findings on the Icelandic slope. Furthermore, S. mentella from the Northeast Arctic and Northwest Atlantic waters are genetically different populations. In both areas, interspecific introgression may influence allele frequency differences among populations. Evidence of introgression was found for almost all the identified Sebastes gene pools, but to a much lower extent than suggested earlier. Greenland waters appear to be a sympatric zone for many of the genetically independent Sebastes groups. This study illustrates that the identified groups maintain their genetic integrity in this region despite introgression.
- Published
- 2016
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