Abstract
Ocean acidification caused by anthropogenic uptake of CO2 is perceived to be a major threat to calcifying organisms. Cold-water corals were thought to be strongly affected by a decrease in ocean pH due to their abundance in deep and cold waters which, in contrast to tropical coral reef waters, will soon become corrosive to calcium carbonate. Calcification rates of two Mediterranean cold-water coral species, Lophelia pertusa and Madrepora oculata, were measured under variable partial pressure of CO2 (pCO2) that ranged between 380 µatm for present-day conditions and 930 µatm for the end of the century. The present study addressed both short- and long-term responses by repeatedly determining calcification rates on the same specimens over a period of 9 months. Besides studying the direct, short-term response to elevated pCO2 levels, the study aimed to elucidate the potential for acclimation of calcification of cold-water corals to ocean acidification. Net calcification of both species was unaffected by the levels of pCO2 investigated and revealed no short-term shock and, therefore, no long-term acclimation in calcification to changes in the carbonate chemistry. There was an effect of time during repeated experiments with increasing net calcification rates for both species, however, as this pattern was found in all treatments, there is no indication that acclimation of calcification to ocean acidification occurred. The use of controls (initial and ambient net calcification rates) indicated that this increase was not caused by acclimation in calcification response to higher pCO2. An extrapolation of these data suggests that calcification of these two cold-water corals will not be affected by the pCO2 level projected at the end of the century.
Highlights
Ocean acidification is one of the major threats to the marine environment and has become a central research focus in marine science during the last decade
PHT and Va were lower in coral vials than in blanks while pressure of CO2 (pCO2) increased (Table 2)
The present study revealed significant changes observed as function of time for all pCO2 treatments, but this must be attributed to other causes than pCO2 either related to aquarium conditions or coral biology
Summary
Ocean acidification is one of the major threats to the marine environment and has become a central research focus in marine science during the last decade. The ocean and atmosphere exchange carbon dioxide (CO2) [1], and the net uptake of CO2 by the ocean causes the pH to decline. Many calcifying organisms will be affected by ocean acidification with a decrease of the growth of their shells or skeletons [4,5,6,7]. The predictions as to the detrimental effects of ocean acidification are almost unison and foresee a decline in reef growth [11,12,13,14,15] and a shift in species composition with a decrease in diversity [16,17]. It has been shown, that the response to ocean acidification can be highly variable for different taxonomic groups [18]
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