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Maximum thermal limits of coral reef damselfishes are size dependent and resilient to near-future ocean acidification


Clark, TD and Roche, DG and Binning, SA and Speers-Roesch, B and Sundin, J, Maximum thermal limits of coral reef damselfishes are size dependent and resilient to near-future ocean acidification, Journal of Experimental Biology, 220, (19) pp. 3519-3526. ISSN 0022-0949 (2017) [Refereed Article]


Copyright Statement

Copyright 2017. Published by The Company of Biologists Ltd. Licensed under Creative Commons Attribution 3.0 Unported (CC BY 3.0)

DOI: doi:10.1242/jeb.162529


Theoretical models predict that ocean acidification, caused by increased dissolved CO2, will reduce the maximum thermal limits of fishes, thereby increasing their vulnerability to rising ocean temperatures and transient heatwaves. Here, we test this prediction in three species of damselfishes on the Great Barrier Reef, Australia. Maximum thermal limits were quantified using critical thermal maxima (CTmax) tests following acclimation to either present-day or end-of-century levels of CO2 for coral reef environments (∼500 or ∼1,000 µatm, respectively). While species differed significantly in their thermal limits, whereby Dischistodus perspicillatus exhibited greater CTmax (37.88±0.03oC; N=47) than Dascyllus aruanus (37.68±0.02oC; N=85) and Acanthochromis polyacanthus (36.58±0.02oC; N=63), end-of-century CO2 had no effect (D. aruanus) or a slightly positive effect (increase in CTmax of 0.16oC in D. perspicillatus and 0.21oC in A. polyacanthus) on CTmax. Contrary to expectations, smaller individuals were equally as resilient to CO2 as larger conspecifics, and CTmax was higher at smaller body sizes in two species. These findings suggest that ocean acidification will not impair the maximum thermal limits of reef fishes, and they highlight the critical role of experimental biology in testing predictions of theoretical models forecasting the consequences of environmental change.

Item Details

Item Type:Refereed Article
Keywords:carbon dioxide, CO2, critical thermal maximum, CTmax, Great Barrier Reef, climate change, climate warming, thermal tolerance, fish, ontogeny
Research Division:Biological Sciences
Research Group:Zoology
Research Field:Animal physiological ecology
Objective Division:Environmental Management
Objective Group:Coastal and estuarine systems and management
Objective Field:Coastal or estuarine biodiversity
UTAS Author:Clark, TD (Dr Timothy Clark)
ID Code:123597
Year Published:2017
Web of Science® Times Cited:21
Deposited By:Fisheries and Aquaculture
Deposited On:2018-01-14
Last Modified:2018-05-17
Downloads:75 View Download Statistics

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