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: UMLS:C0038187 (starvation)
24,951 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The eukaryotic facilitated glucose transporter (GT) is expressed by many cell types, with the notable exception of hepatocytes; however, GT is expressed by several hepatoma cell lines, including the well-differentiated lines Fao, Hep3B, and HepG2. We report on studies carried out to determine the aspect(s) of the transformed phenotype that might be responsible for activating GT expression. Using RNA blot analysis with probes derived from rat GT cDNA, we found that GT was expressed by rat hepatocytes under two conditions (i) in vitro, when isolated hepatocytes were placed in cell culture, and (ii) in vivo, when rats were subjected to starvation for greater than or equal to 2 days. However, GT expression was not an obligatory feature of hepatomas, since two primary hepatocellular carcinomas did not express any GT mRNA. GT expression in hepatocytes was reduced by addition of dimethyl sulfoxide or sodium butyrate to the culture medium. Since these reagents are known to promote differentiation in some cell culture systems, their effect on hepatocytes may be to maintain the GT repression normally observed in vivo. Inclusion or exclusion in the culture medium of several other agents that enhance hepatocyte viability (serum, insulin, corticosteroids, epidermal growth factor, or triiodothyronine) did not affect GT expression. It is unclear whether the two conditions that led to GT expression in hepatocytes are related by a common signaling mechanism. Possibly, both cases involve a "stress" response: in vivo, a normal physiological response to starvation; in vitro, a response to a major alteration in the cellular environment.
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PMID:Evidence for expression of the facilitated glucose transporter in rat hepatocytes. 319 5

Photoaffinity labeling with [3H]cytochalasin B detects two D-glucose-sensitive proteins in the chicken embryo fibroblast (CEF) plasma membrane, which accumulate under conditions of glucose starvation and are probably involved in the glucose transport system (Pessin, J.E., et al. (1982) Proc. Natl. Acad. Sci. U.S. 79, 2286-2290). The two labeled components, designated as peak I (Mr 45,000) and II (Mr 52,000) components, were separated by preparative gel electrophoresis in the presence of sodium dodecyl sulfate. The fractions were digested with S. aureus V8 or papain, and the radioactive products were analyzed by one-dimensional gel electrophoresis. The peptide maps showed that they have different peptide structures. Peptide maps of authentic actin, a possible contaminant of the peak I fractions, were quite different from those of the peak I component. Rous sarcoma virus-transformed CEF have two components similar as to apparent molecular size and peptide maps to those present in glucose-starved cells. The peak I and II components show minimal affinity to agarose-bound Ricinus communis agglutinin which binds the human erythrocyte glucose transporter quite well. The peak II component was more susceptible to proteolysis than the peak I one or the human erythrocyte glucose transporter. However, the peptide maps of the peak II component were similar to those of the human erythrocyte glucose transporter.
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PMID:Separation and proteolytic mapping of the two [3H]cytochalasin B photoaffinity labeled D-glucose-sensitive proteins in the chicken embryo fibroblast plasma membrane. 351 90

The product of the c-myc proto-oncogene (c-Myc) is involved in the control of cell proliferation, differentiation, and apoptosis. It acts as a transcription factor that recognizes the CACGTG motif. This sequence has also been found in the glucose-responsive elements of genes involved in the control of liver glycolysis and lipogenesis. To determine whether c-Myc can regulate hepatic carbohydrate metabolism in vivo, transgenic mice that overexpress c-myc under control of the P-enolpyruvate carboxykinase (PEPCK) gene promoter have been generated. These mice showed a threefold increase in c-Myc protein in liver nuclei. Hepatocytes from transgenic mice were normal and did not acquire the fetal phenotype. However, transgenic mice showed higher levels (threefold) of L-type pyruvate kinase mRNA and enzyme activity than control mice. The increase in pyruvate kinase activity led to a three- to fivefold increase in liver lactate content and a fivefold induction of lactate production by hepatocytes in primary culture. The expression of the 6-phosphofructo-2-kinase gene was also increased in the liver of these transgenic mice. The induction of hepatic glycolysis was related with an increase in the expression (about fourfold) and activity (about threefold) of liver glucokinase, whereas no change was noted in hexokinase-I. This change in glucokinase activity led to an increase in both glucose 6-phosphate and glycogen contents in the liver of transgenic mice. The expression of the liver-specific glucose transporter GLUT2 was also increased in transgenic mice, whereas no change was noted in the mRNA concentration of GLUT1. Furthermore, the changes of liver glucose metabolism led to a marked reduction of blood glucose (25%) and insulin (40%) concentrations in starvation, whereas the fall in both was only 10% in fed mice. Thus, liver glucose metabolism could determine the blood glucose and insulin set points in the transgenic mice. All these results indicated that the increase in c-Myc protein was able to induce liver glucose utilization and accumulation, and suggested that c-Myc transcription factor is involved in the control in vivo of liver carbohydrate metabolism.
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PMID:Evidence from transgenic mice that myc regulates hepatic glycolysis. 764 6

The mutual role of glucose and insulin in the regulation of glucokinase and GLUT2 glucose transporter gene expression in pancreatic B-cells and liver has been studied in vivo in the rat. Glucokinase mRNA was quantified by competitive reverse-transcriptase PCR analysis, and GLUT2 mRNA by Northern-blot analysis in total RNA fractions. As in the liver, glucokinase mRNA decreased by 64% in pancreatic B-cells after starvation for 2 days and was induced 3-fold by short-term treatment (1 h) of the rats with oral glucose (4 g/kg body wt.). In contrast the sulphonylurea compound glibenclamide (0.1 mg/kg body wt.) did not significantly stimulate glucokinase gene expression in pancreatic B-cells. But glibenclamide caused a 4-fold increase of glucokinase mRNA in liver which was abolished by concomitant administration of diazoxide, a drug which antagonizes glibenclamide stimulated insulin secretion. GLUT2 gene expression was decreased by 50% in pancreatic B-cells and liver after starvation of the rats for 2 days. Neither short-term treatment (1 h) with glucose nor glibenclamide resulted in a significant increase of GLUT2 gene expression in pancreatic B-cells and liver. The results suggest that it is glucose which stimulates glucokinase gene expression in pancreatic B-cells whereas the transcriptional regulation of the glucokinase gene in liver is directed by insulin.
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PMID:Effects of glucose refeeding and glibenclamide treatment on glucokinase and GLUT2 gene expression in pancreatic B-cells and liver from rats. 775 56

Oral vanadate administration has been demonstrated to normalize blood glucose levels in ob/ob and db/db mice and streptozotocin (STZ) diabetic rats. The exact mechanism of this vanadate effect is uncertain, since there are no consistent effects on the insulin receptor tyrosine kinase activity or phosphotyrosine phosphatase activity. We have therefore studied the postreceptor actions of vanadate, focusing our attention on the steady-state levels of mRNA of enzymes involved in carbohydrate metabolism. When compared with their lean (ob/+) controls, the livers of ob/ob mice exhibited an approximately 90% reduction in the levels of phosphoenolpyruvate carboxykinase (PEPCK) mRNA and twofold to fivefold higher levels of the mRNAs for glyceraldehyde-3-phosphate dehydrogenase (GAPDH), the "liver beta-cell" glucose transporter (GLUT2), and the proto-oncogene c-myc. Administration of sodium vanadate (0.25 mg/mL) in the drinking water of ob/ob mice over a 45-day period resulted in a near normalization of blood glucose and increased PEPCK mRNA levels more than ninefold. Starvation of the ob/ob mice for 24 to 48 hours also increased PEPCK mRNA levels by fourfold to 15-fold. Vanadate treatment did not alter mRNA levels of any other proteins studied and had no effect on PEPCK mRNA in ob/+ mice. However, 1 to 100 mumol/L vanadate produced a concentration-dependent increase in PEPCK mRNA levels in an H35 hepatoma cell line, an effect opposite to the suppression of PEPCK mRNA produced by insulin. In summary, hyperglycemia in the ob/ob mouse is characterized by decreased expression of PEPCK and increased expression of GAPDH mRNA.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Vanadate normalizes hyperglycemia and phosphoenolpyruvate carboxykinase mRNA levels in ob/ob mice. 796 88

The effect of insulinopenic diabetes on the expression of glucose transporters in the small intestine was investigated. Enterocytes were sequentially isolated from jejunum and ileum of normal fed rats, streptozotocin-diabetic rats, and diabetic rats treated with insulin. Facilitative glucose transporter (GLUT) 2, GLUT5, and sodium-dependent glucose transporter 1 protein content was increased from 1.5- to 6-fold in enterocytes isolated from diabetic animals in both jejunum and ileum. Insulin was able to reverse the increase in transporter protein expression seen after induction of diabetes. There was a four- to eightfold increase in the amount of enterocyte glucose transporter mRNA after diabetes with greater changes in sodium-dependent glucose transporter 1 and GLUT2 than in GLUT5 levels. In situ hybridization showed that after the induction of diabetes there was new hybridization in lower villus and crypt enterocytes that was reversed by insulin treatment. Thus, the increase in total hexose transport caused by diabetes is due to a premature expression of hexose transporters by enterocytes along the crypt-villus axis, causing a cumulative increase in enterocyte transporter protein during maturation. These changes are likely to represent an adaptive response by the organism to increase nutrient absorption in a perceived state of tissue starvation. These adaptive changes may lead to exacerbation of hyperglycemia in uncontrolled diabetes.
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PMID:Small intestine hexose transport in experimental diabetes. Increased transporter mRNA and protein expression in enterocytes. 811 95

The erythrocyte (or HepG2/brain) type glucose transporter (GLUT 1) was the first of the family of facilitative glucose transporter proteins to be cloned [M. Mueckler et al., Science 229, 941-945, 1985]. GLUT 1 is expressed in most tissue types, all cell lines, transformed cells and tumour cells. It is thought to be responsible for "housekeeping" levels of glucose transport, i.e. the uptake of glucose required for oxidative phosphorylation. The rate of glucose transport via GLUT 1 can be regulated under conditions in which the metabolic rate must be adjusted such as cell division (mitosis and meiosis), differentiation, transformation and nutrient starvation. Here we review the recent literature on the control of glucose transport of mitogens, growth factors and oncogenes, and discuss some of the implications for the integration of cellular signalling pathways and cell growth.
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PMID:Growth factors, mitogens, oncogenes and the regulation of glucose transport. 813 71

This study was designed to determine whether glucose regulates the gene expression of glucose transporter GLUT3 in neurons. We examined the regulation of GLUT3 mRNA by glucose in vivo in mouse brain and in vitro by using neuronal cultures from rat embryos. Hypoglycaemia (< 30 mg/dl), produced by 72 h of starvation, increased GLUT3 mRNA in mouse brain by 2-fold. Hybridization studies in situ demonstrated that hypoglycaemia-induced increases in GLUT3 mRNA expression were observed selectively in brain regions including the hippocampus, dentate gyrus, cerebral cortex and piriform cortex, but not the cerebellum. Primary neuronal cultures from rat embryos deprived of glucose for 48 h also showed an increase (4-fold over control) in GLUT3 mRNA, indicating that glucose can directly regulate expression of GLUT3 mRNA. In contrast with hypoglycaemia, hyperglycaemia produced by streptozotocin did not alter the expression of GLUT3 mRNA. We also confirmed previous findings that hypoglycaemia increases GLUT1 mRNA expression in brain. The increase in GLUT1 expression was probably limited to the blood-brain barrier in vivo, since GLUT1 mRNA could not be detected in neurons of the mouse cerebrum. Thus we conclude that up-regulation of neuronal GLUT3 in response to glucose starvation represents a protective mechanism against energy depletion in neurons.
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PMID:Gene expression of GLUT3 glucose transporter regulated by glucose in vivo in mouse brain and in vitro in neuronal cell cultures from rat embryos. 819 23

High-fat diet (HFD) induces skeletal muscle insulin resistance. To investigate associated changes in the plasma membrane glucose transporter, male Sprague-Dawley rats were fed either chow [high-carbohydrate diet (HCD)] or HFD for 3 wk. Plasma membrane vesicles were prepared from hindlimb muscle of control, insulin-stimulated (Ins), and acutely exercised (Ex) rats. Maximal vesicle glucose transport activity (Vmax) increased threefold with Ins and Ex treatment compared with controls in HCD rats; in HFD rats, increases were less than twofold. Transporter numbers (measured by cytochalasin B binding, CB) approximately doubled with Ins and Ex in both diet groups. Intrinsic activity (carrier turnover, Vmax/CB) increased significantly with stimulation in HCD but not HFD rats. Therefore, vesicles from HFD rats showed resistance to both exercise and insulin stimulation of muscle glucose transport. Transporter number increased normally, but intrinsic activity in HFD rats did not respond. Two conclusions are discussed: 1) translocation and activation are distinct, separable steps in transporter stimulation and 2) HFD produces effects that resemble the insulin resistance of starvation.
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PMID:High-fat diet reduces glucose transporter responses to both insulin and exercise. 830 61

The GLUT4 glucose transporter and type II hexokinase are predominantly expressed in skeletal muscle and adipose tissue. The effects of insulin and glucose on the expression of GLUT4 and HKII were studied in vivo by using the euglycemic-hyperinsulinemic and hyperglycemic-hyperinsulinemic clamp methods. The clamps were maintained in conscious rats for 6 or 24 h after a 1-day starvation period. Adipose tissue GLUT4 mRNA was increased 4-fold after 6 h and 23-fold after 24 h of hyperinsulinemia; HKII mRNA was increased by four- and eightfold after 6 and 24 h, respectively. In contrast, GLUT4 mRNA was not significantly changed in skeletal muscle by either the euglycemic- or hyperglycemic-hyperinsulinemic clamps. Each of these treatments resulted in a fourfold induction of HKII mRNA. No changes of GLUT4 protein and hexokinase activity were detected after 6 h of hyperinsulinemia in either skeletal muscle or adipose tissue. After 24 h of hyperinsulinemia, adipose tissue GLUT4 protein had doubled, whereas skeletal muscle GLUT4 was unchanged. In contrast, hexokinase activity increased by two- to eightfold in skeletal muscle and adipose tissue. Hyperinsulinemia alone was sufficient to mediate the effects observed, because no additional effects were seen when hyperglycemia accompanied hyperinsulinemia. These results reveal the lack of coordinate regulation of GLUT4 and HKII in adipose tissue and skeletal muscle. Whereas hyperinsulinemia increases both GLUT4 and HKII mRNA and protein levels in adipose tissue, this treatment increases HKII mRNA and protein in skeletal muscle, but has no effect on GLUT4 in this tissue.
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PMID:The effects of hyperinsulinemia and hyperglycemia on GLUT4 and hexokinase II mRNA and protein in rat skeletal muscle and adipose tissue. 849 14


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