Copepod grazing influences diatom aggregation and particle dynamics

In marine ecosystems, carbon export is driven by particle flux which is modulated by aggregation, remineralization, and grazing processes. Zooplankton contribute to the sinking flux through the egestion of fast sinking fecal pellets but may also attenuate the flux by tearing apart phytoplankton aggr...

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Bibliographic Details
Published in:Frontiers in Marine Science
Main Authors: Toullec, Jordan, Vincent, Dorothée, Frohn, Laura, Miner, Philippe, Le Goff, Manon, Devesa, Jérémy, Moriceau, Brivaëla
Format: Article in Journal/Newspaper
Language:English
Published: Frontiers Media SA 2019
Subjects:
Biology and Life Sciences
Earth and Environmental Sciences
Ocean Engineering
Water Science and Technology
Aquatic Science
Global and Planetary Change
Oceanography
particle dynamics
sinking velocity
copepod
grazing experiment
diatom aggregate
Calanus hyperboreus
Copepods
Online Access:https://biblio.ugent.be/publication/01HF6ZWPHRJA0PD1KVGF4S7EEB
http://hdl.handle.net/1854/LU-01HF6ZWPHRJA0PD1KVGF4S7EEB
https://doi.org/10.3389/fmars.2019.00751
https://biblio.ugent.be/publication/01HF6ZWPHRJA0PD1KVGF4S7EEB/file/01HF706ENWTEM2YD1PYW5Q4KFQ
Description
Summary:In marine ecosystems, carbon export is driven by particle flux which is modulated by aggregation, remineralization, and grazing processes. Zooplankton contribute to the sinking flux through the egestion of fast sinking fecal pellets but may also attenuate the flux by tearing apart phytoplankton aggregates into small pieces through swimming activity or direct ingestion. Freely suspended cells, artificial monospecific aggregates from two different diatom species (Chaetoceros neogracile and Skeletonema merinol) and natural aggregates of Melosira sp. were independently incubated with five different copepod species (Acadia clausi, Temora longicomis, Calanus helgolandicus, Euterpina acutifrons, and Calanus hyperboreus). During the grazing experiments initiated with free diatoms, E. acutifrons feeding activity evidenced by ingestion rates of 157 +/- 155 ng Chl a ind(-1) d(-1), induced a significant increase of S. marinoi aggregation. Transparent exopolymeric particles (TEP) production was only slightly boosted by the presence of grazers and turbulences created by swimming may be the main trigger of the aggregation processes. All copepods studied were able to graze on aggregates and quantitative estimates led to chlorophyll a ingestion rates (expressed in Chla a equivalent, i.e., the sum of chlorophyll a and pheopigments in their guts) ranging from 4 to 23 ng Chl a(eq) ind(-1) d(-1). The relation between equivalent spherical diameters (ESDs) and sinking velocities of the aggregates did not significantly change after grazing, suggesting that copepod grazing did not affect aggregate density as also shown by Si:C and C:N ratios. Three main trends in particle dynamics could be identified and further linked to the copepod feeding behavior and the size ratio between prey and predators: (1) Fragmentation of S. marinoi aggregates by the cruise feeder T. longicomis and of Melosira sp. aggregates by C. hyperboreus at prey to predator size ratios larger than 15; (2) no change of particle dynamics in the presence of the detritic ...

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