Open Access
Knowl. Manag. Aquat. Ecosyst.
Number 417, 2016
Article Number 3
Number of page(s) 4
Published online 07 January 2016
  • Als T.D., Hansen M.M., Maes G.E., Castongua M., Riemann L., Aarestrup K., Munk P., Sparholt H., Hanel R. and Bernatchez L., 2011. All roads lead to home: panmixia of European eel in the Sargasso Sea. Mol. Ecol., 20, 1333–1346. [CrossRef] [PubMed]
  • Altukhov Yu.P., Salmenkova E.A. and Omelchenko V.T., 2000. Salmonid fishes. Population biology, genetics and management, Blackwell Science, Oxford, 354 p.
  • Andrello M., Bevacqua D., Maes G.E. and De Leo G.A., 2011. An integrated genetic-demographic model to unravel the origin of genetic structure in European eel (Anguilla anguilla L.). Evol. Appl., 4, 517–533. [CrossRef] [PubMed]
  • Artamonova V.S., 2007. Genetic markers in population studies of Atlantic salmon Salmo salar L.: Karyotype characters and allozymes. Russ. J. Genetics, 43, 221–233. [CrossRef]
  • Côté C.L., Gagnaire P.A., Bourret V., Verreault G., Castonguay M. and Bernatchez L., 2013. Population genetics of the American eel (Anguilla rostrata): Fst = 0 and North Atlantic oscillation effects on demographic fluctuations of a panmictic species. Mol. Ecol., 22, 1763–1776. [CrossRef] [PubMed]
  • Crozier W.W., 1998. Genetic implications of hatchery rearing in Atlantic salmon: effects of rearing environment on genetic composition. J. Fish Biol., 52, 1014–1025. [CrossRef]
  • Gagnaire P.A., Albert V., Jónsson B. and Bernatchez L., 2009. Natural selection influences AFLP intraspecific genetic variability and introgression patterns in Atlantic eels. Mol. Ecol., 18, 1678–1691. [CrossRef] [PubMed]
  • Gagnaire P.A., Normandeau E., Côté C., Hansen M.M. and Bernatchez L., 2012. The genetic consequences of spatially varying selection in the panmictic American eel (Anguilla rostrata). Genetics, 190, 725–736. [CrossRef] [PubMed]
  • Golubtsov A.S., 1988. Intrapopulation variability in animals and protein polymorphism. Nauka Press, Moscow, 168 p. (in Russian).
  • Hedrick P.W., 2006. Genetic polymorphism in heterogeneous environments: The age of genomics. Annu. Rev. Ecol., Evol., and Systematics, 37, 67–93. [CrossRef]
  • Hoffmann A.A. and Willi Y., 2008. Detecting genetic responses to environmental change. Nat. Rev. Genetics, 9, 421–432. [CrossRef]
  • Jonsson B. and Jonsson N., 2011. Ecology of Atlantic Salmon and Brown Trout. Habitat as a Template for Life Histories. Springer, Dordrecht, 708 p.
  • King D.P.F., Hovey S.L., Thompson D. and Scott A., 1993. Mitochondrial DNA variation in Atlantic salmon, Salmo salar L., populations. J. Fish Biol., 42, 25–33.
  • Kirpichnikov V.S., Muske G.A., Scholl-Engberts A.D., Chernov V.M. and Borchsenius S.N., 1990. Genetic structure and allele frequency dynamics in the sockeye salmon population of Lake Dalneye, Kamchatka. Aquaculture, 84, 13–25. [CrossRef]
  • Larsen P.F., Schulte P.M. and Nielsen E.E., 2011. Gene expression analysis for the identification of selection and local adaptation in fishes. J. Fish Biol., 78, 1–22. [CrossRef] [PubMed]
  • Levene H., 1953. Genetic equilibrium when more than one ecological niche is available. American Naturalist, 87, 331–333. [CrossRef]
  • Makhrov A.A., Kuzishchin K.V. and Altukhov Yu.P., 1997. Association of allozyme heterozygosity with growth rate and ecological differentiation in brown trout Salmo trutta L. Russ. J. Genetics, 33, 568–573.
  • McCarthy I.D., Sanchez J.A. and Blanco G., 2003. Allozyme heterozygosity, date of first feeding and life history strategy in Atlantic salmon. J. Fish Biol., 62, 341–357. [CrossRef]
  • Nielsen R., 2005, Molecular signatures of natural selection. Annual Review of Genetics, 39, 197–218. [CrossRef] [PubMed]
  • Palm S., Dannewitz J., Prestegaard T. and Wickströmet H., 2009. Panmixia in European eel revisited: no genetic difference between maturing adults from southern and northern Europe. Heredity, 103, 82–89. [CrossRef] [PubMed]
  • Pampoulie C., Ruzzante D.E., Chosson V., Jörundsdóttir L., Taylor V., Thorsteinsson V., Daníelsdóttir A.K. and Marteinsdóttir G., 2006. The genetic structure of Atlantic cod (Gadus morhua) around Iceland: insight from microsatellites, the Pan I locus, and tagging experiments. Can. J. Fish. Aquat. Sci., 63, 2660–2674. [CrossRef]
  • Pampoulie C., Jakobsdóttir K.B., Marteinsdóttir G. and Thorsteinsson V., 2008. Are vertical behaviour patterns related to the pantophysin locus in the Atlantic cod (Gadus morhua L.)? Behaviour Genetics, 38, 76–81. [CrossRef]
  • Pineda H., Borrell Y.J., McCarthy I., Vázquez E., Sánchez J.A. and Blanco G., 2003. Timing of first feeding and life history strategies in salmon: genetic data. Hereditas, 139, 41–48. [CrossRef] [PubMed]
  • Pollard S.M., Danzmann R.G. and Claytor R.R., 1994. Association between the regulatory locus PGM-1r* and life-history types of juvenile Atlantic salmon (Salmo salar). Can. J. Fish. Aquat. Sci., 51, 1322–1329. [CrossRef]
  • Secor D.H., 2005. Fish migration and the unit stock: three formative debates. In: Cadrin S.X., Friedland K.D., Waldman J.R. (eds), Stock identification methods. Application in fishery science, Elsevier Academic Press, Amsterdam etc., 17–44.
  • Volis S. and Zhang Y.-H., 2010. Separating effects of gene flow and natural selection along an environmental gradient. Evol. Biol., 37, 187–199. [CrossRef]
  • Williams G.C. and Koehn R.K., 1984. Population genetics of North Atlantic catadromous eels (Anguilla). In: Terner B.J. (ed.), Evolutionary Genetics of Fishes, Plenum Press, New York and London, 529–560.

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