Climate change and control of the southeastern Bering Sea pelagic ecosystem

We propose a new hypothesis, the Oscillating Control Hypothesis (OCH), which predicts that pelagic ecosystem function in the southeastern Bering Sea will alternate between primarily bottom-up control in cold regimes and primarily top-down control in warm regimes. The timing of spring primary product...

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Published in:Deep Sea Research Part II: Topical Studies in Oceanography
Main Authors: Hunt, GL, Stabeno, P, Walters, G, Sinclair, E, Brodeur, RD, Napp, JM, Bond, NA
Format: Article in Journal/Newspaper
Language:English
Published: eScholarship, University of California 2002
Subjects:
Bering Sea
Pacific
Theragra chalcogramma
Callorhinus ursinus
Online Access:http://www.escholarship.org/uc/item/1kx2g2dt
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description We propose a new hypothesis, the Oscillating Control Hypothesis (OCH), which predicts that pelagic ecosystem function in the southeastern Bering Sea will alternate between primarily bottom-up control in cold regimes and primarily top-down control in warm regimes. The timing of spring primary production is determined predominately by the timing of ice retreat. Late ice retreat (late March or later) leads to an early, ice-associated bloom in cold water (e.g., 1995, 1997, 1999), whereas no ice, or early ice retreat before mid-March, leads to an open-water bloom in May or June in warm water (e.g., 1996, 1998, 2000). Zooplankton populations are not closely coupled to the spring bloom, but are sensitive to water temperature. In years when the spring bloom occurs in cold water, low temperatures limit the production of zooplankton, the survival of larval/juvenile fish, and their recruitment into the populations of species of large piscivorous fish, such as walleye pollock (Theragra chalcogramma), Pacific cod (Gadus macrocephalus) and arrowtooth flounder (Atheresthes stomias). When continued over decadal scales, this will lead to bottom-up limitation and a decreased biomass of piscivorous fish. Alternatively, in periods when the bloom occurs in warm water, zooplankton populations should grow rapidly, providing plentiful prey for larval and juvenile fish. Abundant zooplankton will support strong recruitment of fish and will lead to abundant predatory fish that control forage fish, including, in the case of pollock, their own juveniles. Piscivorous marine birds and pinnipeds may achieve higher production of young and survival in cold regimes, when there is less competition from large piscivorous fish for coldwater forage fish such as capelin (Mallotus villosus). Piscivorous seabirds and pinnipeds also may be expected to have high productivity in periods of transition from cold regimes to warm regimes, when young of large predatory species of fish are numerous enough to provide forage. The OCH predicts that the ability of large predatory fish populations to sustain fishing pressure will vary between warm and cold regimes. The OCH points to the importance of the timing of ice retreat and water temperatures during the spring bloom for the productivity of zooplankton, and the degree and direction of coupling between zooplankton and forage fish. Forage fish (e.g., juvenile pollock, capelin, Pacific herring [Clupea pallasii]) are key prey for adult pollock and other apex predators. In the southeastern Bering Sea, important changes in the biota since the mid-1970s include a marked increase in the biomass of large piscivorous fish and a concurrent decline in the biomass of forage fish, including age-1 walleye pollock, particularly over the southern portion of the shelf. Populations of northern fur seals (Callorhinus ursinus) and seabirds such as kittiwakes (Rissa spp.) at the Pribilof Islands have declined, most probably in response to a diminished prey base. The available evidence suggests that these changes are unlikely the result of a decrease in total annual new primary production, though the possibility of reduced post-bloom production during summer remains. An ecosystem approach to management of the Bering Sea and its fisheries is of great importance if all of the ecosystem components valued by society are to thrive. Cognizance of how climate regimes may alter relationships within this ecosystem will facilitate reaching that goal.
format Article in Journal/Newspaper
author Hunt, GL
Stabeno, P
Walters, G
Sinclair, E
Brodeur, RD
Napp, JM
Bond, NA
spellingShingle Hunt, GL
Stabeno, P
Walters, G
Sinclair, E
Brodeur, RD
Napp, JM
Bond, NA
Climate change and control of the southeastern Bering Sea pelagic ecosystem
author_facet Hunt, GL
Stabeno, P
Walters, G
Sinclair, E
Brodeur, RD
Napp, JM
Bond, NA
author_sort Hunt, GL
title Climate change and control of the southeastern Bering Sea pelagic ecosystem
title_short Climate change and control of the southeastern Bering Sea pelagic ecosystem
title_full Climate change and control of the southeastern Bering Sea pelagic ecosystem
title_fullStr Climate change and control of the southeastern Bering Sea pelagic ecosystem
title_full_unstemmed Climate change and control of the southeastern Bering Sea pelagic ecosystem
title_sort climate change and control of the southeastern bering sea pelagic ecosystem
publisher eScholarship, University of California
publishDate 2002
url http://www.escholarship.org/uc/item/1kx2g2dt
op_coverage 5821 - 5853
geographic Bering Sea
Pacific
geographic_facet Bering Sea
Pacific
genre Bering Sea
Theragra chalcogramma
Callorhinus ursinus
genre_facet Bering Sea
Theragra chalcogramma
Callorhinus ursinus
op_source Hunt, GL; Stabeno, P; Walters, G; Sinclair, E; Brodeur, RD; Napp, JM; et al.(2002). Climate change and control of the southeastern Bering Sea pelagic ecosystem. Deep-Sea Research Part II: Topical Studies in Oceanography, 49(26), 5821 - 5853. doi:10.1016/S0967-0645(02)00321-1. UC Irvine: Retrieved from: http://www.escholarship.org/uc/item/1kx2g2dt
op_relation qt1kx2g2dt
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op_rights Attribution (CC BY): http://creativecommons.org/licenses/by/3.0/
op_rightsnorm CC-BY
op_doi https://doi.org/10.1016/S0967-0645(02)00321-1
container_title Deep Sea Research Part II: Topical Studies in Oceanography
container_volume 49
container_issue 26
container_start_page 5821
op_container_end_page 5853
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spelling ftcdlib:qt1kx2g2dt 2023-05-15T15:43:36+02:00 Climate change and control of the southeastern Bering Sea pelagic ecosystem Hunt, GL Stabeno, P Walters, G Sinclair, E Brodeur, RD Napp, JM Bond, NA 5821 - 5853 2002-01-01 application/pdf http://www.escholarship.org/uc/item/1kx2g2dt english eng eScholarship, University of California qt1kx2g2dt http://www.escholarship.org/uc/item/1kx2g2dt Attribution (CC BY): http://creativecommons.org/licenses/by/3.0/ CC-BY Hunt, GL; Stabeno, P; Walters, G; Sinclair, E; Brodeur, RD; Napp, JM; et al.(2002). Climate change and control of the southeastern Bering Sea pelagic ecosystem. Deep-Sea Research Part II: Topical Studies in Oceanography, 49(26), 5821 - 5853. doi:10.1016/S0967-0645(02)00321-1. UC Irvine: Retrieved from: http://www.escholarship.org/uc/item/1kx2g2dt article 2002 ftcdlib https://doi.org/10.1016/S0967-0645(02)00321-1 2017-12-22T23:51:03Z We propose a new hypothesis, the Oscillating Control Hypothesis (OCH), which predicts that pelagic ecosystem function in the southeastern Bering Sea will alternate between primarily bottom-up control in cold regimes and primarily top-down control in warm regimes. The timing of spring primary production is determined predominately by the timing of ice retreat. Late ice retreat (late March or later) leads to an early, ice-associated bloom in cold water (e.g., 1995, 1997, 1999), whereas no ice, or early ice retreat before mid-March, leads to an open-water bloom in May or June in warm water (e.g., 1996, 1998, 2000). Zooplankton populations are not closely coupled to the spring bloom, but are sensitive to water temperature. In years when the spring bloom occurs in cold water, low temperatures limit the production of zooplankton, the survival of larval/juvenile fish, and their recruitment into the populations of species of large piscivorous fish, such as walleye pollock (Theragra chalcogramma), Pacific cod (Gadus macrocephalus) and arrowtooth flounder (Atheresthes stomias). When continued over decadal scales, this will lead to bottom-up limitation and a decreased biomass of piscivorous fish. Alternatively, in periods when the bloom occurs in warm water, zooplankton populations should grow rapidly, providing plentiful prey for larval and juvenile fish. Abundant zooplankton will support strong recruitment of fish and will lead to abundant predatory fish that control forage fish, including, in the case of pollock, their own juveniles. Piscivorous marine birds and pinnipeds may achieve higher production of young and survival in cold regimes, when there is less competition from large piscivorous fish for coldwater forage fish such as capelin (Mallotus villosus). Piscivorous seabirds and pinnipeds also may be expected to have high productivity in periods of transition from cold regimes to warm regimes, when young of large predatory species of fish are numerous enough to provide forage. The OCH predicts that the ability of large predatory fish populations to sustain fishing pressure will vary between warm and cold regimes. The OCH points to the importance of the timing of ice retreat and water temperatures during the spring bloom for the productivity of zooplankton, and the degree and direction of coupling between zooplankton and forage fish. Forage fish (e.g., juvenile pollock, capelin, Pacific herring [Clupea pallasii]) are key prey for adult pollock and other apex predators. In the southeastern Bering Sea, important changes in the biota since the mid-1970s include a marked increase in the biomass of large piscivorous fish and a concurrent decline in the biomass of forage fish, including age-1 walleye pollock, particularly over the southern portion of the shelf. Populations of northern fur seals (Callorhinus ursinus) and seabirds such as kittiwakes (Rissa spp.) at the Pribilof Islands have declined, most probably in response to a diminished prey base. The available evidence suggests that these changes are unlikely the result of a decrease in total annual new primary production, though the possibility of reduced post-bloom production during summer remains. An ecosystem approach to management of the Bering Sea and its fisheries is of great importance if all of the ecosystem components valued by society are to thrive. Cognizance of how climate regimes may alter relationships within this ecosystem will facilitate reaching that goal. Article in Journal/Newspaper Bering Sea Theragra chalcogramma Callorhinus ursinus University of California: eScholarship Bering Sea Pacific Deep Sea Research Part II: Topical Studies in Oceanography 49 26 5821 5853

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