Deep zooplankton rely on small particles when particle fluxes are low

Abstract The fate of organic matter (OM) in the deep ocean remains enigmatic, with little understood regarding the flux and its utilization by deep food webs. We used compound‐specific nitrogen stable isotope ratios of source amino acids measured in particle size classes and deep zooplankton (700–15...

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Main Authors: Sonia Romero‐Romero, Cassie A. Ka'apu‐Lyons, Blaire P. Umhau, Claudia R. Benitez‐Nelson, Cecelia C. S. Hannides, Hilary G. Close, Jeffrey C. Drazen, Brian N. Popp
Format: Article
Language:English
Published: Wiley 2020-12-01
Series:Limnology and Oceanography Letters
Online Access:https://doi.org/10.1002/lol2.10163
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spelling doaj-d56564f615bb4e749594f0b01f5e779a2020-11-25T04:09:02ZengWileyLimnology and Oceanography Letters2378-22422020-12-015641041610.1002/lol2.10163Deep zooplankton rely on small particles when particle fluxes are lowSonia Romero‐Romero0Cassie A. Ka'apu‐Lyons1Blaire P. Umhau2Claudia R. Benitez‐Nelson3Cecelia C. S. Hannides4Hilary G. Close5Jeffrey C. Drazen6Brian N. Popp7Department of Oceanography University of Hawaii at Manoa Honolulu Hawaii USADepartment of Earth Sciences University of Hawaii at Manoa Honolulu Hawaii USASchool of the Earth, Ocean and Environment University of South Carolina Columbia South Carolina USASchool of the Earth, Ocean and Environment University of South Carolina Columbia South Carolina USADepartment of Earth Sciences University of Hawaii at Manoa Honolulu Hawaii USARosenstiel School of Marine and Atmospheric Science University of Miami Miami Florida USADepartment of Oceanography University of Hawaii at Manoa Honolulu Hawaii USADepartment of Earth Sciences University of Hawaii at Manoa Honolulu Hawaii USAAbstract The fate of organic matter (OM) in the deep ocean remains enigmatic, with little understood regarding the flux and its utilization by deep food webs. We used compound‐specific nitrogen stable isotope ratios of source amino acids measured in particle size classes and deep zooplankton (700–1500 m) to determine the contribution of small (0.7–53 μm) vs. large particles (> 53 μm) to their diet at four sites in the North Pacific. Our results show that small particles constitute between 9% and 98% of zooplankton diets, being the contribution higher at sites with lower flux regimes. The contribution of small particles to the diet of deep zooplankton was also higher when biomass of vertical migrators, and therefore actively transported OM, was lower. Climate‐driven changes in primary production and export are expected to shift particle fluxes to smaller size classes, and thus their importance in midwater food webs may become more widespread.https://doi.org/10.1002/lol2.10163
collection DOAJ
language English
format Article
sources DOAJ
author Sonia Romero‐Romero
Cassie A. Ka'apu‐Lyons
Blaire P. Umhau
Claudia R. Benitez‐Nelson
Cecelia C. S. Hannides
Hilary G. Close
Jeffrey C. Drazen
Brian N. Popp
spellingShingle Sonia Romero‐Romero
Cassie A. Ka'apu‐Lyons
Blaire P. Umhau
Claudia R. Benitez‐Nelson
Cecelia C. S. Hannides
Hilary G. Close
Jeffrey C. Drazen
Brian N. Popp
Deep zooplankton rely on small particles when particle fluxes are low
Limnology and Oceanography Letters
author_facet Sonia Romero‐Romero
Cassie A. Ka'apu‐Lyons
Blaire P. Umhau
Claudia R. Benitez‐Nelson
Cecelia C. S. Hannides
Hilary G. Close
Jeffrey C. Drazen
Brian N. Popp
author_sort Sonia Romero‐Romero
title Deep zooplankton rely on small particles when particle fluxes are low
title_short Deep zooplankton rely on small particles when particle fluxes are low
title_full Deep zooplankton rely on small particles when particle fluxes are low
title_fullStr Deep zooplankton rely on small particles when particle fluxes are low
title_full_unstemmed Deep zooplankton rely on small particles when particle fluxes are low
title_sort deep zooplankton rely on small particles when particle fluxes are low
publisher Wiley
series Limnology and Oceanography Letters
issn 2378-2242
publishDate 2020-12-01
description Abstract The fate of organic matter (OM) in the deep ocean remains enigmatic, with little understood regarding the flux and its utilization by deep food webs. We used compound‐specific nitrogen stable isotope ratios of source amino acids measured in particle size classes and deep zooplankton (700–1500 m) to determine the contribution of small (0.7–53 μm) vs. large particles (> 53 μm) to their diet at four sites in the North Pacific. Our results show that small particles constitute between 9% and 98% of zooplankton diets, being the contribution higher at sites with lower flux regimes. The contribution of small particles to the diet of deep zooplankton was also higher when biomass of vertical migrators, and therefore actively transported OM, was lower. Climate‐driven changes in primary production and export are expected to shift particle fluxes to smaller size classes, and thus their importance in midwater food webs may become more widespread.
url https://doi.org/10.1002/lol2.10163
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