Starvation rates in larval and juvenile Atlantic silversides (Menidia menidia) are unaffected by high CO2 conditions

• Published in: Marine biology Vol. 165; no. 4; pp. 1 - 9
• Main Authors: Baumann, Hannes, Parks, Elle M., Murray, Christopher S.
• Format: Journal Article
• Language: English
• Published: Berlin/Heidelberg Springer Berlin Heidelberg 01.04.2018; Springer Nature B.V
• Subjects: Biomedical and Life Sciences; Carbon dioxide; Deprivation; Dietary restrictions; Extreme values; Feeding; Fish; Food consumption; Food intake; Food supply; Foods; Freshwater & Marine Ecology; Laboratory tests; Larvae; Larval development; Life cycles; Life Sciences; Marine & Freshwater Sciences; Marine biology; Masking; Menidia menidia; Metabolism; Microbiology; Oceanography; Offspring; Original Paper; Reconfiguration; Starvation; Stochasticity; Zoology
• ISSN: 0025-3162; 1432-1793
• DOI: 10.1007/s00227-018-3335-x

Over the past decade, laboratory experiments on fish early life stages have found many traits that are evidently sensitive to elevated CO 2 levels. With respect to larval growth, high CO 2 environments are commonly assumed to increase acid–base regulation and other plastic responses, thus incurring additional metabolic costs that reduce the scope for growth. This assumption is not well supported by empirical evidence. One reason might be that experiments often provide unrestricted feeding conditions, which could allow larvae to compensate for higher costs by increased food intake. To remove potentially confounding effects of larval feeding, we conducted a series of starvation trials on offspring of the Atlantic silverside ( Menidia menidia ), predicting faster starvation at high compared to ambient CO 2 treatments. We compiled observations from five separate experiments spanning different years, laboratories, temperatures (17–26 °C), life stages (newly hatched larvae, previously fed larvae, early juveniles), and CO 2 levels (300–6500 µatm). Contrary to expectation, we found that starvation rates were largely independent of the CO 2 environment in this fish species. The one exception occurred at the lowest temperature and most extreme CO 2 treatment, which resulted in slower not faster starvation in newly hatched larvae at high compared to ambient CO 2 treatments. The apparent failure of starvation rate as a proxy for CO 2 effects on larval fish metabolism may have several reasons, including potential CO 2 tolerance of offspring, observed large stochasticity in early life survival masking small metabolic costs of high CO 2 , and the general depression and reconfiguration of fish metabolism in response to food deprivation.