A turning point in the development of phytoplankton in the Vistula Lagoon (southern Baltic Sea) at the beginning of the 21st century

•The turn of 2009-10 was a breakthrough point for phytoplankton in the Vistula Lagoon.•Phytoplankton biomass changed considerably in the multiannual and seasonal aspect.•Evident trends of changes occurred in summer and autumn months from July to October.•A decreasing trend was determined for Cyanoba...

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Bibliographic Details
Published in:Oceanologia 2020-10, Vol.62 (4), p.538-555
Main Authors: Kownacka, Janina, Całkiewicz, Joanna, Kornijów, Ryszard
Format: Article
Language:English
Subjects:
Biomass
Community composition
Environmental impact
Eutrophication
Lagoons
Marine
Mineral nutrients
Multiannual changes
Nutrients
Phytoplankton
Phytoplankton community shift
Population dynamics
Rangia cuneata
Transparency
Zooplankton/phytoplankton ratio
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Summary:•The turn of 2009-10 was a breakthrough point for phytoplankton in the Vistula Lagoon.•Phytoplankton biomass changed considerably in the multiannual and seasonal aspect.•Evident trends of changes occurred in summer and autumn months from July to October.•A decreasing trend was determined for Cyanobacteria and Chlorophyta.•It could have been a result of a decrease in nutrients and entry of Rangia cuneata. Phytoplankton community structure was studied from 2002 to 2016 in the Vistula Lagoon (southern Baltic Sea) in the context of the 2010 shift in its population, as well as the reason for this shift and its environmental impact. This evident shift was indicated by Multidimensional Scaling at the Bray Curtis similarity level of 31%. Before 2010, the primary components of phytoplankton were Cyanobacteria (up to 98% of the biomass, October 2007) and Chlorophyta (40%, July 2002). After 2010, the contribution of Cyanobacteria considerably decreased, and the proportions of other phyla increased. The total phytoplankton biomass positively correlated with phosphorus, and Cyanobacteria biomass with silica. Evident changes were also observed in the seasonal dynamics of phytoplankton. Before 2010, the highest values of biomass occurred in autumn, and were related to high biomass of Cyanobacteria. Higher biomass has been recently reached in spring, during the dominance of Ochrophyta associated with Chlorophyta, Charophyta, and Cryptophyta. Generalised additive models showed a significant decreasing trend of the total phytoplankton biomass, Cyanobacteria, Chlorophyta, and flagellates, suggesting a decrease in eutrophication. This trend is concurrent with a considerable increase in the ratio of zooplankton to phytoplankton biomass since 2010. The increased ratio, however, did not result from elevated zooplankton biomass, but from the drop in phytoplankton biomass. Therefore, the most probable reason for the decrease in phytoplankton biomass was the simultaneous decrease in the concentration of all nutrients. The potential additional impact of filtration by a new alien bivalve Rangia cuneata G. B. Sowerby I, 1832 is also discussed.
ISSN:0078-3234
2300-7370
DOI:10.1016/j.oceano.2020.08.004