Project description:By directly comparing gene expression in wild type, domestic, and GH transgenic strains of salmon, we have found that domestication and GH transgenesis are modifying similar genetic pathways. Genes in many different physiological pathways show modified expression in domestic and GH transgenic strains relative to wild-type, but effects are strongly correlated. Genes specifically involved in growth regulation (IGF-I, GHR, IGF-II, THR) are also concordantly regulated in domestic and transgenic fish, and both strains show elevated levels of circulating IGF-I. Muscle expression of GH in nontransgenic strains was found to be elevated in domesticated fish relative to wild type, providing a possible mechanism for growth enhancement. These data have implications for genetic improvement of existing domesticated species as well as regulation of emerging transgenic strains. Keywords: Expression profiling by array Microarray analyses were performed on four or five individual fish per group of wild type, domesticated, and GH transgenic salmon hybridized (one slide per individual) against a common wild-type RNA pool.

Project description:By directly comparing gene expression in wild type, domestic, and GH transgenic strains of salmon, we have found that domestication and GH transgenesis are modifying similar genetic pathways. Genes in many different physiological pathways show modified expression in domestic and GH transgenic strains relative to wild-type, but effects are strongly correlated. Genes specifically involved in growth regulation (IGF-I, GHR, IGF-II, THR) are also concordantly regulated in domestic and transgenic fish, and both strains show elevated levels of circulating IGF-I. Muscle expression of GH in nontransgenic strains was found to be elevated in domesticated fish relative to wild type, providing a possible mechanism for growth enhancement. These data have implications for genetic improvement of existing domesticated species as well as regulation of emerging transgenic strains. Keywords: Expression profiling by array

Project description:Although studies have established that exogenous growth hormone (GH) treatment stimulates growth in fish, its effects on target tissue gene expression are not well characterized. We assessed the effects Posilac® (Monsanto Co., St. Louis, MO), a recombinant bovine somatotropin, on tissue transcript levels. Transcript abundance was measure in liver and muscle using the GRASP 16 K cDNA microarray. A selection of the genes identified as altered with the microarray, and also transcripts for insulin-like growth factors, growth hormone receptors (GHR) and myostatins were measured by realtime PCR in the liver, muscle, brain, kidney, intestine, stomach, gill and heart. In general, transcripts identified as differentially regulated in the muscle on the microarray showed similar direction of expression in the other non-hepatic tissues. Rainbow trout were selected from two high growth rate and two low growth rate families. A total of 113 and 67 transcripts were identified by microarray as differentially expressed with GH treatment across growth rate for muscle and liver respectively. The largest proportion of the transcripts represented novel transcripts, followed by immune and metabolism related genes. The immune related genes were primarily modulated in the liver and indicate activation of a non-specific immune response. The metabolic genes include lipid metabolism, oxidative phosphorylation and one carbon metabolism pathway transcripts. Most notable among the growth axis genes measured by realtime PCR were increases in GHR1 and-2 transcript in liver and muscle. Our results indicate that short-term GH treatment activates the immune system, shifts the metabolic sectors and modulates growth regulating genes. Keywords: Growth Hormone Injection Muscle and Liver Gene Expression Rainbow trout (hatched March 2005) selected for extreme growth rate were obtained from NCCCWA brood stock. Families were selected based on body weight at 7 months of age and thermal growth coefficient for the final month of growth. The two high growth families used in the study were in the top 2% in terms of growth rate, and the low growth families were in the lowest 10% for growth rate. Fish acclimated to the new tanks for two weeks prior to initiation of the treatments. Fish from each family were randomly selected to receive one of three treatments: 1) Posilac® injection (120 mg/kg BW, n = 4 per family); 2) vehicle injection (n = 4 per family); or 3) untouched controls (n = 2 per family). We had determined there was no effect to growth or the GH/IGF-I axis in the vehicle treated fish, and therefore, all of the microarray hybridizations were made between the GH and vehicle injected groups. This study included a total of 16 two-channel arrays designed for the direct comparison of GH treatment levels. That is, for each of the four groups, 1) High Growth Rate Liver; 2) Low Growth Rate Liver; 3) High Growth Rate Muscle; and 4) Low Growth Rate Muscle, four slide were hybridizes using individual RNA samples from individual fish. RNA isolation from each tissue/organ sample was handled separately (without pooling) with the purpose of using biological replications. We hybridized two slides with the GH cDNA labeled with Alexa 555 and vehicle cDNA labeled with Alexa 647; and two slides, using unique RNA samples, for the with GH cDNA labeled with Alexa 647 and tissue from the vehicle injected group labeled with Alexa 647 within each tissue and growth rate. Sixteen slides were used in the current study representing 32 individual tissue samples, meaning a total of four biological replicates for each treatment group.

Project description:Muscle is a target of growth hormone (GH) action and a major contributor to whole body metabolism. Little is known about how GH regulates metabolic process in muscle or the extent to which muscle contributes to changes in whole body substrate metabolism during GH treatment. To identify GH-responsive genes that regulate substrate metabolism in muscle, we studied six hypopituitary men who underwent whole body metabolic measurement and muscle biopsies before and after two weeks of GH treatment (0.5mg/day). Transcript profiles of four subjects were analysed using Affymetrix GeneChips. Serum insulin-like growth factor I (IGF-I), procollagens I and III were measured by RIA. GH increased serum IGF-I, procollagens I and III, enhanced whole body lipid oxidation, reduced carbohydrate oxidation, and stimulated protein synthesis. It induced gene expression of IGF-I and collagens in muscle. GH reduced expression of several enzymes regulating lipid oxidation and energy production. It reduced calpain 3, increased ribosomal protein L38 expression, and displayed mixed effects on genes encoding myofibrillar proteins. It increased expression of circadian gene CLOCK, and reduced that of PERIOD. In summary, GH exerted concordant effects on muscle expression and blood levels of IGF-I and collagens. It induced changes in genes regulating protein metabolism in parallel with a whole body anabolic effect. The discordance between muscle gene expression profiles and metabolic responses suggests that muscle is unlikely to contribute to GH-induced stimulation of whole body energy and lipid metabolism. GH may regulate circadian function in muscle by modulating circadian gene expression with possible metabolic consequences.

Project description:This study, using a growth hormone (GH)-deficient dwarf animal model and peripheral GH replacement, investigated the effects of circulating IGF-1 during adolescence on IGF-1 levels in the brain. Our results demonstrated that hippocampal IGF-1 protein concentrations during adolescence are highly regulated by circulating IGF-1, which were reduced by GH deficiency and restored by systematic GH replacement. In contrast, IGF-1 levels in the CSF were decreased by GH deficiency but not restored by GH replacement. Furthermore, analysis of gene expression using microarrays and RT-PCR indicated that circulating IGF-1 levels did not modify the transcription of IGF-1 or its receptor in the hippocampus but did regulate genes that are involved in microvascular structure and function, brain development, and synaptic plasticity, which potentially support brain structures involved in cognitive function during this important developmental period.

Project description:This study, using a growth hormone (GH)-deficient dwarf animal model and peripheral GH replacement, investigated the effects of circulating IGF-1 during adolescence on IGF-1 levels in the brain. Our results demonstrated that hippocampal IGF-1 protein concentrations during adolescence are highly regulated by circulating IGF-1, which were reduced by GH deficiency and restored by systematic GH replacement. In contrast, IGF-1 levels in the CSF were decreased by GH deficiency but not restored by GH replacement. Furthermore, analysis of gene expression using microarrays and RT-PCR indicated that circulating IGF-1 levels did not modify the transcription of IGF-1 or its receptor in the hippocampus but did regulate genes that are involved in microvascular structure and function, brain development, and synaptic plasticity, which potentially support brain structures involved in cognitive function during this important developmental period. GH-deficient dwarf (dw/dw) and heterozygous (HZ) rats were identified at postnatal day 33-34. Starting from d35, dw/dw rats received subcutaneous injection of either 300µg GH (dw/dw+GH) or saline (dw/dw+sal) for 7d or 30d. HZ animals received saline for the same periods as controls. Animals (n=4/group for each time point) were sacrificed, the hippocampi were dissected, and total RNA were isolated for subsequent transcriptomic profiling.

Project description:Training at sustainable swimming speeds can produce changes in fish skeletal muscle that are important for aquaculture due to their growth-potentiating effects. Such changes may be even more relevant when fish are fed diets containing an increasing proportion of carbohydrates as an energy source. We evaluated the effects of moderate-intensity sustained swimming on the transcriptomic response of red and white muscle in rainbow trout fed a carbohydrate-rich diet using microarray and qPCR. Analysis of the red and white muscle transcriptome revealed significant changes in the expression of a large number of genes (395 and 597, respectively), with a total of 218 differentially expressed genes (DEGs) common for both muscles. A large number of the genes involved in glucose use and energy generation, contraction, development, synthesis and catabolism of proteins were up-regulated in red and white muscle. Additionally, DEGs in both muscles were involved in processes of defense response and apoptosis. Skeletal muscle contraction activates a transcriptional program required for the successful adaptation of both muscles to the changing demands imposed by swimming conditions. Future studies should further clarify the mechanisms involved in the adaptation of both tissues to exercise and assess possible benefits of such conditions for cultured fish. Total RNA from pooled red and white skeletal muscle samples of individual rainbow trout from each group (resting fish, n=8; swimming fish, n=8) was labeled with Cy3-dUTP and Cy5-dUTP (GE Healthcare, Barcelona, Spain). We used a dye swap experimental design and each cDNA from a pooled RNA sample was hybridized to two microarrays. For the first slide, cDNAs from resting and swimming fish were labeled with Cy5 and Cy3, respectively, and for the second array dye assignment was reversed. Therefore, samples from individual fish within each group were pooled and expression values shown represent the means of 6 M-CM-^W 2 = 12 technical replicates. A total of four slides were used in this study

Project description:The incidence of pre-diabetes (PD) and Type-2 Diabetes Mellitus (T2D) is a worldwide epidemic. African American (AA) individuals are disproportionately more likely to become diabetic than other ethnic groups. Over the long-term, metabolic complications related to diabetes result in significant alterations in growth hormone (GH) and insulin-like growth factor-1 (IGF-1). Considering the limited exercise-related studies in the area of gene expression changes with disease progression, the objective of this study was to examine differences in exercise-induced gene expression related to the GH and IGF-1 pathways in peripheral blood mononuclear cells (PBMCs) of healthy (CON) and PD AA individuals. Design: Ten subjects [5 PD (age=35±9.3 yr, BMI=32.1±4.0, FBG=101.8±1.3 mg/dl) and 5 CON (age=31±9.4 yr, BMI=29.4±5.2, FBG=82.8±9.7 mg/dl)] had blood drawn for RNA isolation prior to exercise (Pre), immediately following acute moderate intensity exercise on a treadmill (Post-1), 6-hours post (Post-6), and 24-hours post (Post-24). Isolation of mRNA from PBMCs was performed using ficoll separation, while the profiling of mRNA expression was performed using beadchip arrays that were scanned and analyzed by a gene expression module. Scan results were statistically analyzed for a specific list of genes related to GH and IGF-1. GH and IGF-1 protein levels were also assessed in each sample. To address issues of normality, all GH and IGF-1 data were log-transformed prior to analysis. Statistical significance was set at p<0.05. Results: Group differences for GH2 variant 2 (p=0.070) and GH2 variant 3 (p=0.059) were coupled with significant alterations in IGF-1 mRNA over time (p=0.024). A significant interaction between group and time was observed for GHRH mRNA (p=0.008). No group differences were observed in GH AUC (p=0.649), ∆GH (p=0.331), GHrec (p=0.294), or IGF-1 AUC (p=0.865), representing a similar exercise-induced GH and IGF-1 response for both groups. Conclusions: Analysis of GH and IGF-1 related-gene expression indicates that mild elevations in fasting blood glucose and exercise-induced alterations in gene expression are impacted by the prediabetic state.

Project description:We generated h-hepatocyte chimeric mice with livers that were predominantly repopulated with h-hepatocytes in a h-growth hormone (GH)-deficient state. Using microarray profiles, comparison between h-hepatocytes from h-GH-treated and untreated mice identified 14 GH-up-regulated and four GH-down-regulated genes, including IGF-1, SOCS2, NNMT, IGFLS, P4AH1, SLC16A1, and SRD5A1, and FADS1 and AKR1B10, respectively.

Project description:Treatment with insulin-like growth factor-I (IGF-I) during feed deprivation attenuates the weight loss response in both mammals and fish, therefore the reduction in plasma IGF-I concentrations during fasting likely serves as a signal that contributes to the catabolic response. To better understand the physiological mechanisms responsible for this effect rainbow trout were administered IGF-I during a 2 wk period of feed deprivation and changes in gene expression in white muscle were determined using microarray analysis. Weight loss was reduced by 15% (P<0.05) in IGF-I treated fish. A total of 440 transcripts were identified as differentially regulated (P<0.05) between saline and IGF-I treated fish. Genes related to protein degradation were down-regulated and included protease and peptidase genes and genes involved in ubiquitin-proteasome and cathepsin-mediated proteolytic pathways. IGF-I increased expression of myosin binding protein H and coronin-1C, while decreasing expression of other myofibrillar and cytoskeleton-associated genes like troponin-C and parvalbumin-2. Polyadenylate-binding protein 2, a transcription factor that positively regulates myoD and myogenin expression, was upregulated with IGF-I treatment. Additional genes that were differentially regulated are associated with lipid and carbohydrate metabolism, mitochondrial biogenesis and electron transport, gene transcription, signal transduction and regulation of apoptosis. In summary, these data suggest that IGF-I plays a central role in regulating protein degradation, especially via the ubiquitin-proteasomal pathway, and that reductions in protein degradation and the subsequent effects on other physiological systems are largely responsible for the IGF-I-induced reduction in weight loss. Eight approximately 1-year old full-sibling rainbow trout families were housed in individual tanks, according to family, at the National Center for Cool and Cold Water. Each fish was pit-tagged at 7-months of age. At the beginning of the study, fish were anesthetized with tricaine methanesulfonate (MS-222), weighed, and an osmotic pump was surgically inserted into the peritoneal cavity of each fish (n=4 fish/family/treatment, N=16 fish). The osmotic pump contained either recombinant human IGF-I, which released hormone at 25 ug/kg/day, or saline, which was the vehicle used to resuspend IGF-I. Feed was withheld 2-days prior to surgery and for the experimental 2 week period. Fish were harvested using as overdose of MS-222, weighed, and white muscle samples were removed, frozen in liquid N, and stored at -80 C until analysis. Muscle RNA was isolated from muscle of the two families that exhibited the greatest difference in weight loss between IGF-I and saline treatments; families 64 and 107. Hybridizations were performed using a dye-swap design with an IGF-I and saline treated fish within the same family, therefore a total of 16 slides were hybridized using Alexa 647 and Alexa 555 dyes.