UMLS:C0011849 - FACTA Search

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Query: UMLS:C0011849 (diabetes)
277,896 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Insulin regulates cellular metabolic reactions by its action on the plasma membrane, intracellular enzymes and the nucleus. The first stage in the propagation of the insulin signal is the coupling of insulin to specific receptors at the cell surface. The exact mechanism whereby the transmembrane signalling mechanism (s) results in different insulin-mediated cellular effects is not known. However, the insulin receptor tyrosine kinase, the expression of second messengers, and the action of protein kinase C may, either individually or in combination, mediate some of the insulin effects, such as translocation and activation of glucose transporter proteins. Insulin resistance in clinical conditions such as insulin-dependent diabetes mellitus (IDDM), non-insulin-dependent diabetes mellitus (NIDDM), hypertension and obesity may be acquired to a large extent, and is thus partially reversible. Regulatory factors in insulin sensitivity, such as free fatty acids, counterregulatory hormones and blood glucose level, play an important role in the metabolic control and pathogenesis of insulin resistance in man.
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PMID:Regulation of insulin action at the cellular level. 204 21

Vanadate, the major oxidized form of the essential trace element vanadium, has rapid effects on glucose transport in vitro and more delayed effects on glucose transport in vivo. We addressed the question that one potential mechanism for the delayed effects of vanadate on glucose homeostasis could be altered expression of one or more of the genes encoding glucose transporters. To do this we studied vanadate regulation of Glut-1 and Glut-4 in NIH3T3 mouse fibroblasts. Vanadate (5-40 microM) induced cells to proliferate to higher cell densities, and in addition, 40 microM vanadate caused the cells to exhibit a transformed morphology. Glut-1 mRNA was maximally induced 4- to 5-fold over the control value after 6-h exposure to 30 microM vanadate. Unlike the response to serum and growth factors, the vanadate-induced increase in Glut-1 mRNA remained elevated over the control value in the presence of vanadate for 5 days. The vanadate effect was serum dependent and was fully reversible when vanadate was removed from the medium. In the absence of vanadate, the half-life of Glut-1 mRNA was 0.5-1 h, whereas after treatment for 5 h with 30 microM vanadate the half-life was increased to 1.5-2 h. Thus, mRNA stabilization accounts for at least a part of the increase in glucose transporter mRNA levels after vanadate treatment. Glut-4 mRNA was not detected in these cells in either the absence or presence of vanadate. While the importance of this increased Glut-1 gene expression for the vanadate effect on normalization of blood glucose in vivo remains to be determined, an association between vanadate-induced cell proliferation and transformed phenotype, and vanadate-induced Glut-1 mRNA in vitro has been made. Possible potential therapeutic use of vanadate for treatment of diabetes must, therefore, be viewed with caution.
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PMID:Vanadate regulates glucose transporter (Glut-1) expression in NIH3T3 mouse fibroblasts. 210 May 13

Two species of glucose transporter (GT) are present in the liver: the erythroid/brain GT and the newly characterized liver GT. No information is available regarding the functional role of these two species or whether their expression is regulated concordantly in states in which hepatic glucose uptake or output are markedly altered. In this study, we analyzed the effect of fasting and refeeding and streptozocin-induced diabetes and subsequent insulin treatment on the expression of the erythroid/brain and liver GT polypeptides and their mRNAs in rat liver. The erythroid/brain GT mRNA in livers of control rats corresponded to 1-3% of the amount of liver GT mRNA. After a 4-day fast, its level increased approximately 3-fold and represented 8-10% of the liver GT mRNA, whereas the corresponding protein increased 4-fold. In livers from diabetic rats, levels of the erythroid/brain GT mRNA increased up to 2.4-fold and gradually returned to normal with chronic insulin treatment. Levels of the corresponding protein were minimally altered. Levels of immunoreactive liver GTs were not significantly changed by 2 days of fasting, 7 or 14 days of diabetes, or subsequent insulin treatment for 3, 5, or 7 days but increased up to 75% with refeeding for 3-48 h. Liver GT mRNA levels minimally decreased in diabetic or insulin-treated rats, decreased 45% after a 2-day fast, and increased up to 5-fold on refeeding for 24 h.(ABSTRACT TRUNCATED AT 250 WORDS)
Diabetes 1990 Jun
PMID:Differential regulation of two glucose transporters in rat liver by fasting and refeeding and by diabetes and insulin treatment. 214 Aug 4

Analysis of glucose transporter mRNA levels in adipose tissue from streptozotocin (STZ)-induced diabetic rats demonstrated a specific decrease (10-fold) in adipose tissue GLUT-4 mRNA with no significant effect on GLUT-1 mRNA levels. Treatment of STZ-diabetic rats with twice daily injections of insulin for 1-3 days resulted in a 16-fold increase in the relative amount of GLUT-4 mRNA to levels approximately 2-fold greater than those in control animals. However, after 7 days of insulin therapy the amount of GLUT-4 mRNA decreased approximately 2-fold back to the levels in the control animals. Normalization of the STZ-induced serum hyperglycemia by phlorizin treatment, which inhibits renal tubular reabsorption of glucose, had no effect on GLUT-4 mRNA in the absence of insulin. Similar to STZ-diabetes, fasting for 48 h also reduced adipose GLUT-4 mRNA levels. Parenteral administration of insulin with glucose over 7.5 h, but not glucose alone, increased the levels of the GLUT-4 mRNA 3- to 4-fold. These studies demonstrate that the relative glycemic state does not influence GLUT-4 glucose transporter mRNA expression in vivo and strongly suggests that insulin is a major factor regulating the levels of GLUT-4 mRNA in adipose tissue.
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PMID:Regulation of glucose transporter messenger RNA levels in rat adipose tissue by insulin. 214 65

We identified the earliest events in autophosphorylation of the insulin receptor after insulin addition. Insulin-stimulated autophosphorylation at specific sites in the tyrosine kinase domain of the receptor's beta-subunit is correlated kinetically with activation of kinase-catalyzed phosphorylation of a model substrate (reduced and carboxyamidomethylated lysozyme; RCAM-lysozyme). To identify these sites, the deduced amino acid sequence of the 3T3-L1 adipocyte insulin receptor of the mouse was determined. Insulin-induced activation of substrate phosphorylation was shown to require autophosphorylation of three neighboring tyrosines (Tyr1148, Tyr1152, and Tyr1153) in the mouse receptor. A search for cellular substrates of the receptor kinase revealed that insulin causes accumulation of a 15,000-Mr phosphorylated (on tyrosine) cytosolic protein (pp15) in 3T3-L1 adipocytes treated with oxophenylarsine (PAO). PAO blocks turnover of the phosphoryl group of pp15, causing its accumulation, and thereby appears to interrupt signal transmission from the receptor to the glucose-transport system. Two membrane-bound protein phosphotyrosine phosphatases that are inhibited by PAO and are apparently responsible for the turnover of the pp15 phosphoryl group have been purified from 3T3-L1 adipocytes and characterized. These and other results support the hypothesis that turnover of the phosphoryl group of pp15, a product of insulin-receptor tyrosine kinase action, couples signal transmission to the glucose-transport system. [32P]pp15 was purified to homogeneity from 3T3-L1 adipocytes. Amino acid and radiochemical sequence analysis of the purified tryptic [32P]phosphopeptide revealed that pp15 is the phosphorylation product of 422(aP2) protein, a 15,000-Mr adipocyte protein whose cDNA we previously cloned and sequenced. 422(aP2) protein was found to bind fatty acids. When exposed to a free fatty acid, notably oleic acid, 422(aP2) protein becomes an excellent substrate of the isolated insulin-receptor tyrosine kinase. Compelling evidence indicates that on binding fatty acid, 422(aP2) protein undergoes a conformational change whereby Tyr19 becomes accessible to the receptor tyrosine kinase and undergoes O-phosphorylation. Adipose tissue and skeletal and heart muscle, which exhibit insulin-stimulated glucose uptake, express a specific insulin-responsive glucose transporter. A cDNA (GT2) that encodes this protein was isolated from a mouse 3T3-L1 adipocyte library and sequenced. We also isolated and characterized the corresponding mouse gene GLUT4. DNase I footprinting with nuclear extracts from 3T3-L1 cells revealed that a differentiation-specific nuclear factor binds to the GLUT4 promoter. The purified transcription factor C/EBP binds at the same position.(ABSTRACT TRUNCATED AT 400 WORDS)
Diabetes Care 1990 Jun
PMID:Insulin-receptor tyrosine kinase and glucose transport. 216 54

The levels of mRNAs encoding the alpha 1 chain of collagen IV and the B1 chain of laminin were assayed in the lenses and retinas of long-term (28-week) diabetic and galactosaemic rats in order to gain some insight into the effects on basement membrane (BM) synthesis in these tissues. mRNAs coding for beta-actin, glucose transporter protein and the alpha 2 catalytic subunit of Na+,K(+)-ATPase were also assayed to determine whether any effects on BM-coding mRNA levels were specific. Long-term diabetes had no significant effect on the levels of alpha 1 (IV) collagen mRNA but caused a significant reduction in the laminin B1 message in the lens. In the same samples, the level of the glucose transporter protein mRNA was found to be elevated significantly in the diabetic tissue, whereas the mRNAsen coding beta-actin and alpha 2 Na+,K(+)-ATPase were unaffected in comparison with age-matched controls. Long-term galactosaemia resulted in significant increases in the levels of all mRNAs assayed when expressed per micrograms total RNA used for each analysis. However, this effect appeared to be due to a specific loss of ribosomal RNA from these severely cataractous lenses. When related to the beta-actin mRNA internal control, the levels of mRNA in the galactosaemic lenses were very similar to that found in the diabetics. Laminin B1 mRNA levels were decreased significantly.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Effects of long-term diabetes and galactosaemia upon lens and retinal mRNA levels in the rat. 216 48

In vivo studies indicate that patients with NIDDM have defects in both insulin secretion and insulin action. The decrease in insulin action is due to both hepatic and extrahepatic insulin resistance. The impairment in glucose uptake is associated with alterations in both oxidative and nonoxidative disposal. Defective glucose transport may limit both of these processes. NIDDM also is associated with increased concentrations and rates of oxidation of plasma free fatty acids. Insulin resistance appears to be familial and in at least some individuals antedates glucose intolerance. In vitro studies indicate that insulin resistance can involve a variety of insulin sensitive tissues including adipocytes, muscle and liver. While most studies note that insulin binding and insulin receptor kinase activity are decreased in insulin sensitive tissues in obese patients with NIDDM, further delineation of the contribution of obesity and diabetes is required. Alterations in glucose transporter number and function likely account at least in part for impaired glucose transport. The cause of the alterations in other insulin responsive pathways and the role of an abnormal metabolic milieu versus intrinsic cellular defects remain to be established.
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PMID:Insulin resistance in type II diabetes mellitus. 216 26

Isolated muscle cells from adult rat heart were used to study the involvement of G-proteins in the regulation of the glucose transporter by insulin and isoprenaline. Efficient modification of G-protein functions was established by measuring isoprenaline-stimulated cyclic AMP production, viability and ATP content after treating the cells with cholera toxin and pertussis toxin for 2 h. Under these conditions cholera toxin decreased the stimulatory action of insulin on 3-O-methylglucose transport by 56%, but pertussis toxin had no effect. Basal transport was not affected by toxin treatment. Isoprenaline increased 3-O-methylglucose transport by 63%. This effect was not mimicked by dibutyryl cyclic AMP, but was completely blocked by cholera toxin. Streptozotocin-diabetes abolished isoprenaline action and decreased stimulation of transport by 64%. Concomitantly, cholera-toxin sensitivity of glucose transport was lost in cells from diabetic animals. This was paralleled by a large decrease (87 +/- 4%) in mRNA expression of the insulin-regulatable glucose transporter, as shown by Northern-blot analysis of RNA isolated from cardiomyocytes of diabetic rats. These data suggest a functional association between the insulin-responsive glucose transporter and a cholera-toxin-sensitive G-protein mediating stimulation by insulin and isoprenaline.
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PMID:G-protein-mediated regulation of the insulin-responsive glucose transporter in isolated cardiac myocytes. 217 73

Rats injected with a single dose of streptozocin at 2 days of age develop non-insulin-dependent diabetes 6 weeks later. The pancreatic beta islet cells of these diabetic rats display a loss of glucose-induced insulin secretion while maintaining sensitivity to other secretagogues such as arginine. We analyzed the level of expression of the liver/beta-cell glucose transporter isoform in diabetic islets by immunofluorescence staining of pancreas sections and by Western blotting of islet lysates. Islets from diabetic animals have a reduced expression of this beta-cell-specific glucose transporter isoform and the extent of reduction is correlated with the severity of hyperglycemia. In contrast, expression of this transporter isoform in liver is minimally modified by the diabetes. Thus a decreased expression of the liver/beta-cell glucose transporter isoform in beta cells is associated with the impaired glucose sensing characteristic of diabetic islets; our data suggest that this glucose transporter may be part of the beta-cell glucose sensor.
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PMID:Reduced expression of the liver/beta-cell glucose transporter isoform in glucose-insensitive pancreatic beta cells of diabetic rats. 220 56

Diabetes was induced in male Lewis rats by a single injection of streptozocin (50 mg/kg body wt ip). After 10-14 days, diabetic and age- and sex-matched control animals were killed, and their proximal small intestines were removed. Villus-tip, mid-villus, and lower-villus enterocytes were harvested from each group with a method that combined divalent cation chelation with mild mechanical dissociation. These fractions were used as starting material to prepare brush-border membrane vesicles. Preparations from each of these fractions were then analyzed and compared with respect to their Na(+)-gradient-dependent and Na(+)-independent D-glucose transport, lipid fluidity, and lipid composition. The results of these experiments demonstrated that 1) maximum rates of Na(+)-gradient-dependent D-glucose transport (Vmax) were greatest in membrane vesicles prepared from mature cells (villus tip and mid villus) of control rats; 2) the glucose concentration producing half-maximal rates of transport (Km), however, was significantly lower in lower-villus membrane vesicles of control rats, suggesting that a distinct glucose transporter existed in the membranes of these relatively immature enterocytes; 3) Na(+)-gradient-dependent, but not Na(+)-independent, D-glucose uptake was greater in diabetic membrane vesicles prepared from mid-villus and lower-villus fractions but not in vesicles prepared from villus-tip cells; and 4) no obvious relationship between alterations in membrane lipid fluidity and enhanced uptake of Na(+)-gradient-dependent D-glucose by these transporter(s) could be established in this experimental model of acute diabetes mellitus.
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PMID:Intestinal D-glucose transport and membrane fluidity along crypt-villus axis of streptozocin-induced diabetic rats. 222 Oct 67

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