Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UNIPROT:P01275 (glucagon)
26,492 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Phloridzin-insensitive D-glucose uptake into enterocytes isolated sequentially from along the crypt-villus axis showed the majority of transport activity to reside in cells from the upper third of the villus. In contrast, total postnuclear glucose transporter 2 (GLUT2) protein content of the cells was high even close to the crypt and was almost constant for the upper 80% of the villi. A 4 h lumenal perfusion in vivo with 100 mM D-glucose prior to harvesting the enterocytes produced a 2- to 3-fold increase in phloridzin-insensitive D-glucose uptake which extended down 70% of the villus. Vascular infusion in vivo with either 800 pM gastric inhibitory polypeptide (GIP) or glucagon-like peptide-2 (GLP-2) prior to harvesting enterocytes produced the same response as lumenal glucose, while glucagon like peptide-1 (GLP-1) had no effect. Inclusion of 30 microM brefeldin A (BFA), an inhibitor of protein trafficking, in the lumenal perfusate produced a small, but not significant, increase in the control uptake profile along the villus in isolated enterocytes. However, BFA significantly reduced the upregulation induced by lumenal glucose and vascular GIP and blocked the stimulation produced by vascular GLP-2. Biotinylation of surface proteins and isolation with protein A indicated that there was no change in the membrane abundance of GLUT2 after GLP-2 treatment. These results are discussed in relation to the role of gastrointestinal peptide hormones in controlling intestinal hexose transport and the possibility of protein trafficking being involved in mediating the upregulation of GLUT2 activity in the enterocyte basolateral membrane.
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PMID:Basolateral D-glucose transport activity along the crypt-villus axis in rat jejunum and upregulation induced by gastric inhibitory peptide and glucagon-like peptide-2. 979 81

Glucose, that Claude Bernard has demonstrated in 1850 to be synthesized and secreted by the liver, is an important regulator of gene transcription in all types of organisms. In vertebrates, it especially regulates transcription of metabolic genes in the liver and fat tissue, activating genes encoding enzymes and regulators of the glycolytic and lipogenic pathways. Working with the L-type pyruvate kinase gene we have found that in hepatocytes glucose-dependent gene regulation requires: Presence of the GLUT2 glucose transporter, necessary to allow for an effective depletion in glucose 6-phosphate (G-6P) under gluconeogenic conditions. Phosphorylation of glucose to G-6P assured either by insulin-dependent glucokinase or by another hexokinase isoform. Most likely, entry of G-6P in the pentose phosphate pathway. Modulation of a kinase/phosphatase cascade, in particular inhibition of the 5'AMP-activated protein kinase. Signalling through a glucose response complex assembled onto a glucose-response element (GIRE) located in regulatory regions of glucose-responsive genes. The activators USF belong to the complex, and are required for a normal gene activation by glucose, as evidenced from the phenotype of knock-out mice deficient in USF. The study of USF-defective knock-out mice suggest that USF could be involved in nutritional activation of a whole class of genes regulated by glucose, and not by insulin itself. In particular, lipogenic genes and the ob gene, encoding the leptin satiety hormone, are abnormally responsive to diet in USF-/- mice. The transactivation potential of USF would be modulated by a glucose sensor system implying the COUP-TFII transcription inhibitor. The main role of insulin in the glucose response of genes like the L-PK gene is to induce the glucokinase gene. Glucagon, through cyclic AMP, inhibits L-PK gene transcription mainly through activation of PKA. The PKA catalytic subunit could act by phosphorylating member(s) of the glucose-response complex, or of contiguous transcription factor, e.g. HNF4. In conclusion, through a pluridisciplinary approach ranging from Claude Bernard-derived biology to modern molecular biology, important progress have been made during the last years on the mechanisms of the regulation of gene transcription by glucose in vertebrates.
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PMID:[From the glycogenic function of the liver to gene regulation by glucose]. 987 95

The mouse ob gene encodes leptin, an adipocyte hormone that regulates body weight and energy expenditure. Leptin has potent metabolic effects on fat and glucose metabolism. A mutation of the ob gene results in mice with severe hereditary obesity and diabetes that can be corrected by treatment with the hormone. In lean mice, leptin acutely increases glucose metabolism in an insulin-independent manner, which could account, at least in part, for some of the antidiabetic effect of the hormone. To investigate further the acute effect of leptin on glucose metabolism in insulin-resistant obese diabetic mice, leptin (40 ng x g(-1) x h(-1)) was administered intravenously for 6 h in C57Bl/6J ob/ob mice. Leptin increased glucose turnover and stimulated glucose uptake in brown adipose tissue (BAT), brain, and heart with no increase in heart rate. A slight increase in all splanchnic tissues was also noticed. Conversely, no increase in skeletal muscle or white adipose tissue (WAT) glucose uptake was observed. Plasma insulin concentration increased moderately but neither glucose, glucagon, thyroid hormones, growth hormone, nor IGF-1 levels were different from phosphate-buffered saline-infused C57Bl/6J ob/ob mice. In addition, leptin stimulated hepatic glucose production, which was associated with increased glucose-6-phosphatase activity. Conversely, PEPCK activity was rather diminished. Interestingly, hepatic insulin receptor substrate (IRS)1-associated phosphatidylinositol 3-kinase activity was slightly elevated, but neither the content of glucose transporter GLUT2 nor the phosphorylation state of the insulin receptor and IRS-1 were changed by acute leptin treatment. Hepatic lipid metabolism was not stimulated during the acute leptin infusion, since the content of triglycerides, glycerol, and citrate was unchanged. These findings suggest that in ob/ob mice, the antidiabetic antiobesity effect of leptin could be the result of a profound alteration of glucose metabolism in liver, BAT, heart, and consequently, glucose turnover. Insulin resistance of skeletal muscle and WAT, while not affected by acute leptin treatment, could also be corrected in the long term and account for some of leptin's antidiabetic effects.
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PMID:Acute intravenous leptin infusion increases glucose turnover but not skeletal muscle glucose uptake in ob/ob mice. 1034 14

In this article, we show that glucagon-like peptide 1 (GLP-1) can induce AR42J cells to differentiate into insulin, pancreatic polypeptide, and glucagon-positive cells. In their natural state, these cells, which are derived from a chemically induced pancreatic tumor, possess exocrine and neuroendocrine properties but are negative for islet hormones and their mRNAs. We found that when these cells were exposed to GLP-1 (1 or 10 nmol), a peptide normally released from the gut in response to food and a modulator of insulin release, intracellular cAMP levels were increased, and proliferation of cells was increased for the first 24 h, followed by inhibition. Up to 50% of the cells became positive for islet hormones. The mRNAs for glucose transporter 2 and glucokinase were detected in the GLP-1-treated cells. Insulin was detected by radioimmunoassay (RIA) in the medium of GLP-1-treated cells, and the cells were capable of releasing insulin in a glucose-mediated fashion. Exendin-4, an analog of GLP-1, in some critical experiments performed in a similar manner to GLP-1, with the exception of it being 10-fold more potent. We therefore propose that GLP-1 and exendin-4 are capable of causing pancreatic precursor cells to differentiate into islet cells.
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PMID:Glucagon-like peptide 1 and exendin-4 convert pancreatic AR42J cells into glucagon- and insulin-producing cells. 1058 Apr 24

There has been no method previously to measure both glucose transport and its effect on the various intracellular functions in single, living mammalian cells. A fluorescent derivative of d-glucose, 2-[N-(7-nitrobenz-2-oxa-1, 3-diazol-4-yl)amino]-2-deoxy-d-glucose (2-NBDG), that we have developed has made such measurements possible. COS-1 cells that overexpress the human glucose transporter GLUT2 show significantly greater 2-NBDG uptake than mock transfected cells. Using GLUT2-abundant mouse insulin-secreting clonal MIN6 cells, we found that 2-NBDG was incorporated into the cells in a time- and concentration-dependent manner. The 2-NBDG uptake was inhibited by high concentrations of d-glucose in a dose-dependent manner and also was almost completely inhibited by 10 micrometer cytochalasin B. We then measured both glucose uptake and the intracellular calcium concentration ([Ca(2+)](i)) in single, living pancreatic islet cells. 2-NBDG and fura-2 were used as the tracer of glucose and indicator of intracellular calcium, respectively. All of the cells that showed an increase in [Ca(2+)](i) in response to a high concentration of glucose (16.8 mm) rapidly incorporated significant 2-NBDG. Immunocytochemical examination confirmed these cells to be insulin-positive beta-cells. All of the cells that showed no significant, rapid 2-NBDG uptake lacked such glucose responsiveness of [Ca(2+)](i), indicating that these cells were non-beta-cells such as glucagon-positive alpha-cells. These results show the uptake of glucose causing a concomitant increase of [Ca(2+)](i) in beta-cells. Because 2-NBDG is incorporated into mammalian cells through glucose transporters, it should be useful for the measurement of glucose uptake together with concomitant intracellular activities in many types of single, living mammalian cells.
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PMID:Measurement of glucose uptake and intracellular calcium concentration in single, living pancreatic beta-cells. 1074 91

Glucagon-like peptide-2 (GLP-2) is a 33 amino acid peptide hormone released from the intestinal endocrine cells following nutrient ingestion. GLP-2 exerts trophic effects on the small and large bowel epithelium via stimulation of cell proliferation and inhibition of apoptosis. GLP-2 also upregulates intestinal glucose transporter activity, and reduces gastric emptying and gastric acid secretion. The activity of GLP-2 is regulated in part via renal clearance and cleavage by the aminopeptidase dipeptidyl peptidase IV. In experimental models of intestinal disease, GLP-2 reversed parenteral nutrition-induced mucosal atrophy and accelerated the process of endogenous intestinal adaptation in rats following major small bowel resection. GLP-2 also markedly attenuated intestinal injury and weight loss in mice with chemically-induced colitis, and significantly reduced mortality, bacterial infection and intestinal mucosal damage in mice with indomethacin-induced enteritis. The actions of GLP-2 are transduced by a recently cloned glucagon-like peptide-2 receptor (GLP-2R) that represents a new member of the G protein-coupled receptor superfamily. The GLP-2R is expressed in a highly tissue-specific manner predominantly in the gastrointestinal tract and GLP-2R activation is coupled to increased adenylate cyclase activity. The available evidence suggests that the biological properties of GLP-2 merit careful therapeutic assessment in selected human diseases characterized by injury and defective repair of the gastrointestinal epithelium.
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PMID:New frontiers in the biology of GLP-2. 1082 89

To elucidate the function of pancreas duodenal homeobox 1 (PDX-1; insulin promoter factor 1/somatostatin transcription factor 1/islet duodenum homeobox 1/insulin upstream factor 1) in differentiated beta-cells of adult animals we generated transgenic mice using the Tet-On system. Inducible expression of an antisense RNA should down-regulate the PDX-1 protein. The selective and continuous inhibition of PDX-1 gene expression should impair the expression of PDX-1 dependent beta-cell specific genes. A gene switch such as the Tet-On system provides a powerful tool to analyze eukaryotic gene expression and function in transgenic mice. The original Tet system contained two transcriptional units, transactivator and target of control, on two plasmids. We combined the two transcriptional units on a single DNA molecule. The transactivator was placed under control of the mouse insulin promoter. The tet responsive element, driving the gene of interest, was inserted further down-stream into the same vector. The tet regulatory system in this approach permitted a tissue-specific and a doxycycline-inducible control of PDX-1 expression in transgenic mice. The expression of glucose transporter 2 and glucokinase was markedly reduced in dox-treated transgenic mice. In contrast, the number of insulin- and amylin-expressing cells was only slightly decreased, whereas the expression of glucagon was increased distinctly in islets of these mice. Furthermore, the exposure to doxycycline resulted in a progressive impairment of glucose tolerance. The characterization of our transgenic mouse model demonstrates the suitability of the Tet-On system for analyzing physiological consequences emerging from a stepwise decrease in a given protein. Using this system we confirmed the essential role of PDX-1 in pancreatic islets and demonstrated that an antisense-mediated PDX-1 deficiency provokes a beta-cell dysfunction.
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PMID:The Tet-On system in transgenic mice: inhibition of the mouse pdx-1 gene activity by antisense RNA expression in pancreatic beta-cells. 1148 27

The winged helix transcription factors, hepatocyte nuclear factors 3alpha, -beta, and -gamma (HNF-3, encoded by the Foxa1, -a2, and -a3 genes, respectively), are expressed early in embryonic endoderm and play important roles in the regulation of gene expression in liver and pancreas. Foxa1 has been shown to be required for glucagon secretion in the pancreas, whereas Foxa2 is critical for the regulation of insulin secretion in pancreatic beta-cells. Here we address the role of Foxa3 in the maintenance of glucose homeostasis. Mice homozygous for a null mutation in Foxa3 appear normal under fed conditions. However, when fasted, Foxa3(-/-) mice have a significantly lower blood glucose compared with control mice. The fasting hypoglycemia in Foxa3(-/-) mice could not be attributed to defects in pancreatic hormone secretion, ketone production, or hepatic glycogen breakdown. Surprisingly, mRNA levels for several gluconeogenic enzymes were up-regulated appropriately in fasted Foxa3(-/-) mice, despite the fact that the corresponding genes had been shown to be activated by FOXA proteins in vitro. However, the mRNA for the plasma membrane glucose transporter GLUT2 was decreased by 64% in the fasted and 93% in the fed state, suggesting that efflux of newly synthesized glucose is limiting in Foxa3(-/-) hepatocytes. Thus, Foxa3 is the dominating transcriptional regulator of GLUT2 expression in hepatocytes in vivo. In addition, we investigated the hepatic transcription factor network in Foxa3(-/-) mice and found that the normal activation of HNF-4alpha, HNF-1alpha, and PGC-1 induced by fasting is attenuated in mice lacking Foxa3.
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PMID:Foxa3 (hepatocyte nuclear factor 3gamma ) is required for the regulation of hepatic GLUT2 expression and the maintenance of glucose homeostasis during a prolonged fast. 1154 10

Functional heterogeneity of pancreatic islets was systematically analyzed for the first time using freshly isolated single rat pancreatic islets. First, 60 islets were sequentially exposed to 3, 9.4, 15.6, and 24.1 mM glucose for 30 min each in incubation experiments: 36 (60%) responded in a concentration-dependent and 19 (32%) in an all-or-none manner, and 5 (8%) islets did not respond to high glucose. As a group, the larger the islet, the higher the beta cell glucose sensitivity. However, glucose-stimulated elevation of [Ca2+]i in the beta cell. insulin/glucagon ratio in the islet, and expression of glucose transporter 2, glucokinase, and pancreatic duodenal homeobox factor-1 in the beta cell were not significantly related to islet size. Second, 50 islets were stimulated with 16.7 mM glucose in perifusion. A biphasic insulin release was found in 39 (78%), and no or little first phase response in 11 (22%) islets, irrespective of the islet size. Nevertheless, when the response was plotted as a group, it was clearly biphasic. Islet size, insulin content and the amount of insulin release were positively correlated with each other. In conclusion, there are size-related and size-unrelated functional diversity among pancreatic islets. The reason for such heterogeneity remained to be determined.
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PMID:Size-related and size-unrelated functional heterogeneity among pancreatic islets. 1171 66

Complete lack of transcription factor PDX-1 leads to pancreatic agenesis, whereas heterozygosity for PDX-1 mutations has been recently noted in some individuals with maturity-onset diabetes of the young (MODY) and in some individuals with type 2 diabetes. To determine how alterations in PDX-1 affect islet function, we examined insulin secretion and islet physiology in mice with one PDX-1 allele inactivated. PDX-1(+/-) mice had a normal fasting blood glucose and pancreatic insulin content but had impaired glucose tolerance and secreted less insulin during glucose tolerance testing. The expression of PDX-1 and glucose transporter 2 in islets from PDX-1(+/-) mice was reduced to 68 and 55%, respectively, whereas glucokinase expression was not significantly altered. NAD(P)H generation in response to glucose was reduced by 30% in PDX-1(+/-) mice. The in situ perfused pancreas of PDX-1(+/-) mice secreted about 45% less insulin when stimulated with 16.7 mm glucose. The K(m) for insulin release was similar in wild type and PDX-1(+/-) mice. Insulin secretion in response to 20 mm arginine was unchanged; the response to 10 nm glucagon-like peptide-1 was slightly increased. However, insulin secretory responses to 10 mm 2-ketoisocaproate and 20 mm KCl were significantly reduced (by 61 and 66%, respectively). These results indicate that a modest reduction in PDX-1 impairs several events in glucose-stimulated insulin secretion (such as NAD(P)H generation, mitochondrial function, and/or mobilization of intracellular Ca(2+)) and that PDX-1 is important for normal function of adult pancreatic islets.
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PMID:Reduction in pancreatic transcription factor PDX-1 impairs glucose-stimulated insulin secretion. 1178 23


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