H+-driven increase in CO2 uptake and decrease in HCO3- uptake explain coccolithophores' acclimation responses to ocean acidification

Kottmeier, Dorothee; Rokitta, Sebastian D; Rost, Björn

H+-driven increase in CO2 uptake and decrease in HCO3- uptake explain coccolithophores' acclimation responses to ocean acidification

2016

Kottmeier, Dorothee | Rokitta, Sebastian D | Rost, Björn

Recent ocean acidification (OA) studies revealed that seawater [H+] rather than [CO2] or [ inline image] regulate short-term responses in carbon fluxes of Emiliania huxleyi. Here, we investigated whether acclimation to altered carbonate chemistry modulates this regulation pattern and how the carbon supply for calcification is affected by carbonate chemistry. We acclimated E. huxleyi to present-day (ambient [CO2], [ inline image], and pH) and OA conditions (high [CO2], ambient [ inline image], low pH). To differentiate between the CO2 and pH/H+ effects, we also acclimated cells to carbonation (high [CO2] and [ inline image], ambient pH) and acidification (ambient [CO2], low [ inline image], and pH). Under these conditions, growth, production of particulate inorganic and organic carbon, as well as carbon and oxygen fluxes were measured. Under carbonation, photosynthesis and calcification were stimulated due to additional inline image uptake, whereas growth was unaffected. Such stimulatory effects are not apparent after short-term carbonation, indicating that cells adjusted their carbon acquisition during acclimation. Being driven by [ inline image], these regulations can, however, not explain typical OA effects. Under acidification and OA, photosynthesis stayed constant, whereas calcification and growth decreased. Similar to the short-term responses toward high [H+], CO2 uptake significantly increased, but inline image uptake decreased. This antagonistic regulation in CO2 and inline image uptake can explain why photosynthesis, being able to use CO2 and inline image, often benefits from OA, whereas calcification, being mostly dependent on inline image, often decreases. We identified H+ as prime driver of coccolithophores' acclimation responses toward OA. Acidified conditions seem to put metabolic burdens on the cells that result in decreased growth.

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alkalinity carbon carbon dioxide growth rate nitrogen oxygen particulate organic carbon ph phytoplankton production respiration respiration rate salinity species temperature water

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Bottles or small containers/aquaria (<20 l); Carbon dioxide uptake rate; Bicarbonate uptake rate; Total; Chromista; Particulate organic nitrogen per cell; Inorganic; Primary production/photosynthesis; Laboratory strains; Particulate/nitrogen; Production per cell; Particulate ratio; Carbon dioxide uptake; Growth/morphology; Particulate inorganic carbon/particulate organic carbon ratio; Calcification/dissolution; Aragonite saturation state; Laboratory experiment; Total scale; Emiliania huxleyi; Type; Calculated using seacarb after nisumaa et al. (2010); Nbs scale; Carbonate system computation flag; Carbon dioxide usage fraction; Biomass/abundance/elemental composition; Calcification rate; Fugacity of carbon dioxide (water) at sea surface temperature (wet air); Uniform resource locator/link to reference; Hydrogen ion; Ocean acidification international coordination centre; Particulate inorganic carbon; Particulate; Carbonate ion; Haptophyta; Organic; Calcification rate of calcium carbonate; Per chlorophyll; Partial pressure of carbon dioxide; Registration number of species; Dissolved; Per chlorophyll a; Chlorophyll a per cell; Oa-icc; Ratio; Per cell; Treatment; Not applicable; Pelagos; Chlorophyll a; Standard deviation; Calcite saturation state; Net photosynthesis rate; Bicarbonate ion; Single species; Chlorophyll a/particulate organic carbon ratio; Bicarbonate uptake in chlorophyll; Partial pressure of carbon dioxide (water) at sea surface temperature (wet air)

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text/tab-separated-values, 495 data points

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CC-BY-3.0: Creative Commons Attribution 3.0 Unported, Access constraints: unrestricted, info:eu-repo/semantics/openAccess

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Supplement to: Kottmeier, Dorothee; Rokitta, Sebastian D; Rost, Björn (2016): H+-driven increase in CO2 uptake and decrease in HCO3- uptake explain coccolithophores' acclimation responses to ocean acidification. Limnology and Oceanography, 61(6), 2045-2057, https://doi.org/10.1002/lno.10352

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Fecha de modificación: 2025-10-25

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H+-driven increase in CO2 uptake and decrease in HCO3- uptake explain coccolithophores' acclimation responses to ocean acidification

2016

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