Abstract
Ocean acidification is a recognized consequence of anthropogenic carbon dioxide (CO2) emission in the atmosphere. Despite its threat to marine ecosystems, little is presently known about the capacity for fish to respond efficiently to this acidification. In adult fish, acid–base regulatory capacities are believed to be relatively competent to respond to hypercapnic conditions. However, fish in early life stage could be particularly sensitive to environmental factors as organs and important physiological functions become progressively operational during this period. In this study, the response of European sea bass (Dicentrarchus labrax) larvae reared under three ocean acidification scenarios, i.e., control (present condition, P_{{{text{CO}}_{2} }} = 590 µatm, pH total = 7.9), low acidification (intermediate IPCC scenario, P_{{{text{CO}}_{2} }} = 980 µatm, pH total = 7.7), and high acidification (most severe IPCC scenario, P_{{{text{CO}}_{2} }} = 1520 µatm, pH total = 7.5) were compared across multiple levels of biological organizations. From 2 to 45 days-post-hatching, the chronic exposure to the different scenarios had limited influence on the survival and growth of the larvae (in the low acidification condition only) and had no apparent effect on the digestive developmental processes. The high acidification condition induced both faster mineralization and reduction in skeletal deformities. Global (microarray) and targeted (qPCR) analysis of transcript levels in whole larvae did not reveal any significant changes in gene expression across tested acidification conditions. Overall, this study suggests that contemporary sea bass larvae are already capable of coping with projected acidification conditions without having to mobilize specific defense mechanisms.
Highlights
Over the last two centuries, the intensification of human activities has led to a rise in the atmospheric concentration of carbon dioxide
Significant differences were observed among experimental conditions, with fish reared under low acidification (LA) exhibiting a survival rate of 21.5 ± 5.5% higher than those reared in the two other conditions (Table 3)
We demonstrated that chronic exposure to predicted levels of ocean acidification had a limited influence on the survival and growth of the larvae from the low acidification condition
Summary
Over the last two centuries, the intensification of human activities has led to a rise in the atmospheric concentration of carbon dioxide. Nowadays, this concentration is in excess of 400 ppm, a level which has never been reached in the past 800,000 years (Lüthi et al 2008). At the current rate of emissions, atmospheric C O2 concentration is projected to reach between 750 and 1000 ppm by the end of the twenty-first century (Intergovernmental Panel on Climate Change 2014). The increase in H+ concentration reduces the ocean pH, which represents the widely recognized phenomenon called “ocean acidification.”. Ocean surface pH has been reduced by 0.1 pH unit (U) during the last century and an additional drop of 0.3–0.5 The increase in H+ concentration reduces the ocean pH, which represents the widely recognized phenomenon called “ocean acidification.” Ocean surface pH has been reduced by 0.1 pH unit (U) during the last century and an additional drop of 0.3–0.5
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