2011
DOI: 10.1007/s00360-011-0636-5
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Glucose and lipid metabolism in the pancreas of rainbow trout is regulated at the molecular level by nutritional status and carbohydrate intake

Abstract: Glucose and lipid metabolism in pancreatic islet organs is poorly characterized. In the present study, using as a model the carnivorous rainbow trout, a glucose-intolerant fish, we assessed mRNA expression levels of several genes involved in glucose and lipid metabolism (including ATP-citrate lyase; carnitine palmitoyltransferase-1 isoforms, CPT; the mitochondrial isoform of the phosphoenolpyrutave carboxykinase, mPEPCK and pyruvate kinase, PK) and glucosensing (glucose transporter type 2, Glut2; glucokinase, … Show more

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Cited by 18 publications
(15 citation statements)
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“…Although few, some genes involved in glycolysis, lipogenesis and energy production pathways were enhanced: GK and FAS (by stimulus 1), G6PDH (by stimulus 2) and 6PFK-L, PK and CS genes (by stimulus 3). These data are similar to the postprandial induction of gene expression observed in rainbow trout, gilthead seabream and zebrafish, after a high carbohydrate intake (Enes et al, 2008b;Kamalam et al, 2012;Meton et al, 2004;Panserat et al, 2000;Polakof et al, 2012b;Seiliez et al, 2013), comparable to what occurs in mammals (Kersten, 2001;Pilkis and Granner, 1992;Yamada and Noguchi, 1999). Moreover, a similar short-term regulation for higher expression of GK and HK1 glycolytic enzymes was observed in rainbow trout and zebrafish fed at first-feeding with a high level (50 to 65%) of dietary carbohydrates (Fang et al, 2014;Geurden et al, 2007Geurden et al, , 2014.…”
Section: Discussionsupporting
confidence: 88%
“…Although few, some genes involved in glycolysis, lipogenesis and energy production pathways were enhanced: GK and FAS (by stimulus 1), G6PDH (by stimulus 2) and 6PFK-L, PK and CS genes (by stimulus 3). These data are similar to the postprandial induction of gene expression observed in rainbow trout, gilthead seabream and zebrafish, after a high carbohydrate intake (Enes et al, 2008b;Kamalam et al, 2012;Meton et al, 2004;Panserat et al, 2000;Polakof et al, 2012b;Seiliez et al, 2013), comparable to what occurs in mammals (Kersten, 2001;Pilkis and Granner, 1992;Yamada and Noguchi, 1999). Moreover, a similar short-term regulation for higher expression of GK and HK1 glycolytic enzymes was observed in rainbow trout and zebrafish fed at first-feeding with a high level (50 to 65%) of dietary carbohydrates (Fang et al, 2014;Geurden et al, 2007Geurden et al, , 2014.…”
Section: Discussionsupporting
confidence: 88%
“…These results are consistent with previous demonstrations in rainbow trout (60,61,75,82), showing that high-carbohydrate diets induced hyperglycemia and reduced plasma AA levels. These plasma parameters clearly confirmed the efficiency of controlled feeding method.…”
Section: High Carbohydrate Intake Induced Hyperglycemia Irrespective supporting
confidence: 93%
“…Interestingly, rapamycin also enhanced plasma FAA levels 8 h after controlled feeding. This elevated FAA level was negatively associated with the reduced glycemia, which is consistent with previous observations in trout (60,61,75,82). Given that AAs, especially gluconeogenic AAs, can promote glucose production through hepatic gluconeogenic pathway (5, 15), we presume that both the elevated FAA levels and the reduced glycemia by rapamycin may be related to the suppressed hepatic gluconeogenesis, as previously demonstrated (16), implicating the importance of hepatic gluconeogenesis in modulating glucose homeostasis.…”
Section: High Carbohydrate Intake Induced Hyperglycemia Irrespective supporting
confidence: 92%
“…In mammals, high carbohydrate availability reduces fatty acid oxidation via an increase in plasma insulin and decreased free fatty acid availability [25], [26]. On the contrary, in rainbow trout, regulation of enzymes involved in fatty acid oxidation was not dependent on the carbohydrate content of the diet [16], [27], [28]. Even conversely, glucose treatment was found to stimulate the rate of hepatic lipolysis by increasing the activity of hepatic lipase activity in rainbow trout [29].…”
Section: Introductionmentioning
confidence: 97%