Using specific antisera to neutralize ACTH in sturgeon: a method for manipulating the interrenal response during stress.

Interrenal function and the magnitude of the stress response were assessed in green sturgeon (Acipenser medirostris) passively immunized with antisera directed against adrenocorticotropic hormone (ACTH). The nucleotide sequence encoding ACTH was determined using reverse transcriptase polymerase chain reaction (RT-PCR). We identified two isoforms of ACTH that differ at a single site (position 26) in the 39 AA peptide. Both forms of green sturgeon ACTH (gsACTH1-39) display 100% homology with both sequences of white sturgeon ACTH (wsACTH1-39). The N-terminal portion of gsACTH also shares absolute identity with the comparable portion of human ACTH (hACTH). However, we identified considerable sequence divergence in the C-terminal domain between gsACTH and hACTH. Species-specific anti-ACTH sera were generated by vaccinating sheep against the C-terminal portion of gsACTH (gsACTH26-39). The peptide was covalently linked to a carrier protein (keyhole-limpet-hemocyanin [KLH]) to further enhance its immunogenicity. The anti-gsACTH sera recognized gsACTH1-39 and the immunogenic peptide (gsACTH26-39), but did not interact with hACTH1-39. To assess the impact of the antisera, fish were passively immunized with anti-gsACTH26-39 sera or anti-KLH sera and challenged with a hACTH1-39 injection on day 1 followed by a 1-min air emersion stressor on day 2. The magnitude and duration of the secretory response induced by hACTH did not differ (P > .05) between groups. Conversely, the magnitude of cortisol secretion induced by air emersion was significantly attenuated (P < .05) in fish passively immunized against gsACTH26-39. Collectively, these data demonstrate that the targeted antisera used in this study can discriminate between mammalian and green sturgeon ACTH and moderate the in vivo response to a stressor.

The cost of chronic stress: impacts of a nonhabituating stress response on metabolic variables and swimming performance in sturgeon.

Metabolic scope for activity (MSA) and critical swimming velocity (U(crit)) were measured in green sturgeon exposed to two stressors daily for 28 consecutive days. The results were compared with unstressed fish in an effort to measure the "cost" of chronic stress. Chronic stress was simulated by exposing fish to a randomized order of acute stressors: a 5-min chasing stressor, a 10-min water depth reduction stressor, or a 5-min confinement stressor. The acute cortisol response to each stressor was initially determined, and the maintenance of that response was verified in 7-d intervals during the chronic stress regime. Exposure to the chronic stress regime resulted in a 25% reduction of MSA caused by significantly increased maintenance metabolic rate (0.27+/-0.01 vs. 0.19+/-0.02 mg O(2) h(-1) g(-1), chronic and control fish, respectively) but did not affect the U(crit) of sturgeon. In addition, a 50% reduction in liver glycogen levels and a twofold increase of resting plasma glucose levels were measured in chronically stressed fish. We conclude that our chronic stress regime resulted in a significant maintenance cost to green sturgeon, possibly because of their inability to habituate to the stressors, but did not decrease their swimming performance.

Time of day and water temperature modify the physiological stress response in green sturgeon, Acipenser medirostris.

The effects of time of day and water temperature on the acute physiological stress response were investigated in young-of-the-year green sturgeon (Acipenser medirostris). The response to a 1-min air-emersion stressor was assessed during the day (08.00 h) and at night (20.00 h), as well as after acclimation to either 11 degrees C or 19 degrees C. Blood samples were collected prior to stress and at several times after exposure to the stressor, and plasma concentrations of cortisol, lactate, and glucose were determined. The magnitudes of cortisol (19.1 ng ml(-1) vs. 4.9 ng ml(-1)) and lactate (190.6 mg l(-1) vs. 166.7 mg l(-1)) were significantly higher in fish stressed at night when compared with the day. There were no significant differences in glucose levels between time periods. Although, acclimation temperature did not affect peak cortisol concentrations (56.7 and 50.3 ng ml(-1) at 11 degrees C and 19 degrees C, respectively), the duration of the response was significantly extended at 11 degrees C. Post-stressor lactate increases were similar between temperature groups, but at 11 degrees C post-stressor glucose levels were significantly increased through 6 h, suggesting stressor-induced glycogenolysis and gluconeogenesis or decreased glucose utilization. These data demonstrate that the physiological stress response in green sturgeon is modified by both time of day and temperature.