Altered burst swimming in rainbow trout Oncorhynchus mykiss exposed to natural and synthetic oestrogens.

Juvenile rainbow trout Oncorhynchus mykiss were exposed to two concentrations each of 17ß-oestradiol (E2; natural oestrogen hormone) or 17α-ethinyl oestradiol (EE2; a potent synthetic oestrogen hormone) to evaluate their potential effects on burst-swimming performance. In each of six successive burst-swimming assays, burst-swimming speed (Uburst ) was lower in fish exposed to 0.5 and 1 µg l(-1) E2 and EE2 for four days compared with control fish. A practice swim (2 days prior to exposure initiation) in control fish elevated initial Uburst values, but this training effect was not evident in the 1 µg l(-1) EE2-exposed fish. Several potential oestrogen-mediated mechanisms for Uburst reductions were investigated, including effects on metabolic products, osmoregulation and blood oxygen-carrying capacity. Prior to burst-swimming trials, fish exposed to E2 and EE2 for 4 days had significantly reduced erythrocyte numbers and lower plasma glucose concentrations. After six repeated burst-swimming trials, plasma glucose, lactate and creatinine concentrations were not significantly different among treatment groups; however, plasma Cl(-) concentrations were significantly reduced in E2- and EE2-treated fish. In summary, E2 and EE2 exposure altered oxygen-carrying capacity ([erythrocytes]) and an osmoregulatory-related variable ([Cl(-) ]), effects that may underlie reductions in burst-swimming speed, which will have implications for fish performance in the wild.

Induction and recovery of estrogenic effects after short-term 17ß-estradiol exposure in juvenile rainbow trout (Oncorhynchus mykiss).

Estrogenic compounds found in the aquatic environment include natural and synthetic estrogen hormones as well as other less potent estrogenic xenobiotics. In this study, a comprehensive approach was used to examine effects on fish endocrine system endpoints during a short-term xenoestrogen exposure as well as after post-exposure recovery. Rainbow trout (Oncorhynchus mykiss) were exposed to an aqueous 17ß-estradiol (E2) concentration of 0.473 µg l(-1) for 2 and 7 days (d) followed by a 14-d recovery period. At d2 and d7, plasma E2 concentrations in treated fish were 458- and 205-fold higher than in control fish and 23- and 16-fold higher than the exposure water concentration. E2 treatment resulted in significant increases in hepatosomatic index (HSI), plasma vitellogenin (VTG) protein concentrations, and liver VTG and estrogen receptor alpha mRNA levels. All of these parameters, with the exception of plasma VTG protein, returned to baseline values during the recovery period. Plasma cortisol concentrations were unaffected by treatment. This research shows varied time frames of the estrogen-responsive molecular-, biochemical-, and tissue-level alterations, as well as their persistence, in juvenile rainbow trout treated with aqueous E2. These results have implications for feral rainbow trout exposed to xenoestrogens and indicate the importance of evaluating a comprehensive suite of endpoints in assessing the impact of this type of environmental contaminant.

Concentration-response relationships and temporal patterns in hepatic gene expression of Chinook salmon (Oncorhynchus tshawytscha) exposed to sewage.

Changes in liver gene expression were examined in juvenile Chinook salmon (Oncorhynchus tshawytscha) exposed in vivo for 8d to seawater (control) or one of 5 concentrations of sewage (environmentally-relevant dilutions of 0.05%, 0.1%, and 0.7%; 2%, 5% or 10%) and subsequently transferred to clean seawater for an 8-d recovery period. Livers were sampled on days 1, 4, 8 (sewage-exposed) and 16 (8d of sewage exposure plus 8d of recovery). A custom cDNA microarray using a universal DNA reference design was used to examine trends of altered gene expression across sewage concentrations, across timepoints, and at the end of the recovery period. Alterations in gene expression followed four distinct concentration-dependent patterns: (1) concentration response (e.g. estrogen receptor alpha), (2) inverse-concentration response (e.g. insulin receptor beta), U-shaped (e.g. mineralocorticoid receptor), (3) inverse U-shaped (e.g. benzodiazepine receptor), and (4) concentration-independent responses (e.g. ubiquitin). Temporal trends included: (1) peak gene expression at one of the sewage exposure timepoints with recovery to baseline levels after the depuration phase (e.g. vitelline envelope protein beta), (2) gene expression alterations that did not recover (e.g. glucose transporter 3), and (3) delayed gene expression alterations initiated only at the recovery timepoint (e.g. insulin-like growth factor 2). In summary, patterns in gene expression changes were found across sewage concentrations and exposure timepoints. This study is the first to show gene expression trends of this nature.

Immunocompetence and alterations in hepatic gene expression in rainbow trout exposed to CdS/CdTe quantum dots.

Cadmium (Cd) tellurium quantum dots (QDs) are long-lived fluorescent nanocrystals that have the ability to produce potentially toxic reactive oxygen species at the surface of the nanoparticle and release toxic cadmium ions. The purpose of this study was to examine the sublethal effects of CdS/CdTe QDs and dissolved Cd on the immune system of rainbow trout. Changes in hepatic gene expression were also monitored to provide insight on the mode of action of both forms of cadmium. Oncorhynchus mykiss fish were exposed to increasing concentrations of CdS/CdTe or dissolved Cd (CdSO(4)) for 48 h at 15 degrees C. The anterior head kidney was analyzed for leukocyte count, viability and phagocytic activity. The livers were harvested and prepared for gene expression analysis using a DNA microarray comprised of 207 stress-related genes. An analysis of total Cd in the aquarium water revealed that the nominal concentrations corresponded well to the actual concentrations and that a small proportion (0.4%) of Cd in the QDs was found in the dissolved fraction. Exposure to QDs led to significant reductions in leukocyte counts, viability and both resting and active phagocytic activity. On a mass concentration basis, QDs were more potent than dissolved Cd in suppressing immunocompetence in rainbow trout. The analysis revealed that both forms of Cd were strong inducers of metallothionein and CP2K1 gene expressions, which are respectively involved in metal detoxification processes and xenobiotic transformation/inflammation conditions. The analysis revealed different modes of action for each form of Cd. For QDs, 25 genes specific to QDs and related to the immune endpoints were found. The genes were involved in inflammation, xenobiotic biotransformation and endocrine system (including the induction of vitellogenin and its receptor). The effect for dissolved Cd was narrower than for QDs, with 9 genes specific to dissolved Cd being strongly correlated with the observed effects on immunocompetence. The involved genes were binding and transport of various solutes (urea, sodium, potassium) and the complement system. The present study revealed that each form of Cd produced a different pattern of gene expression and lowered fish immunocompetence.

Metabolic zonation in teleost gastrointestinal tract. Effects of fasting and cortisol in tilapia.

Activities of several metabolic enzymes show distinct patterns of zonation along the intestinal tract of tilapia (Oreochromis niloticus), rainbow trout (Oncorhynchus mykiss) and copper rockfish (Sebastes caurinus). Zonation is species and enzyme specific, with different metabolic activities concentrated in specific areas, and few generalizations can be made. The rockfish show the smallest degree of zonation, with highest activities in the third quarter of the intestine, and shallow gradients to either side, and a general upswing in activity towards the distal end. In the trout, mitochondrial enzyme activities (citrate synthase, glutamate dehydrogenase, malate dehydrogenase) are highest in the pyloric caeca and decrease along the length of the small intestine. This pattern is accentuated for malic enzyme and glucose 6-phosphate dehydrogenase. These enzymes drop precipitously in activity after the first few sections of the small intestine, while other NADP-linked dehydrogenases (isocitrate dehydrogenase, and 6-phosphogluconate dehydrogenase) show moderate activity in pyloric caeca and peak toward the distal section of the small intestine. In tilapia, glutamate dehydrogenase shows a similar decrease as in trout, but citrate synthase peaks towards the distal sections. NADP-dependent dehydrogenases reveal distinct patterns, peaking in different sections of the intestine-malic enzyme in the proximal midsection, glucose 6-phosphate dehydrogenase in the distal mid-section, and isocitrate dehydrogenase in the anal section. Enzyme activities in the stomach of trout and tilapia also show zonation, with the midsection generally displaying the highest activities. A 5-day treatment of tilapia with an intraperitoneal cortisol deposit (25 mg kg(-1) wet mass) drastically alters metabolic performance along the gut in enzyme specific patterns, generally increasing enzyme activities in site-specific arrangements. Cortisol treatment also leads to the expected increases in activities of phosphoenolpyruvate carboxykinase, pyruvate kinase and aspartate aminotransferase in liver, but not in kidney. Aspartate aminotransferase is the only enzyme in brain significantly increased by cortisol treatment. Short-term food deprivation changes enzyme patterns, often resembling those observed after cortisol administration. We conclude that brain, liver and intestinal amino acid metabolism is an important target for cortisol action in fish and that metabolic zonation is a key factor to be reckoned with when analyzing physiological phenomena in the fish intestine.

Glutamine synthetase in tilapia gastrointestinal tract: zonation, cDNA and induction by cortisol.

Glutamine synthetase, an enzyme generally associated with ammonia detoxication in the vertebrate brain and with hepatic nitrogen turnover in mammals, shows substantial activities in the gastrointestinal tract of teleostean fishes. Enzyme activity is highest in the central area of the stomach and reveals a distinct distribution pattern in stomach and along the intestine of tilapia (Oreochromis niloticus), rainbow trout (Oncorhynchus mykiss) and copper rockfish (Sebastes caurinus). In all three species, intestinal activity peaks in the distal region of the intestine. The brain contains the highest titre of the enzyme (46 U g(-1) in tilapia brain versus 15 U g(-1) in tilapia stomach), but because of the relative mass of the stomach, the largest glutamine synthetase pool in tilapia body appears to be localized in the stomach. Activities in white and red muscle are very modest at 0.1% of the brain. Independent of distribution, peak activities of glutamine synthetase in selected areas of tilapia stomach and intestine are significantly (two- to fourfold) increased after a 5-day treatment with an intraperitoneal cortisol deposit. Cortisol also increases glutamine synthetase activity in tilapia liver, white and red muscle, while activities in brain remain unaffected. We cloned and sequenced the predominant transcript of tilapia stomach glutamine synthetase (about 1.9 kb), encoding a 371-amino acid peptide. The open reading frame shows considerable identity with glutamine synthetase in toadfish (92% at peptide level, 87% at nucleotide level), but possesses a longer 3'-untranslated region than the toadfish. The tilapia glutamine synthetase mRNA contains a remnant of a putative mitochondrial leader sequence, but without a conserved second site for initiation of translation. We also find evidence for additional transcripts of glutamine synthetase in tilapia, suggesting multiple genes. Finally, we present evidence for similar abundance of glutamine synthetase transcripts in all regions of rockfish intestine. The physiological significance of the presence of glutamine synthetase in teleostean intestine is discussed.