TY - JOUR
T1 - A large wild salmon stock shows genetic and life history differentiation within, but not between, rivers
AU - Miettinen, Antti
AU - Palm, Stefan
AU - Dannewitz, Johan
AU - Lind, Emma
AU - Primmer, Craig R.
AU - Romakkaniemi, Atso
AU - Östergren, Johan
AU - Pritchard, Victoria L.
N1 - Funding Information:
Open access funding provided by University of Helsinki including Helsinki University Central Hospital. The study was funded by fishing license revenues from the Tornio River, The Swedish Agency for Marine and Water Management, The Swedish Research Council Formas (Grant/Award 2013-1288 to JÖ), Societas pro Fauna et Flora Fennica, The Betty Väänänen Fund from The Kuopio Naturalists’ Society (KLYY), The Raija and Ossi Tuuliainen Foundation (Raija ja Ossi Tuuliaisen Säätiö), and The Baltic Sea Fund from The Finnish Foundation for Nature Conservation (Suomen Luonnonsuojelun Säätiö) (grants to AM). Acknowledgements
Funding Information:
The study was funded by fishing license revenues from the Tornio/Torne River, The Swedish Agency for Marine and Water Management, Grant/Award 2013-1288 to JÖ from the Swedish Research Council Formas and grants to AM from Societas pro Fauna et Flora Fennica, The Betty Väänänen Fund from The Kuopio Naturalists’ Society (KLYY), The Raija and Ossi Tuuliainen Foundation, and The Finnish Foundation for Nature Conservation’s Baltic Sea Fund. We would like to thank Anders Asp (original map used for Fig. ), field workers and other staff for assistance with the research material (Markku Kilpala, Stefan Stridsman, Ville Vähä, Kari Pulkkinen, Matti Ankkuriniemi, Irmeli Torvi and Rauno Hokki), Tore Prestegaard and Linda Söderberg for lab assistance, Paul Debes for statistical discussions, two anonymous reviewers for their helpful comments that improved the manuscript, and the anglers who collected the adult samples along the Tornio River.
Publisher Copyright:
© 2020, The Author(s).
Copyright:
Copyright 2021 Elsevier B.V., All rights reserved.
PY - 2021/2/28
Y1 - 2021/2/28
N2 - Anadromous salmonid fishes frequently exhibit strong geographic population structuring. However, population genetic differentiation of Atlantic salmon (Salmo salar) at fine geographic scales differs across equivalent spatial extents in different regions. So far, fine-scale genetic differentiation has not been assessed in rivers of the Baltic Sea, a region that contains an evolutionarily distinct Atlantic salmon lineage. Thus, Baltic salmon are currently managed on the river level, without focus on potential genetic structure and diversity within rivers. Here, we used microsatellites to characterize the genetic structure of wild juvenile salmon sampled throughout the interconnected, northern Baltic Tornio and Kalix Rivers. We found genetic differentiation within the two rivers, but not between them: salmon in the upper reaches differed from individuals in the lower reaches, regardless of river system. Further, examining smolts migrating from the river to the sea and adults returning from the sea to spawn, we found an association between the genetic structure and seasonal migration timing. Out-migrating smolts genetically assigned to upper river reaches were older and tended to reach the sea later in the season than smolts from the lower reaches. In contrast, mature adults originating from the upper reaches returned to the river early in the season. Our observation of genetic population structuring between downstream and upstream reaches of the large Tornio and Kalix rivers, and its association with migration timing, implies that careful temporal management of the northern Baltic fisheries would help to preserve the diversity and sustainability of the wild salmon stocks of these rivers.
AB - Anadromous salmonid fishes frequently exhibit strong geographic population structuring. However, population genetic differentiation of Atlantic salmon (Salmo salar) at fine geographic scales differs across equivalent spatial extents in different regions. So far, fine-scale genetic differentiation has not been assessed in rivers of the Baltic Sea, a region that contains an evolutionarily distinct Atlantic salmon lineage. Thus, Baltic salmon are currently managed on the river level, without focus on potential genetic structure and diversity within rivers. Here, we used microsatellites to characterize the genetic structure of wild juvenile salmon sampled throughout the interconnected, northern Baltic Tornio and Kalix Rivers. We found genetic differentiation within the two rivers, but not between them: salmon in the upper reaches differed from individuals in the lower reaches, regardless of river system. Further, examining smolts migrating from the river to the sea and adults returning from the sea to spawn, we found an association between the genetic structure and seasonal migration timing. Out-migrating smolts genetically assigned to upper river reaches were older and tended to reach the sea later in the season than smolts from the lower reaches. In contrast, mature adults originating from the upper reaches returned to the river early in the season. Our observation of genetic population structuring between downstream and upstream reaches of the large Tornio and Kalix rivers, and its association with migration timing, implies that careful temporal management of the northern Baltic fisheries would help to preserve the diversity and sustainability of the wild salmon stocks of these rivers.
KW - Atlantic salmon
KW - Baltic Sea
KW - Isolation by distance
KW - Mixed stock analysis
KW - Population genetics
KW - Run timing
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U2 - 10.1007/s10592-020-01317-y
DO - 10.1007/s10592-020-01317-y
M3 - Article
AN - SCOPUS:85096074085
SN - 1566-0621
VL - 22
SP - 35
EP - 51
JO - Conservation Genetics
JF - Conservation Genetics
IS - 1
ER -