Abstract
Ocean acidification (OA) is predicted to reduce reef coral calcification rates and threaten the long-term growth of coral reefs under climate change. Reduced coral growth at elevated pCO2 may be buffered by sufficiently high irradiances; however, the interactive effects of OA and irradiance on other fundamental aspects of coral physiology, such as the composition and energetics of coral biomass, remain largely unexplored. This study tested the effects of two light treatments (7.5 versus 15.7 mol photons m−2 d−1) at ambient or elevated pCO2 (435 versus 957 µatm) on calcification, photopigment and symbiont densities, biomass reserves (lipids, carbohydrates, proteins), and biomass energy content (kJ) of the reef coral Pocillopora acuta from Kāne‘ohe Bay, Hawai‘i. While pCO2 and light had no effect on either area- or biomass-normalized calcification, tissue lipids gdw−1 and kJ gdw−1 were reduced 15% and 14% at high pCO2, and carbohydrate content increased 15% under high light. The combination of high light and high pCO2 reduced protein biomass (per unit area) by approximately 20%. Thus, under ecologically relevant irradiances, P. acuta in Kāne‘ohe Bay does not exhibit OA-driven reductions in calcification reported for other corals; however, reductions in tissue lipids, energy content and protein biomass suggest OA induced an energetic deficit and compensatory catabolism of tissue biomass. The null effects of OA on calcification at two irradiances support a growing body of work concluding some reef corals may be able to employ compensatory physiological mechanisms that maintain present-day levels of calcification under OA. However, negative effects of OA on P. acuta biomass composition and energy content may impact the long-term performance and scope for growth of this species in a high pCO2 world.
Highlights
Scleractinian corals are engineers of tropical coral reef ecosystems, directing the architecture and bioenergetics of these communities [1]
We address the following questions: (1) Does elevated pCO2 affect calcification, coral biomass and tissue energy content, 3 Symbiodinium density and chlorophyll concentration? (2) Are the effects of pCO2 on coral biomass and calcification modulated by light availability? We reasoned high pCO2 effects on energy reserves and calcification would be attenuated by increased light availability [18] due to stimulatory effects of light on coral tissue and skeletal growth [4,16,40]
Seawater treatments differed in pCO2 (p < 0.001) and pH on the total scale (pHT) conditions (p < 0.001) and AT was not affected by CO2 treatment (p = 0.110). pCO2 and pHT did not differ among replicate CO2 treatment tanks (p ≥ 0.060)
Summary
Scleractinian corals are engineers of tropical coral reef ecosystems, directing the architecture and bioenergetics of these communities [1]. Dissolution of atmospheric CO2 in the upper ocean alters the carbonate chemistry of seawater and reduces seawater pH and the saturation state of aragonite (Ωarag) [4] These changes in seawater chemistry negatively impact many marine organisms, for example, by reducing rates of biogenic calcification in ecologically and economically important marine calcifiers [5,6]. The role of light in modulating OA effects on skeletal growth is gaining attention; few studies have addressed whether other important aspects of coral physiology—such as tissue biomass growth and composition, and the allocation of energy resources—are impacted by pCO2 [19,20,21] and its interaction with light availability
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