Systemic to Microscale Response of Orbicella faveolata to Future Ocean CO2 Conditions.

ABSTRACT WITHDRAWN

Abstract:
Coral reefs are one of the most economically important ecosystems on the planet, supplying roughly $30 billion USD annually into world economies from the goods and services they provide. Despite their great contributions, anthropogenic influence via carbon dioxide emissions is leading to unprecedented changes in the tropical oceans with concerns about subsequent negative impacts on reefs. Surface ocean pH has dropped 0.1 units in the past century, representing a thirty percent increase in hydrogen ion concentration. In spite of this rapid shift in oceanic chemistry, it is unclear how adult corals and their new recruits will be impacted. In this experiment we examined the relationship between CO2-induced seawater acidification, net calcification, and physiological parameters in Orbicella faveolata adults and new recruits under ambient (465 ± 5.52 ppm), and high (1451 ± 6.51 ppm) CO2 conditions. These treatments represented current and end of the century CO2 values predicted under the RCP8.5 scenario developed by the Intergovernmental Panel on Climate Change (IPCC). Electron microscopy (TEM/SEM) was used to examine coral cellular ultrastructure and newly formed aragonite skeletal crystal structures. Orbicella faveolata exhibited no significant difference in skeletal deposition rates under control and high CO2 conditions; however, crystal formations for both adult and juvenile O. faveolata were statistically longer in the high CO2 treatment. No significant differences were seen in photosynthesis or respiration rates. These results suggest that the addition of CO2 may cause a shift in the overall energy budgets causing a modification of skeletal aragonite crystal structures, rather than inhibiting skeletal crystal formation. Consequential to this energy shift, Orbicella faveolata belongs in the category of Scleractinian corals that exhibit a low sensitivity to ocean acidification and existing colonies may continue to calcify and build reefs in the face of ocean acidification. It remains unclear, however, what the long term effects of a more acidic ocean may be on gamete production and other energy expensive processes.