Comparative Biochemistry and Physiology, Part A

Enclosed are the raw data for the tables and figures, along with a statistical analysis summary, related to the manuscript "The Environmental Tolerances and Metabolic Physiology of Sablefish (Anoplopoma fimbria)".

Anatomically accurate surface model of the head of a sturgeon (Huso dauricus)

TIFF images from an X-ray scan of the head of a sturgeon, Huso dauricus

STL model of Huso dauricus's head, with tapered extension

Data include individual identifiers (bird ID), the week during which data were collected, bactericidal activity (BKA), the treatment applied to each individual (Treatment), the experimental period (Period), the sex of each individual (Sex), and the morphotype of each individual (Morphotype).

Enclosed are the raw data and a statistical report related to the manuscript "The Acute and Incremental Thermal Tolerance of Cod (Gadus morhua) Families Under Normoxia and Mild Hypoxia"

Ocean acidification (OA) and the associated changes in seawater carbonate chemistry pose a threat to calcifying organisms. This is particularly serious for shelled molluscs, in which shell growth and microstructure has been shown to be highly sensitive to OA. To improve our understanding of the responses of abalone to OA, this study investigated the effects of CO2-induced ocean acidification on extra-cellular acid–base parameters in the European abalone Haliotis tuberculata. Three-year-old adult abalone were exposed for 15 days to three different pH levels (7.9, 7.7, 7.4) representing current and predicted near-future conditions. Hæmolymph pH and total alkalinity were measured at different time points during exposure and used to calculate the carbonate parameters of the extracellular fluid. Total protein content was also measured to determine whether seawater acidification influences the composition and buffer capacity of hæmolymph. Extracellular pH was maintained at seawater pH 7.7 indicating that abalones are able to buffer moderate acidification (−0.2 pH units). This was not due to an accumulation of HCO3− ions but rather to a high hæmolymph protein concentration. By contrast, hæmolymph pH was significantly decreased after 5 days of exposure to pH 7.4, indicating that abalone do not compensate for higher decreases in seawater pH. Total alkalinity and dissolved inorganic carbon were also significantly decreased after 15 days of low pH exposure. It is concluded that changes in the acid–base balance of the hæmolymph might be involved in deleterious effects recorded in adult H. tuberculata facing severe OA stress. This would impact both the ecology and aquaculture of this commercially important species.

geoscientificInformation

geoscientificInformation

geoscientificInformation