Project description:Transcriptional profiling of rainbow trout muscle cells comparing muscle cells from small fish with muscle cells from large fish at two time periods.

Project description:Transcriptional profiling of rainbow trout liver and muscle cells comparing small fish with large fish within a population of neomale offspring.

Project description:Rainbow trout (Oncorhynchus mykiss) is a typical cold-water fish, the development of rainbow trout aquaculture was severely hampered via the high temperature in summer. Understanding the regulatory mechanism of rainbow trout response to chronic heat stress can provide a theoretical basis for formulating measures to relieve heat stress. In the study, changes in the biochemical parameters revealed that a strong stress response occurred in rainbow trout at 24 °C, the organisms stress defense system was activated, and the immune system was also affected. Proteome of rainbow trout liver tissues under heat stress (24 °C) and control conditions (18 °C) were performed using DIA/SWATH. A total of 390 DEPs were identified by strict threshold (q-value <0.05 and fold changes >1.5), among them 175 were up-regulated and 225 were down-regulated. Some proteins related to HSP, metabolism and immunity were identified. GO analysis showed that some proteins that were highly induced to express at high temperature were involved in the regulation of cell homeostasis, metabolism, adaptive stress and stimulation. KEGG analysis shows that some pathways play an important role in the regulation of heat stress, such as metabolic pathway, protein processing in endoplasmic reticulum pathway, PPAR signaling pathway and complement and coagulation cascades pathway, etc. PPI network analysis shows HSP90b1 and C3 maybe cooperative to protect the integrity of cell membrane function under heat stress. Our finding provide a comprehensive review of protein expression of rainbow trout liver under heat stress, which helps to formulate strategies for rainbow trout to relieve heat stress during high temperature in summer.

Project description:Transcriptional profiling of rainbow trout muscle cells comparing muscle cells from small fish with muscle cells from large fish at two time periods. Two-condition experiment, small vs. large-fish muscle cells. Sept. and Dec. spawning fish. Biological replicates: 4 small replicates, 4 large replicates for each time period.

Project description:Successful production of aquaculture species depends on efficient growth with low susceptibility to disease. Therefore, selection programs have focused on rapid growth combined with disease resistance. However, chronic immune stimulation diminishes muscle growth (a syndrome referred to as cachexia), and decreases growth efficiency in production animals, including rainbow trout. In mammals, recent results show that increased levels of pro-inflammatory cytokines, such as those seen during an immune assault, specifically target myosin and MyoD and inhibit muscle growth. This suggests that increased disease resistance in fish, a desired trait for production, may actually decrease the growth of muscle, the main aquacultural commodity. To test this possibility, a rainbow trout model of cachexia was developed and characterized. A six-week study was conducted in which rainbow trout were chronically immune stimulated by repeated injections of LPS. Growth indices were monitored, and whole body and muscle proximate analyses, real-time PCR, and immunohistochemistry were conducted to examine the resulting cachectic phenotype. Muscle ratio was decreased in fish chronically immunostimulated, however expression levels of MyoD2 and myosin were not decreased compared to fish that were not immunostimulated, indicating that while muscle accretion was altered, the mechanism by which it occurred was somewhat different than that characterized in mammals. Microarray analysis was used to compare gene expression in fish that had been chronically immunostimulated versus those that had not to identify possible alternative mechanisms of cachexia in fish. Keywords: muscle, cachexia, rainbow trout, chronic immune stimulation

Project description:Transcriptional profiling of rainbow trout liver and muscle cells comparing small fish with large fish within a population of neomale offspring. Small vs. large-fish liver and muscle cells from neomale offspring. Biological replicates: 4 small replicates, 4 large replicates.

Project description:The objective of this study was to identify metabolic regulatory mechanisms affected by choline availability in rainbow trout (Oncorhynchus mykiss) broodstock diets associated with increased offspring growth performance. Three customized diets were formulated to have different levels of choline: (a) 0% choline supplementation (Low Choline: 2065 ppm choline), (b) 0.6% choline supplementation (Medium Choline: 5657 ppm choline), and (c) 1.2% choline supplementation (High Choline: 9248 ppm choline). Six all-female rainbow trout families were fed experimental diets beginning 18 months post-hatch until spawning; their offspring were fed a commercial diet. Experimental broodstock diet did not affect overall choline, fatty acid, or amino acid content in the oocytes (p > 0.05), apart from tyrosine (p ≤ 0.05). Offspring body weights from the High and Low Choline diets did not differ from those in the Medium Choline diet (p > 0.05); however, family-by-diet and sire-by-diet interactions on offspring growth were detected (p ≤ 0.05). The High Choline diet did not improve growth performance in the six broodstock families at final harvest (520-days post-hatch, or dph). Numerous genes associated with muscle development and lipid metabolism were identified, including myosin, troponin C, and fatty acid binding proteins, which were associated with key signaling pathways of lipid metabolism, muscle cell development, muscle cell proliferation, and muscle cell differentiation. These findings indicate that supplementing broodstock diets with choline does regulate expression of genes related to growth and nutrient partitioning but does not lead to growth benefits in rainbow trout families selected for disease resistance.

Project description:Short-term growth hormone treatment on the liver and muscle transcriptome in rainbow trout (Oncorhynchus mykiss)

Project description:Dose-dependent effects of TCDD in juvenile rainbow trout

Project description:Transcriptional profiling of rainbow trout liver cells comparing liver cells from small fish with liver cells from large fish at two time periods.