Inorganic carbon physiology underpins macroalgal responses to elevated CO2

Beneficial effects of CO2 on photosynthetic organisms will be a key driver of ecosystem change under ocean acidification. Predicting the responses of macroalgal species to ocean acidification is complex, but we demonstrate that the response of assemblages to elevated CO2 are correlated with inorgani...

Full description

Bibliographic Details
Published in:Scientific Reports
Main Authors: Cornwall, Christopher E., Revill, Andrew T., Hall-Spencer, Jason M., Milazzo, Marco, Raven, John A., Hurd, Catriona L.
Format: Article in Journal/Newspaper
Language:English
Published: 2017
Subjects:
Online Access:https://discovery.dundee.ac.uk/en/publications/d21ff350-b33e-48fa-bf5c-ddf99fbc859d
https://doi.org/10.1038/srep46297
https://discovery.dundee.ac.uk/ws/files/12927705/srep46297.pdf
Description
Summary:Beneficial effects of CO2 on photosynthetic organisms will be a key driver of ecosystem change under ocean acidification. Predicting the responses of macroalgal species to ocean acidification is complex, but we demonstrate that the response of assemblages to elevated CO2 are correlated with inorganic carbon physiology. We assessed abundance patterns and a proxy for CO2:HCO3(-) use (δ(13)C values) of macroalgae along a gradient of CO2 at a volcanic seep, and examined how shifts in species abundance at other Mediterranean seeps are related to macroalgal inorganic carbon physiology. Five macroalgal species capable of using both HCO3(-) and CO2 had greater CO2 use as concentrations increased. These species (and one unable to use HCO3(-)) increased in abundance with elevated CO2 whereas obligate calcifying species, and non-calcareous macroalgae whose CO2 use did not increase consistently with concentration, declined in abundance. Physiological groupings provide a mechanistic understanding that will aid us in determining which species will benefit from ocean acidification and why.