The immune and stress responses of Atlantic cod to long-term increases in water temperature.

Sea-caged cod are limited in their movements in the water column, and thus can be exposed to large seasonal ( approximately 0-20 degrees C) temperature fluctuations. To investigate the physiological response of Atlantic cod to summer-like increases in temperature, we exposed 10 degrees C acclimated juvenile cod to a graded thermal challenge (1 degrees C increase every 5 days) and measured: (1) plasma cortisol and glucose levels; (2) the respiratory burst activity of blood leukocytes; and (3) the expression of specific immune-related genes [MHC Class I, Interleukin-1beta (IL-1beta), beta2-microglobulin (beta2-M), Immunoglobulin M (IgM)-light (L) and -heavy (H) chains] in the blood using quantitative reverse transcription-polymerase chain reaction (QRT-PCR). The experiment was stopped at 19.1 degrees C, with 26.7% of the fish surviving to this point. Plasma glucose levels increased slightly at 16 and 18 degrees C (by 1.39- and 1.74-fold, respectively), in contrast, cortisol levels were elevated significantly (by 2.9-fold) at 16 degrees C but returned to control levels thereafter. The effect of increasing temperature on the expression of immune related genes in blood cells (leukocytes) was variable and depended on the gene of interest. The expression of IgM-H remained stable for the duration of the experiment. In contrast, IL-1beta expression was increased significantly (by approximately 25-fold) at 19 degrees C as compared to time-matched control fish, and changes in the expression of beta2-M, MHC Class I and IgM-L followed a pattern similar to that seen for cortisol: increasing at 16 degrees C (by 4.2-, 5.3- and 17-fold, respectively), but returning to pre-stress levels by 19 degrees C. Interestingly, increasing temperatures had no effect on respiratory burst activity. This study is the first to examine the effects of a chronic regimen of increasing temperature on the stress physiology and immunology of a marine teleost, and suggests that immune function is influenced by complex interactions between thermal effects and temperature-induced stress (elevated circulating cortisol levels).

Trypsinogen expression during the development of the exocrine pancreas in winter flounder (Pleuronectes americanus).

Histological, biochemical and molecular techniques were used to describe the functional development of the pancreas in winter flounder (Pleuronectes americanus) with specific reference to the expression of three trypsinogen genes. The pancreas was identified shortly following hatch, appearing as a compact structure situated dorsal and slightly posterior to the liver. As the larval fish approached metamorphosis, the pancreas became diffuse, spreading throughout the mesentery surrounding the stomach, the upper intestine and the pyloric caecae. Trypsin 2 expression was detected from 5 days post-hatch (dph). Two other related trypsinogen genes isolated from the pyloric caecae (Trypsin 1) and the intestine (Trypsin 3) showed contrasting results. Trypsin 1 showed very low levels of expression and only in late larval stages and metamorphosis. Trypsin 3 showed expression only after 20 dph. In order to determine tissue-specific expression of the three trypsinogen genes, the RNA from seven gastrointestinal-associated tissues was examined. Trypsin 1 and Trypsin 2 expression was most notably associated with the pyloric caecae, cardiac stomach, pyloric stomach and the rectum, although some variation in expression level between tissues was observed. Trypsin 3 expression had a narrower tissue distribution and was only associated with the pyloric caecae and the rectum. The tissue expression patterns observed here are likely due in part to the diffuse nature of the pancreas. Trypsin-like activity was evident from hatch and continued at significant levels through to at least 25 dph.