Annual patterns in phytoplankton phenology in Antarctic coastal waters explained by environmental drivers

Coastal zones of Antarctica harbor rich but highly variable phytoplankton communities. The mechanisms that control the dynamics of these communities are not well defined. Here we elucidate the mechanisms that drive seasonal species succession, based on algal photophysiological characteristics and en...

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Bibliographic Details
Published in:Limnology and Oceanography
Main Authors: Van Leeuwe, Maria A., Webb, Alison L., Venables, Hugh J., Visser, Ronald J.W., Meredith, Mike P., Elzenga, J. Theo M., Stefels, Jacqueline
Format: Article in Journal/Newspaper
Language:English
Published: Wiley 2020
Subjects:
Antarctic
Antarctic Peninsula
Rothera
Ryder
Ryder Bay
Rothera Station
Antarc*
Antarctica
Sea ice
Online Access:http://nora.nerc.ac.uk/id/eprint/528002/
https://nora.nerc.ac.uk/id/eprint/528002/1/lno.11477.pdf
https://aslopubs.onlinelibrary.wiley.com/doi/full/10.1002/lno.11477
Description
Summary:Coastal zones of Antarctica harbor rich but highly variable phytoplankton communities. The mechanisms that control the dynamics of these communities are not well defined. Here we elucidate the mechanisms that drive seasonal species succession, based on algal photophysiological characteristics and environmental factors. For this, phytoplankton community structure together with oceanographic parameters was studied over a 5‐year period (2012–2017) at Rothera Station at Ryder Bay (Western Antarctic Peninsula). Algal pigment patterns and photophysiological studies based on fluorescence analyses were combined with data from the Rothera Time‐Series program. Considerable interannual variation was observed, related to variations in wind‐mixing, ice cover and an El Niño event. Clear patterns in the succession of algal classes became manifest when combining the data collected over the five successive years. In spring, autotrophic flagellates with a high light affinity were the first to profit from increasing light and sea ice melt. These algae most likely originated from sea‐ice communities, stressing the role of sea ice as a seeding vector for the spring bloom. Diatoms became dominant towards summer in more stratified and warmer surface waters. These communities displayed significantly lower photoflexibility than spring communities. There are strong indications for mixotrophy in cryptophytes, which would explain much of their apparently random occurrence. Climate models predict continuing retreat of Antarctic sea‐ice during the course of this century. For the near‐future we predict that the marginal sea‐ice zone will still harbor significant communities of haptophytes and chlorophytes, whereas increasing temperatures will mainly be beneficial for diatoms.

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