Abstract
Anthropogenically-forced changes in ocean chemistry at both the global and regional scale have the potential to negatively impact calcifying plankton, which play a key role in ecosystem functioning and marine carbon cycling. We cultured a globally important calcifying marine plankter (the foraminifer, Globigerina bulloides) under an ecologically relevant range of seawater pH (7.5 to 8.3 total scale). Multiple metrics of calcification and physiological performance varied with pH. At pH > 8.0, increased calcification occurred without a concomitant rise in respiration rates. However, as pH declined from 8.0 to 7.5, calcification and oxygen consumption both decreased, suggesting a reduced ability to precipitate shell material accompanied by metabolic depression. Repair of spines, important for both buoyancy and feeding, was also reduced at pH < 7.7. The dependence of calcification, respiration, and spine repair on seawater pH suggests that foraminifera will likely be challenged by future ocean conditions. Furthermore, the nature of these effects has the potential to actuate changes in vertical transport of organic and inorganic carbon, perturbing feedbacks to regional and global marine carbon cycling. The biological impacts of seawater pH have additional, important implications for the use of foraminifera as paleoceanographic indicators.
Highlights
Global change, driven by the anthropogenic release of carbon dioxide (CO2) into the atmosphere, is rapidly altering modern oceans
While reductions in planktic foraminiferal shell weight have been observed under decreased seawater pH in the laboratory and in some field studies[18,19,20,21, 31], other studies show no such trend[32, 33]
We provide a first exploration of additional biological consequences of ocean acidification by culturing the widespread planktic foraminifer, Globigerina bulloides, a common focal taxon in paleoceanographic research, under a range of seawater pH
Summary
Driven by the anthropogenic release of carbon dioxide (CO2) into the atmosphere, is rapidly altering modern oceans. While a reduction in [CO32−] over the range shown here would negatively impact foraminiferal calcification at the population level, the amount of CaCO3 added to the shell varied among individuals (Fig. S1B).
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