Increased Food Resources Help Eastern Oyster Mitigate the Negative Impacts of Coastal Acidification

Oceanic absorption of atmospheric CO results in alterations of carbonate chemistry, a process coined ocean acidification (OA). The economically and ecologically important eastern oyster ( ) is vulnerable to these changes because low pH hampers CaCO precipitation needed for shell formation. Organisms...

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Bibliographic Details
Published in:Animals (Basel) 2023-03, Vol.13 (7), p.1161
Main Authors: Schwaner, Caroline, Barbosa, Michelle, Schwemmer, Teresa G, Pales Espinosa, Emmanuelle, Allam, Bassem
Format: Article
Language:English
Subjects:
Acidification
Animals
Availability
bioenergetics
Calcification
Calcium carbonate
Carbon dioxide
Carbon dioxide concentration
Chemical analysis
Climate change
Crassostrea
Crassostrea virginica
energy
Energy intake
Energy resources
Energy sources
Exposure
feeding
Feeding regimes
Food
Food availability
Food cans
Food processing
Food resources
Food selection
Homeostasis
Investigations
Metabolism
Mollusks
Mortality
Ocean acidification
Oceans
Organisms
oyster
Oysters
Physiological aspects
Physiology
Resilience
Sea-water
Seawater
Shellfish
Shells
Water analysis
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Summary:Oceanic absorption of atmospheric CO results in alterations of carbonate chemistry, a process coined ocean acidification (OA). The economically and ecologically important eastern oyster ( ) is vulnerable to these changes because low pH hampers CaCO precipitation needed for shell formation. Organisms have a range of physiological mechanisms to cope with altered carbonate chemistry; however, these processes can be energetically expensive and necessitate energy reallocation. Here, the hypothesis that resilience to low pH is related to energy resources was tested. In laboratory experiments, oysters were reared or maintained at ambient (400 ppm) and elevated (1300 ppm) CO levels during larval and adult stages, respectively, before the effect of acidification on metabolism was evaluated. Results showed that oysters exposed to elevated CO had significantly greater respiration. Subsequent experiments evaluated if food abundance influences oyster response to elevated CO . Under high food and elevated CO conditions, oysters had less mortality and grew larger, suggesting that food can offset adverse impacts of elevated CO , while low food exacerbates the negative effects. Results also demonstrated that OA induced an increase in oyster ability to select their food particles, likely representing an adaptive strategy to enhance energy gains. While oysters appeared to have mechanisms conferring resilience to elevated CO , these came at the cost of depleting energy stores, which can limit the available energy for other physiological processes. Taken together, these results show that resilience to OA is at least partially dependent on energy availability, and oysters can enhance their tolerance to adverse conditions under optimal feeding regimes.
ISSN:2076-2615
2076-2615
DOI:10.3390/ani13071161