Your search keyword '"Steeve Comeau"' showing total 2 results

1. Impacts of coral bleaching on pH and oxygen gradients across the coral concentration boundary layer: a microsensor study

Author

Verena Schoepf, Cinzia Alessi, Malcolm T. McCulloch, Steven A. Carrion, Christopher E. Cornwall, Svenja M. Pfeifer, Steeve Comeau, The University of Western Australia (UWA), Research School of Earth Sciences [Canberra] (RSES), and Australian National University (ANU)

Subjects

0106 biological sciences, 0301 basic medicine, biology, Chemistry, Coral bleaching, 010604 marine biology & hydrobiology, Coral, fungi, Ocean acidification, Aquatic Science, biology.organism_classification, Photosynthesis, 01 natural sciences, Acropora aspera, PH elevation, 03 medical and health sciences, 030104 developmental biology, 13. Climate action, Environmental chemistry, [SDE]Environmental Sciences, Acropora, Seawater, 14. Life underwater, ComputingMilieux_MISCELLANEOUS

Abstract

Reef-building corals are surrounded by complex microenvironments (i.e. concentration boundary layers) that partially isolate them from the ambient seawater. Although the presence of such concentration boundary layers (CBLs) could potentially play a role in mitigating the negative impacts of climate change stressors, their role is poorly understood. Furthermore, it is largely unknown how heat stress-induced bleaching affects O2 and pH dynamics across the CBLs of coral, particularly in branching species. We experimentally exposed the common coral species Acropora aspera to heat stress for 13 d and conducted a range of physiological and daytime microsensor measurements to determine the effects of bleaching on O2 and pH gradients across the CBL. Heat stress equivalent to 24 degree heating days (3.4 degree heating weeks) resulted in visible bleaching and significant declines in photochemical efficiency, photosynthesis rates and photosynthesis to respiration (P/R) ratios, whereas dark respiration and calcification rates were not impacted. As a consequence, bleached A. aspera had significantly lower (− 13%) surface O2 concentrations during the day than healthy corals, with concentrations being lower than that of the ambient seawater, thus resulting in O2 uptake from the seawater. Furthermore, we show here that Acropora, and potentially branching corals in general, have among the lowest surface pH elevation of all corals studied to date (0.041 units), which could contribute to their higher sensitivity to ocean acidification. Additionally, bleached A. aspera no longer elevated their surface pH above ambient seawater values and, therefore, had essentially no [H+] CBL. These findings demonstrate that heat stress-induced bleaching has negative effects on pH elevation and [H+] CBL thickness, which may increase the overall susceptibility of coral to the combined impacts of ocean acidification and warming.

Published

2018

2. Complex and interactive effects of ocean acidification and temperature on epilithic and endolithic coral-reef turf algal assemblages

Author

Maggie D. Johnson, Coulson A. Lantz, Jennifer E. Smith, and Steeve Comeau

Subjects

0106 biological sciences, geography, geography.geographical_feature_category, Primary producers, Ecology, Range (biology), 010604 marine biology & hydrobiology, Fringing reef, Global change, Ocean acidification, Coral reef, Aquatic Science, Biology, Photosynthesis, 010603 evolutionary biology, 01 natural sciences, Oceanography, Reef

Abstract

Turf algal assemblages are ubiquitous primary producers on coral reefs, but little is known about the response of this diverse group to ocean acidification (OA) across different temperatures. We tested the hypothesis that CO2 influences the functional response of epilithic and endolithic turf assemblages to increasing temperature. Replicate carbonate plugs covered by turf were collected from the reef and exposed to ambient and high pCO2 (1000 µatm) conditions for 3 weeks. Each pCO2 treatment was replicated across six temperatures (24.0–31.5 °C) that spanned the full seasonal temperature range on a fringing reef in Moorea, French Polynesia, and included one warming treatment (3 °C above daily average temperatures). Temperature and CO2 enrichment had complex, and sometimes interactive, effects on turf metabolism and growth. Photosynthetic and respiration rates were enhanced by increasing temperature, with an interactive effect of CO2 enrichment. Photosynthetic rates were amplified by high CO2 in the warmest temperatures, while the increase in respiration rates with temperature were enhanced under ambient CO2. Epilithic turf growth rates were not affected by temperature, but increased in response to CO2 enrichment. We found that CO2 and temperature interactively affected the endolithic assemblage, with the highest growth rates under CO2 enrichment, but only at the warmest temperatures. These results demonstrate how OA may influence algal physiology and growth across a range of ecologically relevant temperatures, and indicate that the effects of CO2 enrichment on coral-reef turf assemblages can be temperature dependent. The complex effects of CO2 enrichment and temperature across a suite of algal responses illustrates the importance of incorporating multiple stressors into global change experiments.

Published

2017