Highlights
- Protein carbonyl concentration increased, and Na+/K+-ATPase activity decreased with decreasing acute pH in American lobster embryos.
- Oxygen consumption rate and antioxidant content of embryos increased significantly over development.
- American lobster embryos were sensitive to acute pH reductions representative of future ocean and coastal acidification.
Abstract
Ocean and coastal acidification are altering carbonate chemistry conditions and inducing physiological stress in marine organisms. Early life history stages of marine invertebrates, including commercially important species like the American lobster (Homarus americanus) may have limited physiological capacity to tolerate changes in carbonate chemistry. Using American lobster embryos, we quantified physiological disturbances caused by acute changes in carbonate chemistry. We exposed freshly isolated lobster embryos to conditions ranging from 6.94 to 8.07 pH for 24 h at three points during embryo development. With more extreme conditions of acidification, protein carbonyl concentration (indicative of cellular damage from oxidative stress) increased, and Na+/K+-ATPase activity (associated with acid-base regulation) decreased at all stages of development examined. Although oxygen consumption rate and ferric-reducing antioxidant potential both increased over the course of embryogenesis, we found no evidence that the relationship between pH and these physiological metrics varied during ontogeny. Our results indicate that acid-base regulation and oxidative stress in American lobster embryos may be sensitive to acidification-induced hypercapnia within a 24-h period across a large portion of embryo development.
Sisti A. R., Jellison B. M., Shields J. D. & Rivest E. B., 2025. Physiological effects of acute exposure to acidification conditions in embryos of the American lobster (Homarus americanus). Journal of Experimental Marine Biology and Ecology 585: 152095. doi: 10.1016/j.jembe.2025.152095. Article.
