Using Food Webs and Metabolic Theory to Monitor, Model, and Manage Atlantic Salmon—A Keystone Species Under Threat

Guy Woodward; Olivia Morris; José Barquín; Andrea Belgrano; Colin Bull; Elvira de Eyto; Nikolai Friberg; Guðni Guðbergsson; Katrin Layer-Dobra; Rasmus B. Lauridsen; Hannah M. Lewis; Philip McGinnity; Samraat Pawar; James Rosindell; Eoin J. O’Gorman

doi:10.3389/fevo.2021.675261

Using Food Webs and Metabolic Theory to Monitor, Model, and Manage Atlantic Salmon—A Keystone Species Under Threat

Guy Woodward
, Olivia Morris
, José Barquín
, Andrea Belgrano
, Colin Bull
, Elvira de Eyto
, Nikolai Friberg
, Guðni Guðbergsson
, Katrin Layer-Dobra
, Rasmus B. Lauridsen
, Hannah M. Lewis
, Philip McGinnity
, Samraat Pawar
, James Rosindell
, Eoin J. O’Gorman

School of Biological, Earth and Environmental Sciences

Research output: Contribution to journal › Article › peer-review

Abstract

Populations of Atlantic salmon are crashing across most of its natural range: understanding the underlying causes and predicting these collapses in time to intervene effectively are urgent ecological and socioeconomic priorities. Current management techniques rely on phenomenological analyses of demographic population time-series and thus lack a mechanistic understanding of how and why populations may be declining. New multidisciplinary approaches are thus needed to capitalize on the long-term, large-scale population data that are currently scattered across various repositories in multiple countries, as well as marshaling additional data to understand the constraints on the life cycle and how salmon operate within the wider food web. Here, we explore how we might combine data and theory to develop the mechanistic models that we need to predict and manage responses to future change. Although we focus on Atlantic salmon—given the huge data resources that already exist for this species—the general principles developed here could be applied and extended to many other species and ecosystems.

Original language	English
Article number	675261
Journal	Frontiers in Ecology and Evolution
Volume	9
DOIs	https://doi.org/10.3389/fevo.2021.675261
Publication status	Published - 17 Dec 2021

Keywords

Atlantic salmon (Salmo salar)
ecosystem-based management (EBM)
life-stage models
marine and freshwater fisheries
matrix projection models
metabolic theory of ecology (MTE)
size structure

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.3389/fevo.2021.675261

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Woodward, G., Morris, O., Barquín, J., Belgrano, A., Bull, C., de Eyto, E., Friberg, N., Guðbergsson, G., Layer-Dobra, K., Lauridsen, R. B., Lewis, H. M., McGinnity, P., Pawar, S., Rosindell, J., & O’Gorman, E. J. (2021). Using Food Webs and Metabolic Theory to Monitor, Model, and Manage Atlantic Salmon—A Keystone Species Under Threat. Frontiers in Ecology and Evolution, 9, Article 675261. https://doi.org/10.3389/fevo.2021.675261

@article{3bedf14d61ad4d44be7d46bdb929f148,

title = "Using Food Webs and Metabolic Theory to Monitor, Model, and Manage Atlantic Salmon—A Keystone Species Under Threat",

abstract = "Populations of Atlantic salmon are crashing across most of its natural range: understanding the underlying causes and predicting these collapses in time to intervene effectively are urgent ecological and socioeconomic priorities. Current management techniques rely on phenomenological analyses of demographic population time-series and thus lack a mechanistic understanding of how and why populations may be declining. New multidisciplinary approaches are thus needed to capitalize on the long-term, large-scale population data that are currently scattered across various repositories in multiple countries, as well as marshaling additional data to understand the constraints on the life cycle and how salmon operate within the wider food web. Here, we explore how we might combine data and theory to develop the mechanistic models that we need to predict and manage responses to future change. Although we focus on Atlantic salmon—given the huge data resources that already exist for this species—the general principles developed here could be applied and extended to many other species and ecosystems.",

keywords = "Atlantic salmon (Salmo salar), ecosystem-based management (EBM), life-stage models, marine and freshwater fisheries, matrix projection models, metabolic theory of ecology (MTE), size structure",

author = "Guy Woodward and Olivia Morris and Jos{\'e} Barqu{\'i}n and Andrea Belgrano and Colin Bull and \{de Eyto\}, Elvira and Nikolai Friberg and Gu{\dh}ni Gu{\dh}bergsson and Katrin Layer-Dobra and Lauridsen, \{Rasmus B.\} and Lewis, \{Hannah M.\} and Philip McGinnity and Samraat Pawar and James Rosindell and O{\textquoteright}Gorman, \{Eoin J.\}",

note = "Publisher Copyright: Copyright {\textcopyright} 2021 Woodward, Morris, Barqu{\'i}n, Belgrano, Bull, de Eyto, Friberg, Gu{\dh}bergsson, Layer-Dobra, Lauridsen, Lewis, McGinnity, Pawar, Rosindell and O{\textquoteright}Gorman.",

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Woodward, G, Morris, O, Barquín, J, Belgrano, A, Bull, C, de Eyto, E, Friberg, N, Guðbergsson, G, Layer-Dobra, K, Lauridsen, RB, Lewis, HM, McGinnity, P, Pawar, S, Rosindell, J & O’Gorman, EJ 2021, 'Using Food Webs and Metabolic Theory to Monitor, Model, and Manage Atlantic Salmon—A Keystone Species Under Threat', Frontiers in Ecology and Evolution, vol. 9, 675261. https://doi.org/10.3389/fevo.2021.675261

TY - JOUR

T1 - Using Food Webs and Metabolic Theory to Monitor, Model, and Manage Atlantic Salmon—A Keystone Species Under Threat

AU - Woodward, Guy

AU - Morris, Olivia

AU - Barquín, José

AU - Belgrano, Andrea

AU - Bull, Colin

AU - de Eyto, Elvira

AU - Friberg, Nikolai

AU - Guðbergsson, Guðni

AU - Layer-Dobra, Katrin

AU - Lauridsen, Rasmus B.

AU - Lewis, Hannah M.

AU - McGinnity, Philip

AU - Pawar, Samraat

AU - Rosindell, James

AU - O’Gorman, Eoin J.

PY - 2021/12/17

Y1 - 2021/12/17

N2 - Populations of Atlantic salmon are crashing across most of its natural range: understanding the underlying causes and predicting these collapses in time to intervene effectively are urgent ecological and socioeconomic priorities. Current management techniques rely on phenomenological analyses of demographic population time-series and thus lack a mechanistic understanding of how and why populations may be declining. New multidisciplinary approaches are thus needed to capitalize on the long-term, large-scale population data that are currently scattered across various repositories in multiple countries, as well as marshaling additional data to understand the constraints on the life cycle and how salmon operate within the wider food web. Here, we explore how we might combine data and theory to develop the mechanistic models that we need to predict and manage responses to future change. Although we focus on Atlantic salmon—given the huge data resources that already exist for this species—the general principles developed here could be applied and extended to many other species and ecosystems.

AB - Populations of Atlantic salmon are crashing across most of its natural range: understanding the underlying causes and predicting these collapses in time to intervene effectively are urgent ecological and socioeconomic priorities. Current management techniques rely on phenomenological analyses of demographic population time-series and thus lack a mechanistic understanding of how and why populations may be declining. New multidisciplinary approaches are thus needed to capitalize on the long-term, large-scale population data that are currently scattered across various repositories in multiple countries, as well as marshaling additional data to understand the constraints on the life cycle and how salmon operate within the wider food web. Here, we explore how we might combine data and theory to develop the mechanistic models that we need to predict and manage responses to future change. Although we focus on Atlantic salmon—given the huge data resources that already exist for this species—the general principles developed here could be applied and extended to many other species and ecosystems.

KW - Atlantic salmon (Salmo salar)

KW - ecosystem-based management (EBM)

KW - life-stage models

KW - marine and freshwater fisheries

KW - matrix projection models

KW - metabolic theory of ecology (MTE)

KW - size structure

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DO - 10.3389/fevo.2021.675261

M3 - Article

AN - SCOPUS:85122158286

SN - 2296-701X

VL - 9

JO - Frontiers in Ecology and Evolution

JF - Frontiers in Ecology and Evolution

M1 - 675261

ER -

Using Food Webs and Metabolic Theory to Monitor, Model, and Manage Atlantic Salmon—A Keystone Species Under Threat

Abstract

Keywords

UN SDGs

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