Intertidal oysters reach their physiological limit in a future high-CO2 world

Sessile marine molluscs living in the intertidal zone experience periods of internal acidosis when exposed to air (emersion) during low tide. Relative to other marine organisms, molluscs have been identified as vulnerable to future ocean acidification; however, paradoxically it has also been shown t...

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Bibliographic Details
Published in:Journal of Experimental Biology
Main Authors: Scanes, Elliot (S30655), Parker, Laura M. (R14175), O'Connor, Wayne A., Stapp, Laura S., Ross, Pauline M. (R8495)
Other Authors: School of Science and Health (Host institution)
Format: Article in Journal/Newspaper
Language:English
Published: U.K., Company of Biologists 2017
Subjects:
Online Access:https://doi.org/10.1242/jeb.151365
http://ezproxy.uws.edu.au/login?url=http://jeb.biologists.org/content/220/5/765.supplemental
http://handle.westernsydney.edu.au:8081/1959.7/uws:39198
Description
Summary:Sessile marine molluscs living in the intertidal zone experience periods of internal acidosis when exposed to air (emersion) during low tide. Relative to other marine organisms, molluscs have been identified as vulnerable to future ocean acidification; however, paradoxically it has also been shown that molluscs exposed to high CO2 environments are more resilient compared with those molluscs naive to CO2 exposure. Two competing hypotheses were tested using a novel experimental design incorporating tidal simulations to predict the future intertidal limit of oysters in a high-CO2 world; either high-shore oysters will be more tolerant of elevated PCO2 because of their regular acidosis, or elevated PCO2 will cause high-shore oysters to reach their limit. Sydney rock oysters, Saccostrea glomerata, were collected from the high-intertidal and subtidal areas of the shore and exposed in an orthogonal design to either an intertidal or a subtidal treatment at ambient or elevated PCO2, and physiological variables were measured. The combined treatment of tidal emersion and elevated PCO2 interacted synergistically to reduce the haemolymph pH (pHe) of oysters, and increase the PCO2 in the haemolymph (Pe,CO2) and standard metabolic rate. Oysters in the intertidal treatment also had lower condition and growth. Oysters showed a high degree of plasticity, and little evidence was found that intertidal oysters were more resilient than subtidal oysters. It is concluded that in a high-CO2 world the upper vertical limit of oyster distribution on the shore may be reduced. These results suggest that previous studies on intertidal organisms that lacked tidal simulations may have underestimated the effects of elevated PCO2.