Seawater carbonate chemistry and growth rate of Emiliania huxleyi in lab experiment

Predicting the impacts of environmental change on marine organisms, food webs, and biogeochemical cycles presently relies almost exclusively on short-term physiological studies, while the possibility of adaptive evolution is often ignored. Here, we assess adaptive evolution in the coccolithophore Em...

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Bibliographic Details
Main Authors: Lohbeck, Kai T, Riebesell, Ulf, Collins, Sinéad, Reusch, Thorsten B H
Format: Dataset
Language:English
Published: PANGAEA 2013
Subjects:
Alkalinity
total
Aragonite saturation state
Bicarbonate ion
BIOACID
Biological Impacts of Ocean Acidification
Bottles or small containers/Aquaria (<20 L)
Calcite saturation state
Calculated using CO2SYS
Calculated using seacarb after Nisumaa et al. (2010)
Carbon
inorganic
dissolved
Carbonate ion
Carbonate system computation flag
Carbon dioxide
Emiliania huxleyi
Fugacity of carbon dioxide (water) at sea surface temperature (wet air)
Generation
Growth/Morphology
Growth rate
Haptophyta
Laboratory experiment
Laboratory strains
Light
North Atlantic
OA-ICC
Ocean Acidification International Coordination Centre
Partial pressure of carbon dioxide (water) at sea surface temperature (wet air)
Pelagos
pH
Phytoplankton
Population
Potentiometric titration
Replicates
Salinity
Single species
Species
Temperature
water
Treatment
Ocean acidification
Online Access:https://doi.pangaea.de/10.1594/PANGAEA.823153
https://doi.org/10.1594/PANGAEA.823153
Description
Summary:Predicting the impacts of environmental change on marine organisms, food webs, and biogeochemical cycles presently relies almost exclusively on short-term physiological studies, while the possibility of adaptive evolution is often ignored. Here, we assess adaptive evolution in the coccolithophore Emiliania huxleyi, a well-established model species in biological oceanography, in response to ocean acidification. We previously demonstrated that this globally important marine phytoplankton species adapts within 500 generations to elevated CO2. After 750 and 1000 generations, no further fitness increase occurred, and we observed phenotypic convergence between replicate populations. We then exposed adapted populations to two novel environments to investigate whether or not the underlying basis for high CO2-adaptation involves functional genetic divergence, assuming that different novel mutations become apparent via divergent pleiotropic effects. The novel environment "high light" did not reveal such genetic divergence whereas growth in a low-salinity environment revealed strong pleiotropic effects in high CO2 adapted populations, indicating divergent genetic bases for adaptation to high CO2. This suggests that pleiotropy plays an important role in adaptation of natural E. huxleyi populations to ocean acidification. Our study highlights the potential mutual benefits for oceanography and evolutionary biology of using ecologically important marine phytoplankton for microbial evolution experiments.

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