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Biophysical Interactions Control the Size and Abundance of Large Phytoplankton Chains at the Ushant Tidal Front
Biophysical Interactions Control the Size and Abundance of Large Phytoplankton Chains at the Ushant Tidal Front
- Source :
- PLoS ONE, PLoS ONE, Public Library of Science, 2014, 9 (2), pp.e90507. ⟨10.1371/journal.pone.0090507⟩, PLoS ONE, Vol 9, Iss 2, p e90507 (2014), PLoS ONE, 2014, 9 (2), pp.e90507. ⟨10.1371/journal.pone.0090507⟩, Plos One (1932-6203) (Public Library Science), 2014-02, Vol. 9, N. 2, P.
- Publication Year :
- 2014
- Publisher :
- Public Library of Science, 2014.
-
Abstract
- International audience; Phytoplankton blooms are usually dominated by chain-forming diatom species that can alter food pathways from primary producers to predators by reducing the interactions between intermediate trophic levels. The food-web modifications are determined by the length of the chains; however, the estimation is biased because traditional sampling strategies damage the chains and, therefore, change the phytoplankton size structure. Sedimentological studies around oceanic fronts have shown high concentrations of giant diatom mats (.1 cm in length), suggesting that the size of diatom chains is underestimated in the pelagic realm. Here, we investigate the variability in size and abundance of phytoplankton chains at the Ushant tidal front (NW France) using the Video Fluorescence Analyzer (VFA), a novel and non-invasive system. CTD and Scanfish profiling characterized a strong temperature and chlorophyll front, separating mixed coastal waters from the oceanic-stratified domain. In order to elucidate spring-neap variations in the front, vertical microstructure profiler was used to estimate the turbulence and vertical nitrate flux. Key findings were: (1) the VFA system recorded large diatom chains up to 10.7 mm in length; (2) chains were mainly distributed in the frontal region, with maximum values above the pycnocline in coincidence with the maximum chlorophyll; (3) the diapycnal fluxes of nitrate enabled the maintenance of the bloom in the frontal area throughout the spring-neap tidal cycle; (4) from spring to neap tide the chains length was significantly reduced; (5) during neap tide, the less intense vertical diffusion of nutrients, as well as the lower turbulence around the chains, intensified nutrient-depleted conditions and, thus, very large chains became disadvantageous. To explain this pattern, we suggest that size plasticity is an important ecological trait driving phytoplankton species competition. Although this plasticity behavior is well known from experiments in the laboratory, it has never been reported from observations in the field.
- Subjects :
- Chlorophyll
lcsh:Medicine
Marine and Aquatic Sciences
Plant Science
Oceanography
Food chain
Biomass
lcsh:Science
Trophic level
[SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere
Multidisciplinary
Primary producers
biology
Ecology
Geography
[SDV.BA]Life Sciences [q-bio]/Animal biology
Marine Ecology
Temperature
Marine Technology
Plants
Bays
Phycology
France
Seasons
Bloom
Coastal Ecology
Research Article
Pycnocline
Food Chain
Algae
Marine Biology
Ecosystems
Fluorescence
Marine Monitoring
Phytoplankton
Water Movements
14. Life underwater
Biology
Ecosystem
Diatoms
Population Density
Nitrates
lcsh:R
Videotape Recording
Pelagic zone
biology.organism_classification
Diatom
13. Climate action
Spain
Earth Sciences
lcsh:Q
Subjects
Details
- Language :
- English
- ISSN :
- 19326203
- Volume :
- 9
- Issue :
- 2
- Database :
- OpenAIRE
- Journal :
- PLoS ONE
- Accession number :
- edsair.doi.dedup.....69a08b9fc1508c3bc5a26dfcb3353c5d
- Full Text :
- https://doi.org/10.1371/journal.pone.0090507⟩