TY - JOUR
T1 - Population responses to harvesting in fluctuating environments
AU - Lee, Aline Magdalena
AU - Jarillo, Javier
AU - Peeters, Bart
AU - Hansen, Brage Bremset
AU - Cao-García, Francisco J.
AU - Sæther, Bernt Erik
AU - Engen, Steinar
N1 - Funding Information:
Acknowledgements. This work was supported by the Re - search Council of Norway (RCN; KLIMAFORSK project 244647 and SFF-III 223257/F50) and the Norwegian University of Science and Technology (NTNU). B.B.H. was additionally funded by RCN project 276080. F.J.C.-G. was additionally funded by European Regional Development Fund (ERDF) and by the Spanish Ministry of Economy and Competitiveness through projects FIS2015-67765-R and RTI2018-095802-B-I00, and by European Union’s Horizon 2020 through grant agreement No. 817578 TRIATLAS.
Funding Information:
This work was supported by the Research Council of Norway (RCN; KLIMAFORSK project 244647 and SFF-III 223257/F50) and the Norwegian University of Science and Technology (NTNU). B.B.H. was addi-tionally funded by RCN project 276080. F.J.C.-G. was addi-tionally funded by European Regional Development Fund (ERDF) and by the Spanish Ministry of Economy and Com-petitiveness through projects FIS2015-67765-R and RTI2018-095802-B-I00, and by European Union?s Horizon 2020 through grant agreement No. 817578 TRIATLAS.
Publisher Copyright:
© The authors 2022.
PY - 2022
Y1 - 2022
N2 - Achieving sustainable harvesting of natural populations depends on our ability to pre-dict population responses to the combined effects of harvesting and environmental fluctuations while accounting for other internal and external factors that influence population dynamics in time and space. Here, we review recent research showing how spatial patterns and interspecific interactions can influence population responses to harvesting in fluctuating environments. We highlight several pathways through which harvesting can, often inadvertently, influence the dynamics and resilience to environmental fluctuations of both harvested and surrounding non-harvested populations and species. For instance, spatial models have shown that harvesting is expected to influence the spatial synchrony of population fluctuations, both of the harvested species and its competitors, predators and prey, with implications for population extinction risk. Dispersal and interspecific interactions can cause responses to harvesting in areas and species that are not themselves harvested. Harvesting that selectively targets certain groups of individuals, either intentionally or through for example spatially biased harvesting, can amplify environmentally induced population fluctuations by biasing the population structure towards individuals that are more sensitive to environmental variation. On the other hand, harvesting can in some cases buffer populations against the density-dependent effects of harsh climatic conditions, which are probably more common than previously acknowledged. Recent advances in modeling are providing new predictions that are highly re-levant under global warming and now need to be tested empirically. We discuss how knowledge of these pathways can be used to increase the sustainability of harvesting.
AB - Achieving sustainable harvesting of natural populations depends on our ability to pre-dict population responses to the combined effects of harvesting and environmental fluctuations while accounting for other internal and external factors that influence population dynamics in time and space. Here, we review recent research showing how spatial patterns and interspecific interactions can influence population responses to harvesting in fluctuating environments. We highlight several pathways through which harvesting can, often inadvertently, influence the dynamics and resilience to environmental fluctuations of both harvested and surrounding non-harvested populations and species. For instance, spatial models have shown that harvesting is expected to influence the spatial synchrony of population fluctuations, both of the harvested species and its competitors, predators and prey, with implications for population extinction risk. Dispersal and interspecific interactions can cause responses to harvesting in areas and species that are not themselves harvested. Harvesting that selectively targets certain groups of individuals, either intentionally or through for example spatially biased harvesting, can amplify environmentally induced population fluctuations by biasing the population structure towards individuals that are more sensitive to environmental variation. On the other hand, harvesting can in some cases buffer populations against the density-dependent effects of harsh climatic conditions, which are probably more common than previously acknowledged. Recent advances in modeling are providing new predictions that are highly re-levant under global warming and now need to be tested empirically. We discuss how knowledge of these pathways can be used to increase the sustainability of harvesting.
KW - Climate change
KW - Environmental stochasticity
KW - Fisheries
KW - Hunting
KW - Multi-species systems
KW - Population structure
UR - http://www.scopus.com/inward/record.url?scp=85125711822&partnerID=8YFLogxK
U2 - 10.3354/cr01656
DO - 10.3354/cr01656
M3 - Review article
AN - SCOPUS:85125711822
SN - 1864-7782
VL - 86
SP - 79
EP - 91
JO - Aquatic Biology
JF - Aquatic Biology
ER -