Intermediate-size cell dominance in the phytoplankton community of an eutrophic, estuarine ecosystem (Guadalhorce River, Southern Spain)

The size–abundance spectrum (SAS) of phytoplankton is controlled by the interplay of physical and biological factors whose particular relevance varies between ecosystems. Here we report the results of a study of phytoplankton SAS in a system of eight estuarine shallow, eutrophic lagoons (Guadalhorce...

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Veröffentlicht in:	Hydrobiologia 2020-06, Vol.847 (10), p.2241-2254
Hauptverfasser:	Montes-Pérez, Jorge J., Moreno-Ostos, Enrique, Marañón, Emilio, Blanco, José María, Rodríguez, Valeriano, Rodríguez, Jaime
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Sprache:	eng
Schlagworte:	Abundance Allometry Analysis Aquatic ecosystems Biomedical and Life Sciences Brackishwater environment Cell size Cells Dominance Ecology Ecosystems Estuaries Eutrophic rivers Eutrophication Flow cytometry Freshwater & Marine Ecology Growth rate Image analysis Image processing Lagoons Life Sciences Microscopy Nannoplankton Phytoplankton Picoplankton Plankton Primary Research Paper Rivers Scaling Zoology
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container_title	Hydrobiologia
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creator	Montes-Pérez, Jorge J. Moreno-Ostos, Enrique Marañón, Emilio Blanco, José María Rodríguez, Valeriano Rodríguez, Jaime
description	The size–abundance spectrum (SAS) of phytoplankton is controlled by the interplay of physical and biological factors whose particular relevance varies between ecosystems. Here we report the results of a study of phytoplankton SAS in a system of eight estuarine shallow, eutrophic lagoons (Guadalhorce river, South Spain). SAS were obtained through a combination of flow cytometry and image analysis microscopy techniques covering six orders of magnitude from picoplankton to microplankton. Cell numbers were classified into a log2 scale of cell volume to model the log–log relation between cell abundance (cells/mL) and cell volume (μm 3 ). The resulting averaged phytoplankton SAS can be described by a log–log transformed, power model with a slope of – 0.62 (that is, there is an allometric relation between the size and abundance of cells). The distribution of biovolume (μm 3 /l) in broader size categories is characterized by the dominance of nanoplankton (67.4%), followed by microplankton (30.1%) and picoplankton (2.5%). The minor relative contribution of picoplankton to total biovolume can be explained by a combination of high and variable rates of nutrient inputs, light stress and grazing. The biomass dominance of intermediate-size cells (nanoplankton) is coherent with experimental findings describing the unimodal size scaling of growth rate, with maximum values centered in this size category.
doi_str_mv	10.1007/s10750-020-04251-9
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The minor relative contribution of picoplankton to total biovolume can be explained by a combination of high and variable rates of nutrient inputs, light stress and grazing. 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Here we report the results of a study of phytoplankton SAS in a system of eight estuarine shallow, eutrophic lagoons (Guadalhorce river, South Spain). SAS were obtained through a combination of flow cytometry and image analysis microscopy techniques covering six orders of magnitude from picoplankton to microplankton. Cell numbers were classified into a log2 scale of cell volume to model the log–log relation between cell abundance (cells/mL) and cell volume (μm 3 ). The resulting averaged phytoplankton SAS can be described by a log–log transformed, power model with a slope of – 0.62 (that is, there is an allometric relation between the size and abundance of cells). The distribution of biovolume (μm 3 /l) in broader size categories is characterized by the dominance of nanoplankton (67.4%), followed by microplankton (30.1%) and picoplankton (2.5%). 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Here we report the results of a study of phytoplankton SAS in a system of eight estuarine shallow, eutrophic lagoons (Guadalhorce river, South Spain). SAS were obtained through a combination of flow cytometry and image analysis microscopy techniques covering six orders of magnitude from picoplankton to microplankton. Cell numbers were classified into a log2 scale of cell volume to model the log–log relation between cell abundance (cells/mL) and cell volume (μm 3 ). The resulting averaged phytoplankton SAS can be described by a log–log transformed, power model with a slope of – 0.62 (that is, there is an allometric relation between the size and abundance of cells). The distribution of biovolume (μm 3 /l) in broader size categories is characterized by the dominance of nanoplankton (67.4%), followed by microplankton (30.1%) and picoplankton (2.5%). The minor relative contribution of picoplankton to total biovolume can be explained by a combination of high and variable rates of nutrient inputs, light stress and grazing. The biomass dominance of intermediate-size cells (nanoplankton) is coherent with experimental findings describing the unimodal size scaling of growth rate, with maximum values centered in this size category.</abstract><cop>Cham</cop><pub>Springer International Publishing</pub><doi>10.1007/s10750-020-04251-9</doi><tpages>14</tpages></addata></record>
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subjects	Abundance Allometry Analysis Aquatic ecosystems Biomedical and Life Sciences Brackishwater environment Cell size Cells Dominance Ecology Ecosystems Estuaries Eutrophic rivers Eutrophication Flow cytometry Freshwater & Marine Ecology Growth rate Image analysis Image processing Lagoons Life Sciences Microscopy Nannoplankton Phytoplankton Picoplankton Plankton Primary Research Paper Rivers Scaling Zoology
title	Intermediate-size cell dominance in the phytoplankton community of an eutrophic, estuarine ecosystem (Guadalhorce River, Southern Spain)
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