Cooke, S. J., Hinch, S. G., Farrell, A. P., Patterson, D. A., Miller-Saunders, K., Welch, D. W., Donaldson, M. R., Hanson, K. C., Crossin, G. T., Mathes, M. T., Lotto, A. G., Hruska, K. A., Olsson, I. C., Wagner, G. N., Thomson, R., Hourston, R., English, K. K., Larsson, S., Shrimpton, J. M., ... Cooperman (2008). Developing a mechanistic understanding of fish migrations by linking telemetry with physiology, behavior, genomics and experimental biology: An interdisciplinary case study on adul Fraser River sockeye salmon. Fisheries, 33(7), 321-339. https://doi.org/10.1577/1548-8446-33.7.321
Developing a mechanistic understanding of fish migrations by linking telemetry with physiology, behavior, genomics and experimental biology: An interdisciplinary case study on adul Fraser River sockeye salmon. / Cooke, Steven J.; Hinch, S. G.; Farrell, A. P. et al.
In:
Fisheries, Vol. 33, No. 7, 07.2008, p. 321-339.
Research output: Contribution to journal › Review article › peer-review
Cooke, SJ, Hinch, SG, Farrell, AP, Patterson, DA, Miller-Saunders, K, Welch, DW, Donaldson, MR, Hanson, KC, Crossin, GT, Mathes, MT, Lotto, AG, Hruska, KA, Olsson, IC, Wagner, GN, Thomson, R, Hourston, R, English, KK, Larsson, S, Shrimpton, JM, Van Der Kraak, G & Cooperman 2008, 'Developing a mechanistic understanding of fish migrations by linking telemetry with physiology, behavior, genomics and experimental biology: An interdisciplinary case study on adul Fraser River sockeye salmon', Fisheries, vol. 33, no. 7, pp. 321-339. https://doi.org/10.1577/1548-8446-33.7.321
Cooke SJ, Hinch SG, Farrell AP, Patterson DA, Miller-Saunders K, Welch DW et al. Developing a mechanistic understanding of fish migrations by linking telemetry with physiology, behavior, genomics and experimental biology: An interdisciplinary case study on adul Fraser River sockeye salmon. Fisheries. 2008 Jul;33(7):321-339. doi: 10.1577/1548-8446-33.7.321
Cooke, Steven J. ; Hinch, S. G. ; Farrell, A. P. et al. / Developing a mechanistic understanding of fish migrations by linking telemetry with physiology, behavior, genomics and experimental biology : An interdisciplinary case study on adul Fraser River sockeye salmon. In: Fisheries. 2008 ; Vol. 33, No. 7. pp. 321-339.
@article{1d995d57a47d442ba1aa8b13073ad819,
title = "Developing a mechanistic understanding of fish migrations by linking telemetry with physiology, behavior, genomics and experimental biology: An interdisciplinary case study on adul Fraser River sockeye salmon",
abstract = "Fish migration represents one of the most complex and intriguing biological phenomena in the animal kingdom. How do fish migrate such vast distances? What are the costs and benefits of migration? Some of these fundamental questions have been addressed through the use of telemetry. However, telemetry alone has not and will not yield a complete understanding of the migration biology of fi sh or provide solutions to problems such as identifying physical barriers to migration or understanding potential impacts of climate change. Telemetry can be coupled with other tools and techniques to yield new insights into animal biology. Using Fraser River sockeye salmon (Oncorhynchus nerka) as a model, we summarize the advances that we have made in understanding salmonid migration biology through the integration of disciplines (i.e., interdisciplinary research) including physiology, behavior, functional genomics, and experimental biology. We also discuss opportunities for using large-scale telemetry arrays and taking a more experimental approach to studies of fish migration that use telemetry (i.e., intervention studies involving endocrine implants, simulated migration studies) rather than simply focusing on descriptive or correlational techniques. Only through integrative and interdisciplinary research will it be possible to understand the mechanistic basis of fi sh migrations and to predict and possibly mitigate the consequences of anthropogenic impacts. Telemetry is a tool that has the potential to integrate research across disciplines and between the lab and the field to advance the science of fish migration biology. The techniques that we have applied to the study of Pacifi c salmon are equally relevant to other fi sh taxa in both marine and freshwater systems as well as migratory animals beyond ichthyofauna. The interdisciplinary approach used here was essential to address a pressing and complex conservation problem association with sockeye salmon migration.",
author = "Cooke, {Steven J.} and Hinch, {S. G.} and Farrell, {A. P.} and Patterson, {D. A.} and K. Miller-Saunders and Welch, {D. W.} and Donaldson, {M. R.} and Hanson, {K. C.} and Crossin, {G. T.} and Mathes, {M. T.} and Lotto, {A. G.} and Hruska, {K. A.} and Olsson, {I. C.} and Wagner, {G. N.} and R. Thomson and R. Hourston and English, {K. K.} and S. Larsson and Shrimpton, {J. M.} and {Van Der Kraak}, G. and Cooperman",
year = "2008",
month = jul,
doi = "10.1577/1548-8446-33.7.321",
language = "English",
volume = "33",
pages = "321--339",
journal = "Fisheries",
issn = "0363-2415",
publisher = "American Fisheries Society",
number = "7",
}
TY - JOUR
T1 - Developing a mechanistic understanding of fish migrations by linking telemetry with physiology, behavior, genomics and experimental biology
T2 - An interdisciplinary case study on adul Fraser River sockeye salmon
AU - Cooke, Steven J.
AU - Hinch, S. G.
AU - Farrell, A. P.
AU - Patterson, D. A.
AU - Miller-Saunders, K.
AU - Welch, D. W.
AU - Donaldson, M. R.
AU - Hanson, K. C.
AU - Crossin, G. T.
AU - Mathes, M. T.
AU - Lotto, A. G.
AU - Hruska, K. A.
AU - Olsson, I. C.
AU - Wagner, G. N.
AU - Thomson, R.
AU - Hourston, R.
AU - English, K. K.
AU - Larsson, S.
AU - Shrimpton, J. M.
AU - Van Der Kraak, G.
AU - Cooperman,
PY - 2008/7
Y1 - 2008/7
N2 - Fish migration represents one of the most complex and intriguing biological phenomena in the animal kingdom. How do fish migrate such vast distances? What are the costs and benefits of migration? Some of these fundamental questions have been addressed through the use of telemetry. However, telemetry alone has not and will not yield a complete understanding of the migration biology of fi sh or provide solutions to problems such as identifying physical barriers to migration or understanding potential impacts of climate change. Telemetry can be coupled with other tools and techniques to yield new insights into animal biology. Using Fraser River sockeye salmon (Oncorhynchus nerka) as a model, we summarize the advances that we have made in understanding salmonid migration biology through the integration of disciplines (i.e., interdisciplinary research) including physiology, behavior, functional genomics, and experimental biology. We also discuss opportunities for using large-scale telemetry arrays and taking a more experimental approach to studies of fish migration that use telemetry (i.e., intervention studies involving endocrine implants, simulated migration studies) rather than simply focusing on descriptive or correlational techniques. Only through integrative and interdisciplinary research will it be possible to understand the mechanistic basis of fi sh migrations and to predict and possibly mitigate the consequences of anthropogenic impacts. Telemetry is a tool that has the potential to integrate research across disciplines and between the lab and the field to advance the science of fish migration biology. The techniques that we have applied to the study of Pacifi c salmon are equally relevant to other fi sh taxa in both marine and freshwater systems as well as migratory animals beyond ichthyofauna. The interdisciplinary approach used here was essential to address a pressing and complex conservation problem association with sockeye salmon migration.
AB - Fish migration represents one of the most complex and intriguing biological phenomena in the animal kingdom. How do fish migrate such vast distances? What are the costs and benefits of migration? Some of these fundamental questions have been addressed through the use of telemetry. However, telemetry alone has not and will not yield a complete understanding of the migration biology of fi sh or provide solutions to problems such as identifying physical barriers to migration or understanding potential impacts of climate change. Telemetry can be coupled with other tools and techniques to yield new insights into animal biology. Using Fraser River sockeye salmon (Oncorhynchus nerka) as a model, we summarize the advances that we have made in understanding salmonid migration biology through the integration of disciplines (i.e., interdisciplinary research) including physiology, behavior, functional genomics, and experimental biology. We also discuss opportunities for using large-scale telemetry arrays and taking a more experimental approach to studies of fish migration that use telemetry (i.e., intervention studies involving endocrine implants, simulated migration studies) rather than simply focusing on descriptive or correlational techniques. Only through integrative and interdisciplinary research will it be possible to understand the mechanistic basis of fi sh migrations and to predict and possibly mitigate the consequences of anthropogenic impacts. Telemetry is a tool that has the potential to integrate research across disciplines and between the lab and the field to advance the science of fish migration biology. The techniques that we have applied to the study of Pacifi c salmon are equally relevant to other fi sh taxa in both marine and freshwater systems as well as migratory animals beyond ichthyofauna. The interdisciplinary approach used here was essential to address a pressing and complex conservation problem association with sockeye salmon migration.
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U2 - 10.1577/1548-8446-33.7.321
DO - 10.1577/1548-8446-33.7.321
M3 - Review article
AN - SCOPUS:53849145690
SN - 0363-2415
VL - 33
SP - 321
EP - 339
JO - Fisheries
JF - Fisheries
IS - 7
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