UMLS:C0028754 - FACTA Search

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Query: UMLS:C0028754 (obesity)
124,988 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The significance of variation within the genes coding for three glucose transporter proteins in the aetiology of non-insulin dependent diabetes mellitus was assessed by analysing restriction fragment length polymorphisms in an English Caucasian population. Two polymorphisms at the HepG2/erythrocyte glucose transporter (GLUT1) locus, four at the liver/pancreatic glucose transporter (GLUT2) locus and one at the muscle/adipocyte glucose transporter (GLUT4) were analysed in a sample of diabetic and non-diabetic subjects. No significant differences in the allelic, genotypic or haplotypic frequencies of the polymorphisms at these three loci were observed between the diabetic or non-diabetic populations. No significant linkage disequilibrium was observed between the two GLUT1 polymorphic sites, whereas the four polymorphic sites at the GLUT2 locus, one of which appears to be due to a 100-200 base pair DNA insertion/deletion, were found to be in significant linkage disequilibrium. In order to study the possible role of glucose transporter gene variants contributing to the development of obesity, the body mass indexes were compared in the different genotypic groups of diabetic and non-diabetic subjects. No differences in body mass index between genotype groups were found at the p < 0.005 level of significance.
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PMID:Analysis of three glucose transporter genes in a Caucasian population: no associations with non-insulin-dependent diabetes and obesity. 136 30

In obesity, impaired glucose tolerance (IGT), non-insulin-dependent diabetes mellitus (NIDDM), and gestational diabetes mellitus (GDM), defects in glucose transport system activity, contribute to insulin resistance in target tissues. In adipocytes from obese and NIDDM patients, we found that pretranslational suppression of the insulin-responsive GLUT4 glucose transporter isoform is a major cause of cellular insulin resistance; however, whether this process is operative in skeletal muscle is not clear. To address this issue, we performed percutaneous biopsies of the vastus lateralis in lean and obese control subjects and in obese patients with IGT and NIDDM and open biopsies of the rectus abdominis at cesarian section in lean and obese gravidas and gravidas with GDM. GLUT4 was measured in total postnuclear membrane fractions from both muscles by immunoblot analyses. The maximally insulin-stimulated rate of in vivo glucose disposal, assessed with euglycemic glucose clamps, decreased 26% in obesity and 74% in NIDDM, reflecting diminished glucose uptake by muscle. However, in vastus lateralis, relative amounts of GLUT4 per milligram membrane protein were similar (NS) among lean (1.0 +/- 0.2) and obese (1.5 +/- 0.3) subjects and patients with IGT (1.4 +/- 0.2) and NIDDM (1.2 +/- 0.2). GLUT4 content was also unchanged when levels were normalized per wet weight, per total protein, and per DNA as an index of cell number. Levels of GLUT4 mRNA were similarly not affected by obesity, IGT, or NIDDM whether normalized per RNA or for the amount of an unrelated constitutive mRNA species. Because muscle fibers (types I and II) exhibit different capacities for insulin-mediated glucose uptake, we tested whether a change in fiber composition could cause insulin resistance without altering overall levels of GLUT4. However, we found that quantities of fiber-specific isoenzymes (phopholamban and types I and II Ca(2+)-ATPase) were similar in all subject groups. In rectus abdominis, GLUT4 content was similar in the lean, obese, and GDM gravidas whether normalized per milligram membrane protein (relative levels were 1.0 +/- 0.2, 1.3 +/- 0.1, and 1.0 +/- 0.2, respectively) or per wet weight, total protein, and DNA. We conclude that in human disease states characterized by insulin resistance, i.e., obesity, IGT, NIDDM, and GDM, GLUT4 gene expression is normal in vastus lateralis or rectus abdominis. To the extent that these muscles are representative of total muscle mass, insulin resistance in skeletal muscle may involve impaired GLUT4 function or translocation and not transporter depletion as observed in adipose tissue.
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PMID:Gene expression of GLUT4 in skeletal muscle from insulin-resistant patients with obesity, IGT, GDM, and NIDDM. 153 55

In order to determine the role of insulin and glucose transporter gene expression in the development of diabetes in obesity, we examined insulin and GLUT2-liver type and GLUT4-muscle-fat type glucose transporter mRNA levels in obese and diabetic rats. Ventromedial hypothalamus-lesioned (VMH), Zucker fatty (ZF), and Wistar fatty (WF) rats were used as models. VMH and ZF rats are most frequently used as models for simple obesity. In contrast, WF rats, which have been established by transferring the fa gene of ZF rats to Wistar Kyoto rats, develop both obesity and diabetes. Pancreatic insulin content of VMH rats at 10 weeks after the operation and of ZF rats at 5 and 14 weeks of age was significantly higher than that of controls. On the other hand, insulin content of WF rats at 5 and 14 weeks of age was not significantly different from that of lean littermates. The insulin mRNA levels of VMH rats were increased progressively and were significantly higher than those in sham-operated animals at 4 and 10 weeks after the operation. In ZF rats, the insulin mRNA levels at 5 and 14 weeks of age were significantly higher than those of their lean littermates. In WF rats, by contrast, the insulin mRNA levels were similar to those of lean littermates at 5 and 14 weeks of age. The insulin mRNA levels of WF rats were about 40% of that of ZF rats at 14 weeks of age. On the other hand, at 14 weeks of age, the GLUT2 mRNA levels of liver were significantly higher in ZF and WF rats than those in their respective littermates, but not at 5 weeks of age. The GLUT4 mRNA levels of skeletal muscle in both ZF and WF rats were not significantly different from those of controls. It is suggested that the inability of WF rats to augment insulin gene expression in response to a large demand for insulin is associated with the occurrence of diabetes, and that the activation of GLUT2 mRNA without the activation of GLUT4 mRNA is common to obesity with and without diabetes.
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PMID:Insulin and glucose transporter gene expression in obesity and diabetes. 157 85

Insulin resistance is a major pathologic feature of human obesity and diabetes. Understanding the fundamental mechanisms underlying this insulin resistance has been advanced by the recent cloning of the genes encoding a family of facilitated diffusion glucose transporters which are expressed in characteristic patterns in mammalian tissues. Two of these transporters, GLUT1 and GLUT4, are present in muscle and adipose cells, tissues in which glucose transport is markedly stimulated by insulin. To understand the mechanisms underlying in vivo insulin resistance, regulation of these transporters is being investigated. Studies reveal divergent changes in the expression of GLUT1 and GLUT4 in a single cell type as well as tissue specific regulation. Importantly, alterations in glucose transport in rodent models of diabetes and in human obesity and diabetes cannot be entirely explained by changes in glucose transporter expression. This suggests that defects in glucose transporter function such as impaired translocation, fusion with the plasma membrane, or activation probably contribute importantly to in vivo insulin resistance.
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PMID:Alterations in glucose transporter expression and function in diabetes: mechanisms for insulin resistance. 161 26

Glucose uptake in rat skeletal muscles decreases with age and obesity, but increases with chronic exercise training. The purpose of our study was to determine whether the GLUT4 content in several skeletal muscles from 1-mo-old young, lean rats and 12-mo-old aged, obese rats alters with exercise training. For exercise, a treadmill run of approximately 1 km/day was made for 4 wk by both groups of rats. The concentration of GLUT4 per protein in membrane fraction from several skeletal muscles was measured by immunoblotting. The amount of GLUT4 in the gastrocnemius and white quadriceps from aged rats slightly but significantly decreased to 73% and 78% of that from young rats, respectively. However, no significant difference in GLUT4 amount in the soleus, plantaris, and red quadriceps was observed between young and aged rats. The exercise training resulted in a larger increase in the amount of GLUT4 in each muscle from aged rats than in muscles from young rats. In aged rats, GLUT4 amount increased significantly with exercise training by 30, 33, 41, and 27% in the soleus, plantaris, gastrocnemius, and red quadriceps, respectively, compared with the sedentary controls. However, in young rats, exercise-induced increase of GLUT4 amount was significant only in the plantaris, and the increase was 17%. In exercised aged, obese rats, decreases of body weight, plasma triglyceride levels, and plasma free fatty acid were also observed.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Exercise training increases glucose transporter content in skeletal muscles more efficiently from aged obese rats than young lean rats. 162 66

We used antibodies to the fat/muscle glucose transporter (GLUT4) and the liver glucose transporter (GLUT2) to measure levels of these proteins in various tissues of two rodent models of non-insulin-dependent (type II) diabetes mellitus: the obese spontaneously diabetic male Zucker fa/fa rat (ZDF/drt) and the male viable yellow Avy/a obese diabetic mouse. The ZDF/drt strain generally develops overt diabetes associated with decreased plasma insulin levels. Depending on the age of the animals, the ZDF/drt rats can be arbitrarily segregated into age-matched obese, mildly diabetic (blood glucose less than 11 mM) and obese, and severely diabetic (blood glucose greater than 20 mM) groups. Avy/a mice are comparably hyperglycemic but unlike the ZDF/drt rats are severely hyperinsulinemic. In both groups of diabetic animals, GLUT4 in adipose tissue, heart, and skeletal muscle was reduced 25-55%, and GLUT2 in liver was increased 30-40%, relative to lean, age-matched controls. However, when the mildly diabetic ZDF/drt rats were compared to the lean controls, the only significant difference was a 25% reduction of GLUT4 in heart. Within all of the ZDF/drt rats (excluding the lean controls), GLUT2 in liver and GLUT4 in adipose tissue, heart, and skeletal muscle correlated significantly with glycemia. These data suggest that, in these two models of type II diabetes, glucose transporter levels in muscle, adipose tissue, and liver are regulated in a tissue-selective manner in response to changes in insulin and glucose. Furthermore, at least in the ZDF/drt rat, alterations in GLUT2 and/or GLUT4 protein levels appear not to be associated with obesity per se but appear to be secondary to the severely diabetic state.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Glucose transporter levels in tissues of spontaneously diabetic Zucker fa/fa rat (ZDF/drt) and viable yellow mouse (Avy/a). 173 8

A major defect contributing to impaired insulin action in human obesity is reduced glucose transport activity in skeletal muscle. This study was designed to determine whether the improvement in whole body glucose disposal associated with weight reduction is related to a change in skeletal muscle glucose transport activity and levels of the glucose transporter protein GLUT4. Seven morbidly obese (body mass index = 45.8 +/- 2.5, mean +/- SE) patients, including four with non-insulin-dependent diabetes mellitus (NIDDM), underwent gastric bypass surgery for treatment of their obesity. In vivo glucose disposal during a euglycemic clamp at an insulin infusion rate of 40 mU/m2 per min was reduced to 27% of nonobese controls (P less than 0.01) and improved to 78% of normal after weight loss of 43.1 +/- 3.1 kg (P less than 0.01). Maximal insulin-stimulated glucose transport activity in incubated muscle fibers was reduced by approximately 50% in obese patients at the time of gastric bypass surgery but increased twofold (P less than 0.01) to 88% of normal in five separate patients after similar weight reduction. Muscle biopsies obtained from vastus lateralis before and after weight loss revealed no significant change in levels of GLUT4 glucose transporter protein. These data demonstrate conclusively that insulin resistance in skeletal muscle of mobidly obese patients with and without NIDDM cannot be causally related to the cellular content of GLUT4 protein. The results further suggest that morbid obesity contributes to whole body insulin resistance through a reversible defect in skeletal muscle glucose transport activity. The mechanism for this improvement may involve enhanced transporter translocation and/or activation.
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PMID:Restoration of insulin responsiveness in skeletal muscle of morbidly obese patients after weight loss. Effect on muscle glucose transport and glucose transporter GLUT4. 173 57

In order to investigate the regulation of glucose transporter gene expression in the altered metabolic conditions of obesity and diabetes, we have measured mRNA levels encoding GLUT2 in the liver and GLUT4 in the gastrocnemius muscle from various insulin resistant animal models, including Zucker fatty, Wistar fatty, and streptozocin(STZ)-treated diabetic rats. Northern blot analysis revealed that GLUT2 mRNA levels were significantly (P less than 0.001) elevated in 14 wk Zucker fatty and Wistar fatty rats relative to lean littermates but were similar in these two groups at 5 wk of age. Furthermore, there was significant increase (P less than 0.01) in GLUT2 mRNA levels in STZ diabetic rats at 3 wk after treatment. GLUT4 mRNA levels were not significantly different between control and insulin resistant rats in all animal models. These results indicate that neither hyperinsulinemia nor hyperglycemia affects GLUT4 mRNA levels in the muscle. However, GLUT2 mRNA levels in the liver were elevated in obesity and diabetes, although this regulatory event occurred independently from circulating insulin or glucose concentrations.
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PMID:Liver and muscle-fat type glucose transporter gene expression in obese and diabetic rats. 202 68

We recently created a new model of murine obesity through transgenic ablation of brown adipose tissue (BAT) using a tissue-specific toxigene (6). The goal of the present study was to further define the altered glucose homeostasis and insulin resistance in these transgenic animals. Despite an approximately 30% increase in total body lipid, no abnormalities were observed in 6-week-old transgenic animals. At the age of 22-26 weeks, marked obesity in transgenic mice was associated with significant increases in blood glucose and plasma insulin levels and an abnormal response to both intraperitoneal glucose and insulin tolerance tests. Glucose transport in soleus muscle was reduced, with the response to insulin stimulation blunted by up to 85% in males and 55% in females. The total number of insulin receptors was decreased by 36% in muscle and 59% in adipose tissue of transgenic animals. Insulin receptor tyrosine kinase activity, which was assessed following maximal insulin stimulation in vivo, was reduced in transgenic animals by 59% in muscle and 56% in fat. GLUT4 mRNA and protein was unchanged in muscle of transgenic animals compared with in that of controls but was significantly reduced in adipose tissue. In conclusion, primary BAT deficiency results in the development of glucose intolerance or diabetes and severe insulin resistance with both receptor and postreceptor components. These animals should be a useful model for studies of obesity-linked diabetes and insulin resistance and related complications.
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PMID:Characterization of insulin resistance and NIDDM in transgenic mice with reduced brown fat. 758 22

The insulin-sensitive glucose transporter, GLUT4, is the most abundant facilitative glucose transporter in muscle and adipose tissue, the major sites for postprandial glucose disposal. To assess the role of GLUT4 in glucose homeostasis, we have disrupted the murine GLUT4 gene. Because GLUT4 has been shown to be dysregulated in pathological states such as diabetes and obesity, it was expected that genetic ablation of GLUT4 would result in abnormal glucose homeostasis. The mice deficient in GLUT4 (GLUT4-null) are growth-retarded and exhibit decreased longevity associated with cardiac hypertrophy and severely reduced adipose tissue deposits. Blood glucose levels in female GLUT4-null mice are not significantly elevated in either the fasting or fed state; in contrast, male GLUT4-null mice have moderately reduced glycaemias in the fasted state and increased glycaemias in the fed state. However, both female and male GLUT4-null mice exhibit postprandial hyperinsulinaemia, indicating possible insulin resistance. Increased expression of other glucose transporters is observed in the liver (GLUT2) and heart (GLUT1) but not skeletal muscle. Oral glucose tolerance tests show that both female and male GLUT4-null mice clear glucose as efficiently as controls, but insulin tolerance tests indicate that these mice are less sensitive to insulin action. The GLUT4-null mice demonstrate that functional GLUT4 protein is not required for maintaining nearly normal glycaemia but that GLUT4 is absolutely essential for sustained growth, normal cellular glucose and fat metabolism, and expected longevity.
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PMID:Cardiac and adipose tissue abnormalities but not diabetes in mice deficient in GLUT4. 767 73

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