Global Warming Impacts Micro-Phytoplankton at a Long-Term Pacific Ocean Coastal Station

Understanding impacts of global warming on phytoplankton – the foundation of marine ecosystems – is critical to predicting changes in future biodiversity, ocean productivity, and ultimately fisheries production. Using phytoplankton community abundance and environmental data that span ~90 years (1931...

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Bibliographic Details
Published inFrontiers in Marine Science Vol. 7
Main Authors Ajani, Penelope A., Davies, Claire H., Eriksen, Ruth S., Richardson, Anthony J.
Format Journal Article
LanguageEnglish
Published Lausanne Frontiers Research Foundation 21.10.2020
Frontiers Media S.A
Subjects
Abundance
Affinity
Biodiversity
Climate change
community temperature index
diatom
Diatoms
Environmental conditions
Global warming
Investigations
Leptocylindrus danicus
Marine ecosystems
Nutrient deficiencies
Ocean warming
Oceans
Phytoplankton
Plankton
Ports
Preferences
Relative abundance
Resting spores
Salinity
Seasonal variation
Spores
Temperature preferences
Time series
Water temperature
Australia
Pacific Ocean
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Summary:Understanding impacts of global warming on phytoplankton – the foundation of marine ecosystems – is critical to predicting changes in future biodiversity, ocean productivity, and ultimately fisheries production. Using phytoplankton community abundance and environmental data that span ~90 years (1931-2019) from a long-term Pacific Ocean coastal station off Sydney, Australia, we examined the response of the phytoplankton community to long-term ocean warming using the Community Temperature Index, an index of the preferred temperature of a community. With warming of ~1.8℃ at the site since 1931, we found a significant increase in the community temperature index from 1931-1932 to 2009-2019, suggesting that the relative proportion of warm-water to cold-water species has increased. The Community Temperature Index also showed a clear seasonal cycle, with highest values at the end of austral summer (Feb/Mar) and lowest at the end of winter (Aug/Sept), a pattern well supported by other studies at this location. The shift in CTI was a consequence of the decline in the relative abundance of the cool-affinity (optimal temperature = 18.7℃), chain-forming diatom Asterionellopsis glacialis (40% in 1931-1932 to 13% in 2009 onwards), and a substantial increase in the warm-affinity (21.5℃), also chain-forming diatom Leptocylindrus danicus (20% in 1931-1932 to 57% in 2009 onwards). L. danicus reproduces rapidly, forms resting spores under nutrient depletion, and displays a wide thermal range. Species such as L. danicus may provide a glimpse of the functional traits necessary to be a ‘winner’ under climate change.
ISSN:2296-7745
2296-7745
DOI:10.3389/fmars.2020.576011