Resilience of Emiliania huxleyi to future changes in subantarctic waters

Resilience of Emiliania huxleyi to future changes in subantarctic waters

Lower pH and elevated temperature alter phytoplankton growth and biomass in short-term incubations, but longer-term responses and adaptation potential are less well-studied. To determine the future of the coccolithophore Emiliania huxleyi, a mixed genotype culture from subantarctic water was incubat...

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Bibliographic Details
Published in:PloS one Vol. 18; no. 11; p. e0284415
Main Authors: Armstrong, Evelyn, Law, Cliff S
Format: Journal Article
Language:English
Published: San Francisco Public Library of Science 02-11-2023
Public Library of Science (PLoS)
Subjects:
Acidification
Adaptation
Air pollution
Biogeochemistry
Biology and Life Sciences
Calcification
Carbon
Carbonates
Cell culture
Cell size
Chlorophyll
Climate change
Earth Sciences
Emiliania huxleyi
Environmental aspects
Evaluation
Genotypes
Growth rate
High temperature
Influence
Inorganic carbon
Medical prognosis
Neomycin
New Zealand
Ocean acidification
pH effects
Physical Sciences
Phytoplankton
Plankton
Plastic properties
Plasticity
Primary production
Prymnesiophytes
Resilience
Social Sciences
Temperature
Temperature effects
Water pollution
New Zealand
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Summary:Lower pH and elevated temperature alter phytoplankton growth and biomass in short-term incubations, but longer-term responses and adaptation potential are less well-studied. To determine the future of the coccolithophore Emiliania huxleyi, a mixed genotype culture from subantarctic water was incubated for 720 days under present-day temperature and pH, and also projected future conditions by the year 2100. The future population exhibited a higher growth rate relative to present-day cells transferred to future conditions after 309 days, indicating adaptation or genotype selection; this was reflected by an increase in optimum growth temperature of ~2.5°C by the end of the experiment. Following transfer to opposing conditions in short-term cross-over incubations, cell volume responded rapidly, within eight generations, confirming trait plasticity. The changes in growth rate and cell volume were larger than reported in previous single stressor relationships and incubations, suggesting synergistic or additive effects of combined elevated temperature and lower pH and highlighting the importance of long-term multiple stressor experiments. At the end of the incubation there were no significant differences in cellular composition (particulate organic content and chlorophyll a), or primary production between present-day and future populations. Conversely, two independent methods showed a 50% decrease in both particulate inorganic carbon and calcification rate, consistent with the decrease in cell volume, in the future population. The observed plasticity and adaptive capacity of E. huxleyi indicate resilience to future conditions in subantarctic waters, although changes in cell volume and carbonate may alter grazing loss and cell ballast, so influencing carbon export to the deep ocean.
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Competing Interests: The authors have declared that no competing interests exist.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0284415