Morphological consequences of hybridization between farm and wild Atlantic salmon Salmo salar under both wild and experimental conditions

B. M. Perriman; P. Bentzen; B. F. Wringe; S. Duffy; S. S. Islam; I. A. Fleming; M. F. Solberg; I. R. Bradbury

doi:10.3354/aei00429

Morphological consequences of hybridization between farm and wild Atlantic salmon Salmo salar under both wild and experimental conditions

B. M. Perriman, P. Bentzen, B. F. Wringe, S. Duffy, S. S. Islam, I. A. Fleming, M. F. Solberg, I. R. Bradbury

Résultat de recherche: Article › examen par les pairs

4 Citations (Scopus)

Résumé

The escape of Atlantic salmon Salmo salar from aquaculture has been identified as a significant threat to the persistence and stability of wild salmon populations. Yet the magnitude of phenotypic impacts due to hybridization remains largely unresolved. We evaluated the phenotypic consequences of hybridization using geometric morphometrics both under natural conditions in the wild and in the laboratory using common garden experiments. Juvenile Atlantic salmon field-collected in 2015 and 2016 from 18 southern Newfoundland rivers were classified as pure wild, pure farm, or F₁ hybrids using genetic assignment. Overall size and shape differences between wild and farm, and wild and F₁ hybrid individuals were small, largely size related, and present between pure farm and other crosses. Laboratory-reared pure wild, pure farm, and F₁ hybrid salmon were grown in tank and semi-natural conditions. Wild fish were significantly larger than both farm and hybrid salmon at first feeding; these size differences remained at 80 d post first feeding under semi-natural conditions, but all crosses were the same size in tank conditions, and there were no differences between pure farm and hybrid individuals under either condition. Significant shape differences were present among all pairwise comparisons under tank conditions, and in semi-natural conditions, pure wild individuals differed significantly from pure farm and hybrid individuals. Our results suggest phenotypic differences observed under laboratory conditions between wild and farmxwild hybrid individuals may not be appreciable in the wild, and that significant genetic changes may occur in wild populations experiencing hybridization in the absence of obvious large phenotypic changes.

Langue d'origine	English
Pages (de-à)	85-96
Nombre de pages	12
Journal	Aquaculture Environment Interactions
Volume	14
DOI	https://doi.org/10.3354/aei00429
Statut de publication	Published - 2022

Note bibliographique

Funding Information:
The authors thank the Newfoundland DFO Salmonids section for salmon tissue sampling and Nick Jeffery and Ryan Stanley for help with analyses. The authors also thank Beth Watson for helpful advice and D. Saunders, K. B⊘e, and C. Conway for assistance with tagging and rearing of fish in the common garden experiments. Acquisition of aquaculture salmon baseline samples was facilitated by G. Perry, C. Hendry, DFO Aquaculture section Newfoundland Region, and by industry partners Cooke Aquaculture and Northern Harvest Sea Farms. We also thank the staff of the Aquatic Biotechnology Laboratory of the Bedford Institute of Oceanography for their work in the SNP genotyping. This study was funded through the Program for Aquaculture Regulatory Research of Fisheries and Oceans Canada, the Genomics Research and Development Initiative of Canada, as well as the Natural Sciences and Engineering Research Council of Canada, and was supported by the Atlantic Salmon Federation. M.F.S. was supported by the Research Council of Norway (grant no. 310599).

Funding Information:
DFO Salmonids section for salmon tissue sampling and Nick Jeffery and Ryan Stanley for help with analyses. The authors also thank Beth Watson for helpful advice and D. Saunders, K. Bøe, and C. Conway for assistance with tagging and rearing of fish in the common garden experiments. Acquisition of aquaculture salmon baseline samples was facilitated by G. Perry, C. Hendry, DFO Aquaculture section Newfoundland Region, and by industry partners Cooke Aquaculture and Northern Harvest Sea Farms. We also thank the staff of the Aquatic Biotechnology Laboratory of the Bedford Institute of Oceanography for their work in the SNP genotyping. This study was funded through the Program for Aquaculture Regulatory Research of Fisheries and Oceans Canada, the Genomics Research and Development Initiative of Canada, as well as the Natural Sciences and Engineering Research Council of Canada, and was supported by the Atlantic Salmon Federation. M.F.S. was supported by the Research Council of Norway (grant no. 310599).

Publisher Copyright:
© 2022. B.M.P., P.B., S.S.I., I.A.F., M.F.S., I.R.B. and Fisheries and Oceans, Canada,. Open Access under Creative Commons by Attribution Licence. All Rights Reserved.

ASJC Scopus Subject Areas

Aquatic Science
Water Science and Technology
Management, Monitoring, Policy and Law

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10.3354/aei00429

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@article{2edcef5a417e47a9be8bbb3de78364ad,

title = "Morphological consequences of hybridization between farm and wild Atlantic salmon Salmo salar under both wild and experimental conditions",

abstract = "The escape of Atlantic salmon Salmo salar from aquaculture has been identified as a significant threat to the persistence and stability of wild salmon populations. Yet the magnitude of phenotypic impacts due to hybridization remains largely unresolved. We evaluated the phenotypic consequences of hybridization using geometric morphometrics both under natural conditions in the wild and in the laboratory using common garden experiments. Juvenile Atlantic salmon field-collected in 2015 and 2016 from 18 southern Newfoundland rivers were classified as pure wild, pure farm, or F1 hybrids using genetic assignment. Overall size and shape differences between wild and farm, and wild and F1 hybrid individuals were small, largely size related, and present between pure farm and other crosses. Laboratory-reared pure wild, pure farm, and F1 hybrid salmon were grown in tank and semi-natural conditions. Wild fish were significantly larger than both farm and hybrid salmon at first feeding; these size differences remained at 80 d post first feeding under semi-natural conditions, but all crosses were the same size in tank conditions, and there were no differences between pure farm and hybrid individuals under either condition. Significant shape differences were present among all pairwise comparisons under tank conditions, and in semi-natural conditions, pure wild individuals differed significantly from pure farm and hybrid individuals. Our results suggest phenotypic differences observed under laboratory conditions between wild and farmxwild hybrid individuals may not be appreciable in the wild, and that significant genetic changes may occur in wild populations experiencing hybridization in the absence of obvious large phenotypic changes.",

author = "Perriman, {B. M.} and P. Bentzen and Wringe, {B. F.} and S. Duffy and Islam, {S. S.} and Fleming, {I. A.} and Solberg, {M. F.} and Bradbury, {I. R.}",

note = "Funding Information: The authors thank the Newfoundland DFO Salmonids section for salmon tissue sampling and Nick Jeffery and Ryan Stanley for help with analyses. The authors also thank Beth Watson for helpful advice and D. Saunders, K. B⊘e, and C. Conway for assistance with tagging and rearing of fish in the common garden experiments. Acquisition of aquaculture salmon baseline samples was facilitated by G. Perry, C. Hendry, DFO Aquaculture section Newfoundland Region, and by industry partners Cooke Aquaculture and Northern Harvest Sea Farms. We also thank the staff of the Aquatic Biotechnology Laboratory of the Bedford Institute of Oceanography for their work in the SNP genotyping. This study was funded through the Program for Aquaculture Regulatory Research of Fisheries and Oceans Canada, the Genomics Research and Development Initiative of Canada, as well as the Natural Sciences and Engineering Research Council of Canada, and was supported by the Atlantic Salmon Federation. M.F.S. was supported by the Research Council of Norway (grant no. 310599). Funding Information: DFO Salmonids section for salmon tissue sampling and Nick Jeffery and Ryan Stanley for help with analyses. The authors also thank Beth Watson for helpful advice and D. Saunders, K. B{\o}e, and C. Conway for assistance with tagging and rearing of fish in the common garden experiments. Acquisition of aquaculture salmon baseline samples was facilitated by G. Perry, C. Hendry, DFO Aquaculture section Newfoundland Region, and by industry partners Cooke Aquaculture and Northern Harvest Sea Farms. We also thank the staff of the Aquatic Biotechnology Laboratory of the Bedford Institute of Oceanography for their work in the SNP genotyping. This study was funded through the Program for Aquaculture Regulatory Research of Fisheries and Oceans Canada, the Genomics Research and Development Initiative of Canada, as well as the Natural Sciences and Engineering Research Council of Canada, and was supported by the Atlantic Salmon Federation. M.F.S. was supported by the Research Council of Norway (grant no. 310599). Publisher Copyright: {\textcopyright} 2022. B.M.P., P.B., S.S.I., I.A.F., M.F.S., I.R.B. and Fisheries and Oceans, Canada,. Open Access under Creative Commons by Attribution Licence. All Rights Reserved.",

year = "2022",

doi = "10.3354/aei00429",

language = "English",

volume = "14",

pages = "85--96",

journal = "Aquaculture Environment Interactions",

issn = "1869-215X",

publisher = "Inter-Research",

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TY - JOUR

T1 - Morphological consequences of hybridization between farm and wild Atlantic salmon Salmo salar under both wild and experimental conditions

AU - Perriman, B. M.

AU - Bentzen, P.

AU - Wringe, B. F.

AU - Duffy, S.

AU - Islam, S. S.

AU - Fleming, I. A.

AU - Solberg, M. F.

AU - Bradbury, I. R.

N1 - Funding Information: The authors thank the Newfoundland DFO Salmonids section for salmon tissue sampling and Nick Jeffery and Ryan Stanley for help with analyses. The authors also thank Beth Watson for helpful advice and D. Saunders, K. B⊘e, and C. Conway for assistance with tagging and rearing of fish in the common garden experiments. Acquisition of aquaculture salmon baseline samples was facilitated by G. Perry, C. Hendry, DFO Aquaculture section Newfoundland Region, and by industry partners Cooke Aquaculture and Northern Harvest Sea Farms. We also thank the staff of the Aquatic Biotechnology Laboratory of the Bedford Institute of Oceanography for their work in the SNP genotyping. This study was funded through the Program for Aquaculture Regulatory Research of Fisheries and Oceans Canada, the Genomics Research and Development Initiative of Canada, as well as the Natural Sciences and Engineering Research Council of Canada, and was supported by the Atlantic Salmon Federation. M.F.S. was supported by the Research Council of Norway (grant no. 310599). Funding Information: DFO Salmonids section for salmon tissue sampling and Nick Jeffery and Ryan Stanley for help with analyses. The authors also thank Beth Watson for helpful advice and D. Saunders, K. Bøe, and C. Conway for assistance with tagging and rearing of fish in the common garden experiments. Acquisition of aquaculture salmon baseline samples was facilitated by G. Perry, C. Hendry, DFO Aquaculture section Newfoundland Region, and by industry partners Cooke Aquaculture and Northern Harvest Sea Farms. We also thank the staff of the Aquatic Biotechnology Laboratory of the Bedford Institute of Oceanography for their work in the SNP genotyping. This study was funded through the Program for Aquaculture Regulatory Research of Fisheries and Oceans Canada, the Genomics Research and Development Initiative of Canada, as well as the Natural Sciences and Engineering Research Council of Canada, and was supported by the Atlantic Salmon Federation. M.F.S. was supported by the Research Council of Norway (grant no. 310599). Publisher Copyright: © 2022. B.M.P., P.B., S.S.I., I.A.F., M.F.S., I.R.B. and Fisheries and Oceans, Canada,. Open Access under Creative Commons by Attribution Licence. All Rights Reserved.

PY - 2022

Y1 - 2022

N2 - The escape of Atlantic salmon Salmo salar from aquaculture has been identified as a significant threat to the persistence and stability of wild salmon populations. Yet the magnitude of phenotypic impacts due to hybridization remains largely unresolved. We evaluated the phenotypic consequences of hybridization using geometric morphometrics both under natural conditions in the wild and in the laboratory using common garden experiments. Juvenile Atlantic salmon field-collected in 2015 and 2016 from 18 southern Newfoundland rivers were classified as pure wild, pure farm, or F1 hybrids using genetic assignment. Overall size and shape differences between wild and farm, and wild and F1 hybrid individuals were small, largely size related, and present between pure farm and other crosses. Laboratory-reared pure wild, pure farm, and F1 hybrid salmon were grown in tank and semi-natural conditions. Wild fish were significantly larger than both farm and hybrid salmon at first feeding; these size differences remained at 80 d post first feeding under semi-natural conditions, but all crosses were the same size in tank conditions, and there were no differences between pure farm and hybrid individuals under either condition. Significant shape differences were present among all pairwise comparisons under tank conditions, and in semi-natural conditions, pure wild individuals differed significantly from pure farm and hybrid individuals. Our results suggest phenotypic differences observed under laboratory conditions between wild and farmxwild hybrid individuals may not be appreciable in the wild, and that significant genetic changes may occur in wild populations experiencing hybridization in the absence of obvious large phenotypic changes.

AB - The escape of Atlantic salmon Salmo salar from aquaculture has been identified as a significant threat to the persistence and stability of wild salmon populations. Yet the magnitude of phenotypic impacts due to hybridization remains largely unresolved. We evaluated the phenotypic consequences of hybridization using geometric morphometrics both under natural conditions in the wild and in the laboratory using common garden experiments. Juvenile Atlantic salmon field-collected in 2015 and 2016 from 18 southern Newfoundland rivers were classified as pure wild, pure farm, or F1 hybrids using genetic assignment. Overall size and shape differences between wild and farm, and wild and F1 hybrid individuals were small, largely size related, and present between pure farm and other crosses. Laboratory-reared pure wild, pure farm, and F1 hybrid salmon were grown in tank and semi-natural conditions. Wild fish were significantly larger than both farm and hybrid salmon at first feeding; these size differences remained at 80 d post first feeding under semi-natural conditions, but all crosses were the same size in tank conditions, and there were no differences between pure farm and hybrid individuals under either condition. Significant shape differences were present among all pairwise comparisons under tank conditions, and in semi-natural conditions, pure wild individuals differed significantly from pure farm and hybrid individuals. Our results suggest phenotypic differences observed under laboratory conditions between wild and farmxwild hybrid individuals may not be appreciable in the wild, and that significant genetic changes may occur in wild populations experiencing hybridization in the absence of obvious large phenotypic changes.

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ER -

Morphological consequences of hybridization between farm and wild Atlantic salmon Salmo salar under both wild and experimental conditions

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