Microsatellites reveal clear genetic boundaries among Atlantic salmon (<i>Salmo salar</i>) populations from the Barents and White seas, northwest Russia

Tonteri, Anni; Веселов, А. Е.; Зубченко, А. В.; Lumme, Jaakko; Primmer, Craig R.

doi:10.1139/f09-010

Cited by 39 publications

(61 citation statements)

References 49 publications

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“…1) indicates that the most likely explanation is that relative force of genetic drift outweighs that of migration (Hutchison and Templeton 1999). Our results are in contrast with the observations reported by other authors for salmonid populations and particularly for anadromous Atlantic salmon (Moran et al 1995;Hansen and Mensberg 1998;Knutsen et al 2001;King et al 2001;Koljonen 2001;Tonteri et al 2009). However in many of these studies the within-region signal of IBD was almost negligible over distances of more than 100 km (e.g.…”

Section: Genetic Substructurecontrasting

confidence: 79%

“…Genomic DNA was extracted from tissue samples according to Elphinstone et al (2003) with modifications as described in Tonteri et al (2009). The polymerase chain reactions (PCR's) for 14 microsatellites were performed in three multiplexes according to Tonteri et al (2009).…”

Section: Samples Dna Extraction and Genotyping Proceduresmentioning

confidence: 99%

“…The polymerase chain reactions (PCR's) for 14 microsatellites were performed in three multiplexes according to Tonteri et al (2009). PCR products of each of the three multiplexes were pooled together and genotyped using an ABI Prism 3130xl (Applied Biosystems).…”

Section: Samples Dna Extraction and Genotyping Proceduresmentioning

confidence: 99%

“…About 8% of salmon individuals were genotyped twice to check the genotype repeatability. Genotypes for the same 14 microsatellite markers were available for eight anadromous populations from rivers flowing to the White and Barents seas (Titovka, Drozdovka, Ponoi Lebyazhya, Kitsa, Pulonga, Severnaya Dvina Padoma, and Pechora Pizhma) (Tonteri et al 2009). …”

Section: Samples Dna Extraction and Genotyping Proceduresmentioning

confidence: 99%

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Genetic structure of freshwater Atlantic salmon (Salmo salar L.) populations from the lakes Onega and Ladoga of northwest Russia and implications for conservation

et al. 2010

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Freshwater Atlantic salmon (Salmo salar L.) populations are a living example of adaptation to the changing conditions caused by glacial cycles. The uniqueness of these populations is emphasized by almost complete resistance to the dangerous parasite Gyrodactylus salaris. In Europe, freshwater salmon populations occur primarily in north-western Russia in the republic of Karelia. These systems include Lakes Ladoga and Onega, the two largest lakes in Europe, each of which harbours a number of freshwater salmon spawning rivers. We used microsatellite markers to study the genetic structure and temporal stability of 11 freshwater salmon populations in Russian Karelia. Populations clustered according their region of origin. Although temporal variation in allele frequencies was observed in the majority of temporal comparisons, various lines of evidence demonstrated that this influence was relatively minor compared to spatial variation that explained eight times more of the variability than temporal variation. Temporal stability tended to occur in populations from rivers with a higher linear lake coefficient. The high level of genetic structuring observed in both lake systems and the apparent low level of migration between populations suggests that treating each river as a separate management unit is recommended. In addition, as the number of populations is large, the best strategy for such fine scale management would be to ensure that the level of natural reproduction in each river is sufficient to sustain the population. A prioritization strategy for population conservation based on estimating the relative roles of different evolutionary forces shaping the gene pools highlighted a number of populations where further monitoring is warranted and also identified populations which could be prioritized for conservation as living gene banks in the event that conservation resources are limited. This prioritization agreed well with the occurrence of temporal (in)stability.

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Section: Genetic Substructurecontrasting

confidence: 79%

Section: Samples Dna Extraction and Genotyping Proceduresmentioning

confidence: 99%

Section: Samples Dna Extraction and Genotyping Proceduresmentioning

confidence: 99%

Section: Samples Dna Extraction and Genotyping Proceduresmentioning

confidence: 99%

See 2 more Smart Citations

Genetic structure of freshwater Atlantic salmon (Salmo salar L.) populations from the lakes Onega and Ladoga of northwest Russia and implications for conservation

et al. 2010

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“…After the examination of the parasite, host DNA was extracted from 111 Atlantic salmon specimens using the right pectoral fin clips according to Elphinstone et al (2003), with slight modifications as described in Tonteri et al (2009). Three separate multiplex polymerase chain reactions (PCR) were used to amplify 14 polymorphic Atlantic salmon microsatellites as described in Tonteri et al (2009).…”

Section: Methodsmentioning

confidence: 99%

High Gyrodactylus salaris infection rate in triploid Atlantic salmon Salmo salar

Ozerov¹,

Lumme²,

Päkk³

et al. 2010

Dis. Aquat. Org.

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We describe an unusually high infection rate of Gyrodactylus salaris Malmberg in juvenile Atlantic salmon Salmo salar L. of Baltic Sea origin, which are generally believed to be more resistant to G. salaris than East Atlantic salmon populations. Based on analyses of mitochondrial (complete cytochrome oxidase 1 [CO1] gene, 1548 bp) and nuclear (ADNAM1, 435 bp; internal transcribed spacer [ITS] rDNA region, 1232 bp) DNA fragments, the closest relatives of the characterized Estonian G. salaris strain were parasites found off the Swedish west coast and in Raasakka hatchery, Iijoki (Baltic Sea, Finland). Analyses of 14 microsatellite loci of the host S. salar revealed that approximately 40% of studied fish were triploids. We subsequently identified triploid Atlantic salmon of Baltic origin as more susceptible to G. salaris infection than their diploid counterparts, possibly due to compromised complement-dependent immune pathways in triploid salmon. This is in accordance with earlier studies that have shown elevated susceptibility of triploids to various viral or bacterial pathogens, and represents one of the first reports of increased susceptibility of triploid salmonid fish to an ectoparasite. However, further experimental work is needed to determine whether triploid Atlantic salmon is generally more susceptible to G. salaris compared to their diploid counterparts, irrespective of the particular triploidization method and population of origin. KEY WORDS: Atlantic salmon · Gyrodactylus salaris · Pathogen susceptibility · Triploid · Microsatellites · Baltic Sea Resale or republication not permitted without written consent of the publisherDis Aquat Org 91: [129][130][131][132][133][134][135][136] 2010 tect significant differences in susceptibility between diploid and triploid fish. For example, both diploid and triploid rainbow trout exposed to Vibrio ordalii, Aeromonas salmonicida, or infectious hematopoietic necrosis virus demonstrated similar mortality rates (Yamamoto & Iida 1995). Similar mortality rates between diploid and triploid Atlantic salmon were also observed after experimental infection with Renibacterium salmoninarum (Bruno & Johnstone 1990).Gyrodactylosis is a parasitic disease of salmonid fishes caused by the viviparous ectoparasite monogenean flatworm Gyrodactylus salaris, which belongs to the G. wageneri species-group, of the subgenus Limnonephrotus (family Gyrodactylidae, Malmberg, 1957). Due to 'hyperviviparity' (also known as a 'Russian doll' style of reproduction), combined with a rapid generation time, it reproduces fast, and in a matter of weeks a single worm can produce thousands of progeny , Buchmann 2008. G. salaris damages fish not only by consuming mucus and epithelial cells of the host but also by piercing the fish epithelium with its hooklets, compromising its osmoregulatory function, and leaving it vulnerable to fungal and bacterial infections. Importantly, Atlantic salmon populations exhibit marked differences in susceptibility to G. salaris infection, with populations fr...

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Population genetic analysis reveals a geographically limited transition zone between two genetically distinct Atlantic salmon lineages in Norway

Wennevik

Quintela

Skaala

et al. 2019

Ecology and Evolution

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Atlantic salmon is characterized by a high degree of population genetic structure throughout its native range. However, while populations inhabiting rivers in Norway and Russia make up a significant proportion of salmon in the Atlantic, thus far, genetic studies in this region have only encompassed low to modest numbers of populations. Here, we provide the first “in‐depth” investigation of population genetic structuring in the species in this region. Analysis of 18 microsatellites on >9,000 fish from 115 rivers revealed highly significant population genetic structure throughout, following a hierarchical pattern. The highest and clearest level of division separated populations north and south of the Lofoten region in northern Norway. In this region, only a few populations displayed intermediate genetic profiles, strongly indicating a geographically limited transition zone. This was further supported by a dedicated cline analysis. Population genetic structure was also characterized by a pattern of isolation by distance. A decline in overall genetic diversity was observed from the south to the north, and two of the microsatellites showed a clear decrease in number of alleles across the observed transition zone. Together, these analyses support results from previous studies, that salmon in Norway originate from two main genetic lineages, one from the Barents–White Sea refugium that recolonized northern Norwegian and adjacent Russian rivers, and one from the eastern Atlantic that recolonized the rest of Norway. Furthermore, our results indicate that local conditions in the limited geographic transition zone between the two observed lineages, characterized by open coastline with no obvious barriers to gene flow, are strong enough to maintain the genetic differentiation between them.

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Microsatellites reveal clear genetic boundaries among Atlantic salmon (Salmo salar) populations from the Barents and White seas, northwest Russia

Cited by 39 publications

References 49 publications

Genetic structure of freshwater Atlantic salmon (Salmo salar L.) populations from the lakes Onega and Ladoga of northwest Russia and implications for conservation

Genetic structure of freshwater Atlantic salmon (Salmo salar L.) populations from the lakes Onega and Ladoga of northwest Russia and implications for conservation

High Gyrodactylus salaris infection rate in triploid Atlantic salmon Salmo salar

Population genetic analysis reveals a geographically limited transition zone between two genetically distinct Atlantic salmon lineages in Norway

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