Formation of population genetic structure following the introduction and establishment of non-native American shad (Alosa sapidissima) along the Pacific Coast of North America

Daniel J. Hasselman; Paul Bentzen; Shawn R. Narum; Thomas P. Quinn

doi:10.1007/s10530-018-1763-7

Formation of population genetic structure following the introduction and establishment of non-native American shad (Alosa sapidissima) along the Pacific Coast of North America

Daniel J. Hasselman, Paul Bentzen, Shawn R. Narum, Thomas P. Quinn

Medicine, Science

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

8 Citas (Scopus)

Resumen

Biological invasions provide opportunities to examine contemporary evolutionary processes in novel environments. American shad, an anadromous fish native to the Atlantic Coast of North America, was introduced to California in 1871 and established spawning populations along the Pacific Coast that may provide insights into the dynamics of dispersal, colonization, and the establishment of philopatry. Using 13 neutral microsatellite loci we genotyped anadromous, freshwater resident and landlocked American shad from 14 locations along the US Pacific Coast to resolve population genetic structure. We observed significant differences in multilocus allele frequency distributions in nearly all (61/66; 92%) pairwise comparisons of non-native anadromous, freshwater resident and landlocked populations, and detected significant genetic differentiation for most (55/66; 83%) of these comparisons. Genetic divergence between landlocked and anadromous populations is due to genetic drift in isolation because of a physical migration barrier. However, some reproductive isolating mechanism maintains genetic differentiation between sympatric populations in the Columbia River exhibiting alternative life history strategies (i.e. anadromous vs. ‘freshwater-type’). Non-native populations possessed genetic variants that were not observed in the species’ native range and were strongly differentiated from Atlantic Coast populations (GST′ = 0.218). Our results indicate that philopatry became established shortly after dispersal and colonization along the Pacific Coast. This study contributes to our understanding of dynamic evolutionary processes during invasions.

Idioma original	English
Páginas (desde-hasta)	3123-3143
Número de páginas	21
Publicación	Biological Invasions
Volumen	20
N.º	11
DOI	https://doi.org/10.1007/s10530-018-1763-7
Estado	Published - nov. 1 2018

Nota bibliográfica

Funding Information:
Acknowledgements This research would not have been possible without assistance from many federal (National Marine Fisheries Service, US Geological Survey, US Army Corps of Engineers) and state-level resource management agencies (Washington Department of Fish and Wildlife, Oregon Department of Fish and Wildlife, California Department of Fish and Wildlife), tribal governments (Columbia River Inter-Tribal Fish Commission, Yurok tribe, Karuk tribe), non-governmental organizations (Skagit River System Cooperative, Bonneville Power Administration), academic partners (University of Idaho, University of California Davis), and countless recreational fishers who collected specimens on our behalf. We thank members of the Marine Gene Probe Laboratory (M.C. McBride, I.P. Paterson) for laboratory assistance. We thank M.A Beaumont for assistance with the program 2MOD, and B. Wasserman for assistance creating associated figures. We thank T. Apgar for assistance with ArcGIS 10.2 in measuring distances among rivers, and K. Dlugosch for analytical advice. We also thank Phil Roni and Blake Feist for their contributions, three anonymous reviewers and an associate editor whose constructive comments greatly improved the quality of this manuscript. This work was conducted under IACUC protocol #2442-30 at the University of Washington and was supported by the Cooperative Institute for Limnology and Ecosystems Research at the University of Michigan and a NOAA (Great Lakes Environmental Research Laboratory) Aquatic Invasive Species Program (AISP) Grant (No. NA07OAR4320006) to DJH at the School of Aquatic and Fishery Sciences, University of Washington.

Funding Information:
This research would not have been possible without assistance from many federal (National Marine Fisheries Service, US Geological Survey, US Army Corps of Engineers) and state-level resource management agencies (Washington Department of Fish and Wildlife, Oregon Department of Fish and Wildlife, California Department of Fish and Wildlife), tribal governments (Columbia River Inter-Tribal Fish Commission, Yurok tribe, Karuk tribe), non-governmental organizations (Skagit River System Cooperative, Bonneville Power Administration), academic partners (University of Idaho, University of California Davis), and countless recreational fishers who collected specimens on our behalf. We thank members of the Marine Gene Probe Laboratory (M.C. McBride, I.P. Paterson) for laboratory assistance. We thank M.A Beaumont for assistance with the program 2MOD , and B. Wasserman for assistance creating associated figures. We thank T. Apgar for assistance with ArcGIS 10.2 in measuring distances among rivers, and K. Dlugosch for analytical advice. We also thank Phil Roni and Blake Feist for their contributions, three anonymous reviewers and an associate editor whose constructive comments greatly improved the quality of this manuscript. This work was conducted under IACUC protocol #2442-30 at the University of Washington and was supported by the Cooperative Institute for Limnology and Ecosystems Research at the University of Michigan and a NOAA (Great Lakes Environmental Research Laboratory) Aquatic Invasive Species Program (AISP) Grant (No. NA07OAR4320006) to DJH at the School of Aquatic and Fishery Sciences, University of Washington.

Publisher Copyright:
© 2018, Springer International Publishing AG, part of Springer Nature.

ASJC Scopus Subject Areas

Ecology, Evolution, Behavior and Systematics
Ecology

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10.1007/s10530-018-1763-7

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Formation of population genetic structure following the introduction and establishment of non-native American shad (Alosa sapidissima) along the Pacific Coast of North America. / Hasselman, Daniel J.; Bentzen, Paul; Narum, Shawn R. et al.
En: Biological Invasions, Vol. 20, N.º 11, 01.11.2018, p. 3123-3143.

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

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abstract = "Biological invasions provide opportunities to examine contemporary evolutionary processes in novel environments. American shad, an anadromous fish native to the Atlantic Coast of North America, was introduced to California in 1871 and established spawning populations along the Pacific Coast that may provide insights into the dynamics of dispersal, colonization, and the establishment of philopatry. Using 13 neutral microsatellite loci we genotyped anadromous, freshwater resident and landlocked American shad from 14 locations along the US Pacific Coast to resolve population genetic structure. We observed significant differences in multilocus allele frequency distributions in nearly all (61/66; 92%) pairwise comparisons of non-native anadromous, freshwater resident and landlocked populations, and detected significant genetic differentiation for most (55/66; 83%) of these comparisons. Genetic divergence between landlocked and anadromous populations is due to genetic drift in isolation because of a physical migration barrier. However, some reproductive isolating mechanism maintains genetic differentiation between sympatric populations in the Columbia River exhibiting alternative life history strategies (i.e. anadromous vs. {\textquoteleft}freshwater-type{\textquoteright}). Non-native populations possessed genetic variants that were not observed in the species{\textquoteright} native range and were strongly differentiated from Atlantic Coast populations (GST′ = 0.218). Our results indicate that philopatry became established shortly after dispersal and colonization along the Pacific Coast. This study contributes to our understanding of dynamic evolutionary processes during invasions.",

author = "Hasselman, {Daniel J.} and Paul Bentzen and Narum, {Shawn R.} and Quinn, {Thomas P.}",

note = "Funding Information: Acknowledgements This research would not have been possible without assistance from many federal (National Marine Fisheries Service, US Geological Survey, US Army Corps of Engineers) and state-level resource management agencies (Washington Department of Fish and Wildlife, Oregon Department of Fish and Wildlife, California Department of Fish and Wildlife), tribal governments (Columbia River Inter-Tribal Fish Commission, Yurok tribe, Karuk tribe), non-governmental organizations (Skagit River System Cooperative, Bonneville Power Administration), academic partners (University of Idaho, University of California Davis), and countless recreational fishers who collected specimens on our behalf. We thank members of the Marine Gene Probe Laboratory (M.C. McBride, I.P. Paterson) for laboratory assistance. We thank M.A Beaumont for assistance with the program 2MOD, and B. Wasserman for assistance creating associated figures. We thank T. Apgar for assistance with ArcGIS 10.2 in measuring distances among rivers, and K. Dlugosch for analytical advice. We also thank Phil Roni and Blake Feist for their contributions, three anonymous reviewers and an associate editor whose constructive comments greatly improved the quality of this manuscript. This work was conducted under IACUC protocol #2442-30 at the University of Washington and was supported by the Cooperative Institute for Limnology and Ecosystems Research at the University of Michigan and a NOAA (Great Lakes Environmental Research Laboratory) Aquatic Invasive Species Program (AISP) Grant (No. NA07OAR4320006) to DJH at the School of Aquatic and Fishery Sciences, University of Washington. Funding Information: This research would not have been possible without assistance from many federal (National Marine Fisheries Service, US Geological Survey, US Army Corps of Engineers) and state-level resource management agencies (Washington Department of Fish and Wildlife, Oregon Department of Fish and Wildlife, California Department of Fish and Wildlife), tribal governments (Columbia River Inter-Tribal Fish Commission, Yurok tribe, Karuk tribe), non-governmental organizations (Skagit River System Cooperative, Bonneville Power Administration), academic partners (University of Idaho, University of California Davis), and countless recreational fishers who collected specimens on our behalf. We thank members of the Marine Gene Probe Laboratory (M.C. McBride, I.P. Paterson) for laboratory assistance. We thank M.A Beaumont for assistance with the program 2MOD , and B. Wasserman for assistance creating associated figures. We thank T. Apgar for assistance with ArcGIS 10.2 in measuring distances among rivers, and K. Dlugosch for analytical advice. We also thank Phil Roni and Blake Feist for their contributions, three anonymous reviewers and an associate editor whose constructive comments greatly improved the quality of this manuscript. This work was conducted under IACUC protocol #2442-30 at the University of Washington and was supported by the Cooperative Institute for Limnology and Ecosystems Research at the University of Michigan and a NOAA (Great Lakes Environmental Research Laboratory) Aquatic Invasive Species Program (AISP) Grant (No. NA07OAR4320006) to DJH at the School of Aquatic and Fishery Sciences, University of Washington. Publisher Copyright: {\textcopyright} 2018, Springer International Publishing AG, part of Springer Nature.",

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T1 - Formation of population genetic structure following the introduction and establishment of non-native American shad (Alosa sapidissima) along the Pacific Coast of North America

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N1 - Funding Information: Acknowledgements This research would not have been possible without assistance from many federal (National Marine Fisheries Service, US Geological Survey, US Army Corps of Engineers) and state-level resource management agencies (Washington Department of Fish and Wildlife, Oregon Department of Fish and Wildlife, California Department of Fish and Wildlife), tribal governments (Columbia River Inter-Tribal Fish Commission, Yurok tribe, Karuk tribe), non-governmental organizations (Skagit River System Cooperative, Bonneville Power Administration), academic partners (University of Idaho, University of California Davis), and countless recreational fishers who collected specimens on our behalf. We thank members of the Marine Gene Probe Laboratory (M.C. McBride, I.P. Paterson) for laboratory assistance. We thank M.A Beaumont for assistance with the program 2MOD, and B. Wasserman for assistance creating associated figures. We thank T. Apgar for assistance with ArcGIS 10.2 in measuring distances among rivers, and K. Dlugosch for analytical advice. We also thank Phil Roni and Blake Feist for their contributions, three anonymous reviewers and an associate editor whose constructive comments greatly improved the quality of this manuscript. This work was conducted under IACUC protocol #2442-30 at the University of Washington and was supported by the Cooperative Institute for Limnology and Ecosystems Research at the University of Michigan and a NOAA (Great Lakes Environmental Research Laboratory) Aquatic Invasive Species Program (AISP) Grant (No. NA07OAR4320006) to DJH at the School of Aquatic and Fishery Sciences, University of Washington. Funding Information: This research would not have been possible without assistance from many federal (National Marine Fisheries Service, US Geological Survey, US Army Corps of Engineers) and state-level resource management agencies (Washington Department of Fish and Wildlife, Oregon Department of Fish and Wildlife, California Department of Fish and Wildlife), tribal governments (Columbia River Inter-Tribal Fish Commission, Yurok tribe, Karuk tribe), non-governmental organizations (Skagit River System Cooperative, Bonneville Power Administration), academic partners (University of Idaho, University of California Davis), and countless recreational fishers who collected specimens on our behalf. We thank members of the Marine Gene Probe Laboratory (M.C. McBride, I.P. Paterson) for laboratory assistance. We thank M.A Beaumont for assistance with the program 2MOD , and B. Wasserman for assistance creating associated figures. We thank T. Apgar for assistance with ArcGIS 10.2 in measuring distances among rivers, and K. Dlugosch for analytical advice. We also thank Phil Roni and Blake Feist for their contributions, three anonymous reviewers and an associate editor whose constructive comments greatly improved the quality of this manuscript. This work was conducted under IACUC protocol #2442-30 at the University of Washington and was supported by the Cooperative Institute for Limnology and Ecosystems Research at the University of Michigan and a NOAA (Great Lakes Environmental Research Laboratory) Aquatic Invasive Species Program (AISP) Grant (No. NA07OAR4320006) to DJH at the School of Aquatic and Fishery Sciences, University of Washington. Publisher Copyright: © 2018, Springer International Publishing AG, part of Springer Nature.

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N2 - Biological invasions provide opportunities to examine contemporary evolutionary processes in novel environments. American shad, an anadromous fish native to the Atlantic Coast of North America, was introduced to California in 1871 and established spawning populations along the Pacific Coast that may provide insights into the dynamics of dispersal, colonization, and the establishment of philopatry. Using 13 neutral microsatellite loci we genotyped anadromous, freshwater resident and landlocked American shad from 14 locations along the US Pacific Coast to resolve population genetic structure. We observed significant differences in multilocus allele frequency distributions in nearly all (61/66; 92%) pairwise comparisons of non-native anadromous, freshwater resident and landlocked populations, and detected significant genetic differentiation for most (55/66; 83%) of these comparisons. Genetic divergence between landlocked and anadromous populations is due to genetic drift in isolation because of a physical migration barrier. However, some reproductive isolating mechanism maintains genetic differentiation between sympatric populations in the Columbia River exhibiting alternative life history strategies (i.e. anadromous vs. ‘freshwater-type’). Non-native populations possessed genetic variants that were not observed in the species’ native range and were strongly differentiated from Atlantic Coast populations (GST′ = 0.218). Our results indicate that philopatry became established shortly after dispersal and colonization along the Pacific Coast. This study contributes to our understanding of dynamic evolutionary processes during invasions.

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Formation of population genetic structure following the introduction and establishment of non-native American shad (Alosa sapidissima) along the Pacific Coast of North America

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