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N. Takezaki, M. Nei, K. Tamura (2010)
POPTREE2: Software for constructing population trees from allele frequency data and computing other population statistics with Windows interface.Molecular biology and evolution, 27 4
J. Gilbey, E. Cauwelier, M. Coulson, L. Stradmeyer, J. Sampayo, Anja Armstrong, E. Verspoor, L. Corrigan, J. Shelley, S. Middlemas (2016)
Accuracy of Assignment of Atlantic Salmon (Salmo salar L.) to Rivers and Regions in Scotland and Northeast England Based on Single Nucleotide Polymorphism (SNP) MarkersPLoS ONE, 11
E. Cauwelier, J. Gilbey, J. Sampayo, L. Stradmeyer, S. Middlemas (2018)
Identification of a single genomic region associated with seasonal river return timing in adult Scottish Atlantic salmon (Salmo salar), using a genome-wide association studyCanadian Journal of Fisheries and Aquatic Sciences
A. Griffiths, G. Machado-Schiaffino, E. Dillane, J. Coughlan, J. Horreo, A. Bowkett, P. Minting, S. Toms, W. Roche, P. Gargan, P. McGinnity, T. Cross, D. Bright, E. Garcia-Vazquez, J. Stevens (2010)
Genetic stock identification of Atlantic salmon (Salmo salar) populations in the southern part of the European rangeBMC Genetics, 11
D. Reddin, K. Friedland (1999)
A history of identification to continent of origin of Atlantic salmon (Salmo salar L.) at west Greenland, 1969–1997Fisheries Research, 43
J. Corander, P. Waldmann, M. Sillanpää (2003)
Bayesian analysis of genetic differentiation between populations.Genetics, 163 1
B. Phillips, G. Brown, R. Shine (2010)
Evolutionarily accelerated invasions: the rate of dispersal evolves upwards during the range advance of cane toadsJournal of Evolutionary Biology, 23
J. Webb, H. McLay (1996)
Variation in the time of spawning of Atlantic salmon (Salmo salar) and its relationship to temperature in the Aberdeenshire Dee, ScotlandCanadian Journal of Fisheries and Aquatic Sciences, 53
E. Dillane, P. McGinnity, J. Coughlan, M. Cross, E. Eyto, Ellen Kenchington, P. Prodöhl, Thomas Cross (2008)
Demographics and landscape features determine intrariver population structure in Atlantic salmon (Salmo salar L.): the case of the River Moy in IrelandMolecular Ecology, 17
A. Dittman, Thomas Quinn (1996)
Homing in Pacific salmon: mechanisms and ecological basisThe Journal of experimental biology, 199 Pt 1
R. Buck, D. Hay (1984)
The relation between stock size and progeny of Atlantic salmon, Salmo salar L., in a Scottish streamJournal of Fish Biology, 24
Juha‐Pekka Vähä, J. Erkinaro, E. Niemelä, C. Primmer (2007)
Life‐history and habitat features influence the within‐river genetic structure of Atlantic salmonMolecular Ecology, 16
M. Nei, F. Tajima, Y. Tateno (1983)
Accuracy of estimated phylogenetic trees from molecular dataJournal of Molecular Evolution, 19
Jean-Sébastien Moore, V. Bourret, M. Dionne, I. Bradbury, P. O’Reilly, M. Kent, G. Chaput, L. Bernatchez (2014)
Conservation genomics of anadromous Atlantic salmon across its North American range: outlier loci identify the same patterns of population structure as neutral lociMolecular Ecology, 23
K. Elo (2004)
Gene flow and conservation of genetic variation in anadromous Atlantic salmon (Salmo salar)Hereditas, 119
Anni Tonteri, A. Veselov, A. Zubchenko, J. Lumme, C. Primmer (2009)
Microsatellites reveal clear genetic boundaries among Atlantic salmon (Salmo salar) populations from the Barents and White seas, northwest RussiaCanadian Journal of Fisheries and Aquatic Sciences, 66
Sudhir Kumar, G. Stecher, K. Tamura (2016)
MEGA7: Molecular Evolutionary Genetics Analysis Version 7.0 for Bigger Datasets.Molecular biology and evolution, 33 7
B. Jonsson, N. Jonsson, L. Hansen (2003)
Atlantic salmon straying from the River ImsaJournal of Fish Biology, 62
C. Perrier, R. Guyomard, J. Baglinière, G. Evanno (2011)
Determinants of hierarchical genetic structure in Atlantic salmon populations: environmental factors vs. anthropogenic influencesMolecular Ecology, 20
Marjatta Säisä, M. Koljonen, R. Gross, J. Nilsson, J. Tähtinen, J. Koskiniemi, A. Vasemägi (2005)
Population genetic structure and postglacial colonization of Atlantic salmon (Salmo salar )i n the Baltic Sea area based on microsatellite DNA variationCanadian Journal of Fisheries and Aquatic Sciences, 62
Julian Dodson, R Gibson, R. Cunjak, K. Friedland, C. Leaniz, Mart Gross, R. Newbury, Jennifer Nielsen, Mary Power, Steven Roy (1998)
Elements in the development of conservation plans for Atlantic salmon (Salmo salar)Canadian Journal of Fisheries and Aquatic Sciences, 55
K. Crandall, O. Bininda-Emonds, G. Mace, R. Wayne (2000)
Considering evolutionary processes in conservation biology.Trends in ecology & evolution, 15 7
D. Garant, J. Dodson, L. Bernatchez (2000)
Ecological determinants and temporal stability of the within‐river population structure in Atlantic salmon (Salmo salar L.) *Molecular Ecology, 9
L. Excoffier, H. Lischer (2010)
Arlequin suite ver 3.5: a new series of programs to perform population genetics analyses under Linux and WindowsMolecular Ecology Resources, 10
Owen Jones, Jinliang Wang (2010)
COLONY: a program for parentage and sibship inference from multilocus genotype dataMolecular Ecology Resources, 10
B. Jonsson, N. Jonsson, L. Hansen (1991)
Differences in life history and migratory behaviour between wild and hatchery-reared Atlantic salmon in natureAquaculture, 98
S. Lien, L. Gidskehaug, T. Moen, B. Hayes, P. Berg, W. Davidson, S. Omholt, M. Kent (2011)
A dense SNP-based linkage map for Atlantic salmon (Salmo salar) reveals extended chromosome homeologies and striking differences in sex-specific recombination patternsBMC Genomics, 12
F. Palstra, M. O’Connell, D. Ruzzante (2007)
Population structure and gene flow reversals in Atlantic salmon (Salmo salar) over contemporary and long‐term temporal scales: effects of population size and life historyMolecular Ecology, 16
E. Verspoor, W. Jordan (2006)
Genetic variation at the Me-2 locus in the Atlantic salmon within and between rivers: evidence for its selective maintenanceJournal of Fish Biology, 35
P. Fontaine, J. Dodson, L. Bernatchez, A. Slettan (1997)
A genetic test of metapopulation structure in Atlantic salmon (Salmo salar) using microsatellitesCanadian Journal of Fisheries and Aquatic Sciences, 54
(2015)
Salmon and sea Trout Catches 2015
T. Quinn, E. Volk, A. Hendry (1999)
Natural otolith microstructure patterns reveal precise homing to natal incubation sites by sockeye salmon (Oncorhynchus nerka)Canadian Journal of Zoology, 77
C. Perrier, É. Normandeau, M. Dionne, A. Richard, L. Bernatchez (2014)
Alternative reproductive tactics increase effective population size and decrease inbreeding in wild Atlantic salmonEvolutionary Applications, 7
Craig Primmer, Craig Primmer, A. Veselov, Alexander Zubchenko, A. Poututkin, Igor Bakhmet, Mikko Koskinen (2006)
Isolation by distance within a river system: genetic population structuring of Atlantic salmon, Salmo salar, in tributaries of the Varzuga River in northwest RussiaMolecular Ecology, 15
O. Stabell (1984)
HOMING AND OLFACTION IN SALMONIDS: A CRITICAL REVIEW WITH SPECIAL REFERENCE TO THE ATLANTIC SALMONBiological Reviews, 59
A. Youngson, W. Jordan, D. Hay (1994)
Homing of Atlantic salmon (Salmo salar L.) to a tributary spawning stream in a major river catchmentAquaculture, 121
C. Leaniz, I. Fleming, S. Einum, E. Verspoor, W. Jordan, S. Consuegra, N. Aubin‐Horth, D. Lajus, B. Letcher, A. Youngson, J. Webb, L. Vøllestad, B. Villanueva, A. Ferguson, T. Quinn (2007)
A critical review of adaptive genetic variation in Atlantic salmon: implications for conservationBiological Reviews, 82
J. Dietrich, R. Cunjak (2006)
Evaluation of the Impacts of Carlin Tags, Fin Clips, and Panjet Tattoos on Juvenile Atlantic SalmonNorth American Journal of Fisheries Management, 26
E. Potter, J. MacLean, R. Wyatt, R. Campbell (2003)
Managing the exploitation of migratory salmonidsFisheries Research, 62
V. Bourret, M. Kent, C. Primmer, A. Vasemägi, S. Karlsson, K. Hindar, P. McGinnity, E. Verspoor, L. Bernatchez, S. Lien (2013)
SNP‐array reveals genome‐wide patterns of geographical and potential adaptive divergence across the natural range of Atlantic salmon (Salmo salar)Molecular Ecology, 22
A. Youngson, W. Jordan, E. Verspoor, P. McGinnity, T. Cross, A. Ferguson (2003)
Management of salmonid fisheries in the British Isles: towards a practical approach based on population geneticsFisheries Research, 62
M. Dionne, F. Caron, J. Dodson, L. Bernatchez (2009)
Comparative survey of within-river genetic structure in Atlantic salmon; relevance for management and conservationConservation Genetics, 10
E. Verspoor (1997)
Genetic diversity among Atlantic salmon (Salmo salar L.) populationsIces Journal of Marine Science, 54
M. Dionne, F. Caron, J. Dodson, L. Bernatchez (2008)
Landscape genetics and hierarchical genetic structure in Atlantic salmon: the interaction of gene flow and local adaptationMolecular Ecology, 17
Colin Millar, Robert Fryer, K. Millidine, I. Malcolm (2016)
Modelling capture probability of Atlantic salmon (Salmo salar) from a diverse national electrofishing dataset: Implications for the estimation of abundanceFisheries Research, 177
D. Stewart, Gordon Smith, A. Youngson (2002)
Tributary-specific variation in timing of return of adult Atlantic salmon (Salmo salar) to fresh water has a genetic componentCanadian Journal of Fisheries and Aquatic Sciences, 59
Juha‐Pekka Vähä, J. Erkinaro, E. Niemelä, C. Primmer, I. Saloniemi, M. Johansen, M. Svenning, S. Brørs (2010)
Temporally stable population-specific differences in run timing of one-sea-winter Atlantic salmon returning to a large river systemEvolutionary Applications, 4
T. Heggberget, L. Hansen, T. Næsje (1988)
Within-River Spawning Migration of Atlantic Salmon (Salmo salar)Canadian Journal of Fisheries and Aquatic Sciences, 45
R. Peakall, P. Smouse (2012)
GenAlEx 6.5: genetic analysis in Excel. Population genetic software for teaching and research—an updateBioinformatics, 28
I. Bradbury, L. Hamilton, M. Robertson, C. Bourgeois, Atef Mansour, J. Dempson (2014)
Landscape structure and climatic variation determine Atlantic salmon genetic connectivity in the Northwest AtlanticCanadian Journal of Fisheries and Aquatic Sciences, 71
The aim of this study was to examine the genetic structuring, based on c. 4300 single nucleotide polymorphic markers, of juvenile Atlantic salmon Salmo salar sampled from 11 rivers in north‐east Scotland, which form part of a radial drainage system. Within this area, sites in the upper mountainous and lower coastal sections of the different rivers were more closely related than sites from the upper and lower sections of the same river. Differentiation between fish from upper and lower sections was related to both distance from the sea and elevation, which were themselves correlated. The occurrence of such cross‐river genetic grouping appears to be the result of both similar selective pressures resulting in homologous adaptive differences within each river and also recent common ancestry between rivers. Examination of historical tagging information showed high rates (27·4%) of between‐river straying in this region that may help to maintain the across rather than between‐river structure. The existence of cross‐river groupings highlights the complex structuring of S. salar populations and may confound genetic identification of single‐river stocks. Furthermore, the results presented show that cross‐river structuring should also be an important consideration in managing S. salar stocks.
Journal of Fish Biology – Wiley
Published: Jan 1, 2018
Keywords: ; ; ; ; ;
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