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)

The number of glucose transporters was measured in isolated membranes from diabetic-rat skeletal muscle to determine the role of circulating blood glucose levels in the control of glucose uptake into skeletal muscle. Three experimental groups of animals were investigated in the post-absorptive state: normoglycaemic/normoinsulinaemic, hyperglycaemic/normoinsulinaemic and hyperglycaemic/normoinsulinaemic made normoglycaemic/normoinsulinaemic by phlorizin treatment. Hyperglycaemia caused a reversible decrease in total transporter number, as measured by cytochalasin B binding, in both plasma membranes and internal membranes of skeletal muscle. Changes in GLUT4 glucose transporter protein mirrored changes in cytochalasin B binding in plasma membranes. However, there was no recovery of GLUT4 levels in intracellular membranes with correction of glycaemia. GLUT4 mRNA levels decreased with hyperglycaemia and recovered only partially with correction of glycaemia. Conversely, GLUT1 glucose transporters were only detectable in the plasma membranes; the levels of this protein varied directly with glycaemia, i.e. in the opposite direction to GLUT4 glucose transporters. This study demonstrates that hyperglycaemia, in the absence of hypoinsulinaemia, is capable of down-regulating the glucose transport system in skeletal muscle, the major site of peripheral resistance to insulin-stimulated glucose transport in diabetes. Furthermore, correction of hyperglycaemia causes a complete restoration of the transport system in the basal state (determined by the transporter number in the plasma membrane), but possibly only an incomplete recovery of the transport system's ability to respond to insulin (since there is no recovery of GLUT4 levels in the intracellular membrane insulin-responsive transporter pool). Finally, the effect of hyperglycaemia is specific for glucose transporter isoforms, with GLUT1 and GLUT4 proteins varying respectively in parallel and opposite directions to levels of glycaemia.
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PMID:Glycaemia regulates the glucose transporter number in the plasma membrane of rat skeletal muscle. 153 53

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.
Diabetes 1992 Apr
PMID:Gene expression of GLUT4 in skeletal muscle from insulin-resistant patients with obesity, IGT, GDM, and NIDDM. 153 55

To study whether insulin resistance in Type 2 (non-insulin-dependent) diabetes mellitus is due to a defect in the expression of the insulin-responsive glucose transporter gene (GLUT-4) in human skeletal muscle, we measured the level of GLUT-4 mRNA and (in some of the subjects) its protein in muscle biopsies taken from 14 insulin-resistant patients with Type 2 diabetes, 10 first-degree relatives of the diabetic patients and 12 insulin-sensitive control subjects. Insulin sensitivity was measured with a + 45 mU.m2(-1).min-1 euglycaemic insulin clamp in combination with indirect calorimetry and infusion of [3-3H]glucose. GLUT-4 mRNA was measured using a human GLUT-4 cDNA probe and GLUT-4 protein with a polyclonal antibody specific for the 15 amino acid carboxy-terminal peptide. Both Type 2 diabetic patients and their relatives showed impaired stimulation of total-body glucose disposal by insulin compared with control subjects (29.5 +/- 2.1 and 34.0 +/- 4.8 vs 57.9 +/- 3.1 mumol.kg lean body mass-1.min-1; p less than 0.01). This impairment in glucose disposal was primarily accounted for by a reduction in insulin-stimulated storage of glucose as glycogen (13.0 +/- 2.4 and 15.6 +/- 3.9 vs 36.9 +/- 2.2 mumol.kg lean body mass-1.min-1; p less than 0.01). The levels of GLUT-4 mRNA expressed both per microgram of total RNA and per microgram DNA, were higher in the diabetic patients compared with the control subjects (116 +/- 25 vs 53 +/- 10 pg/microgram RNA and 177 +/- 35 vs 112 +/- 29 pg/microgram DNA; p less than 0.05, p less than 0.01, respectively).(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Insulin resistance in type 2 (non-insulin-dependent) diabetic patients and their relatives is not associated with a defect in the expression of the insulin-responsive glucose transporter (GLUT-4) gene in human skeletal muscle. 154 18

Three major metabolic abnormalities contribute to hyperglycemia in non-insulin-dependent diabetes mellitus (NIDDM) including defective glucose-induced insulin secretion, elevated rates of hepatic glucose output, and insulin's impaired ability to stimulate glucose uptake in peripheral target tissues (insulin resistance). These functions involve cellular glucose transport in beta-cells, liver, adipose tissue, and skeletal muscle; and, in some instances, abnormalities in glucose transporter isoforms (GLUT) specifically expressed in these tissues may constitute key biochemical lesions underlying defective glucose homeostasis. In animal models of NIDDM, suppression of GLUT2 in beta-cells is correlated with loss of high-Km glucose transport and glucose-sensitive insulin secretion. Although there are no data on humans with NIDDM, GLUT2 loss would constitute an attractive mechanism for defective glucose sensing in beta-cells if it can be shown that transport then becomes rate limiting for glucose metabolism. In the liver, however, hepatocyte glucose transport via GLUT2 probably plays only a permissive role in sustaining increased glucose efflux. Peripheral insulin resistance is associated with decreased glucose transport activity, the likely rate-limiting step for glucose uptake in fat and muscle. Accordingly, the insulin-responsive GLUT4 isoform expressed exclusively in insulin target tissues has been studied intensively in NIDDM. In these studies, pretranslational suppression of GLUT4 appears to be the key mechanism of insulin resistance in adipocytes. However, levels of GLUT4 protein and mRNA are normal in vastus lateralis and rectus abdominis, inferring that defects in GLUT4 functional activity or insulin-mediated translocation cause insulin resistance in muscle. Thus, the intensified study of glucose transport has provided important new insights into NIDDM pathogenesis over the past 5 yr and has presented investigators with additional intriguing hypotheses.
Diabetes Care 1992 Mar
PMID:Glucose transport and NIDDM. 155 8

Insulin-dependent diabetes mellitus (IDDM) is associated with insulin deficiency and insulin-resistant glucose uptake in skeletal muscle. To investigate the molecular mechanisms for this insulin resistance, we examined the expression of GLUT1 and GLUT4, glucose transporter genes in vastus lateralis muscle from 20 IDDM subjects and 10 nondiabetic controls. Both groups had a mean age of 34 yr and were nonobese. Fasting free plasma insulin levels were similar in control and IDDM subjects but hemoglobin A1c (HbA1c), fasting plasma glucose and free fatty acid levels were significantly higher in IDDM subjects. Euglycemic clamp studies over a range of insulin concentrations in these IDDM subjects previously showed both decreased insulin sensitivity and decreased maximally insulin stimulated glucose utilization. In this study, Northern blotting of muscle ribonucleic acid (RNA) revealed a single 3.0-3.5 kb transcript for both GLUT1 and GLUT4 with no change in messenger RNA (mRNA) size or abundance with IDDM. In IDDM subjects, GLUT1 mRNA levels correlated positively with HbA1c whereas GLUT4 mRNA levels correlated negatively with fasting plasma glucose but not with HbA1c. Neither mRNA correlated with fasting plasma insulin or free fatty acid levels or with daily insulin dose. Immunoblotting of total muscle membranes for GLUT4 showed a single band of mol mass of approximately 45 kilodaltons with no change in size or abundance with IDDM. There was no significant correlation between GLUT4 polypeptide levels and HbA1c, fasting plasma glucose, insulin, or free fatty acids, daily insulin dose, duration of diabetes, or subject age but in IDDM subjects GLUT4 protein levels correlated negatively with body mass index. Thus, impaired expression of glucose transporters in muscle is not essential for the pathogenesis of insulin-resistant glucose uptake in IDDM. No direct regulatory role of chronic glycemic control or plasma insulin levels on GLUT4 expression is evident. In contrast, recent ambient glucose levels may affect levels of GLUT4 mRNA but not GLUT4 protein, suggesting important posttranscriptional regulation of this protein. Since glucose transport has been shown to be rate limiting for glucose utilization in muscle in IDDM, these results suggest impaired translocation or activation of glucose transporters in IDDM.
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PMID:Expression of GLUT1 and GLUT4 glucose transporters in skeletal muscle of humans with insulin-dependent diabetes mellitus: regulatory effects of metabolic factors. 156 56

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

The diabetogenic effects of glucocorticoid excess are due in part to peripheral resistance to insulin. To test the hypothesis that glucocorticoid-induced peripheral insulin resistance might be attributable to a decreased number of glucose transporters, we examined the effects of dexamethasone treatment on the expression of the GLUT4 (insulin regulatable) glucose transporter in skeletal muscle, the major site of insulin-mediated glucose uptake. Dexamethasone treatment of rats (1 mg/day for 1 wk) induced hyperglycemia and hyperinsulinemia. At dosages of either 0.1 or 1 mg/day, insulin-stimulated 2-deoxyglucose uptake in isolated soleus muscle was reduced by greater than or equal to 50%, demonstrating the presence of insulin resistance in skeletal muscle. Immunoblots of crude membranes from deep quadriceps muscle showed that dexamethasone treatment (1 mg/day) increased the amount of GLUT4 protein by 84%. GLUT4 mRNA abundance was similarly increased when expressed per unit RNA but was unchanged when expressed on a DNA basis because the tissue RNA content was decreased by dexamethasone. In contrast to quadriceps, GLUT4 protein concentration in soleus and extensor digitorum longus extracts was not significantly increased by dexamethasone treatment. Because glucocorticoids cause selective atrophy of type IIb muscle fibers, which express relatively less GLUT4 protein, the apparent increase in GLUT4 content in quadriceps muscle from dexamethasone-treated animals may have resulted from inadvertent increased sampling of GLUT4-enriched type I and IIA fibers, caused by a glucocorticoid-induced decrease in the relative mass of the GLUT4-poor type IIb fibers. We conclude that glucocorticoids do not decrease GLUT4 content in skeletal muscle and that glucocorticoid-induced insulin resistance in this tissue is not due to suppression of glucose transporter gene expression.
Diabetes 1992 Jun
PMID:Role of glucose transporters in glucocorticoid-induced insulin resistance. GLUT4 isoform in rat skeletal muscle is not decreased by dexamethasone. 158 99

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

The human liver/islet glucose transporter (GLUT2), a candidate gene for diabetes, has been incorporated into a genetic linkage map for chromosome 3q using a (CA)n dinucleotide repeat polymorphism adjacent to the 3'-end of exon 4a. We have found a total of nine alleles ranging in length from 153 to 169 nucleotides in three racial groups and have determined the precise structure of the variable region for four of the alleles by DNA sequencing. Five alleles were found to be common to the American Black, Caucasian, and Pima Indian racial groups studied. One allele (169 bp) was unique to American Blacks, and another rare allele (153 bp) was found only in the Caucasian population studied. Observed heterozygosity of the polymorphism in the Caucasian (CEPH) reference pedigree collection is 60%, for American Blacks 71%, and for Pima Indians 53%. An independent study recently identified the same dinucleotide repeat and found six alleles in a Caucasian population (Froguel et al., 1991), a result that we confirm; however, our sequencing data indicate a different molecular structure for the polymorphism for some of the alleles. We have constructed a new genetic linkage map of chromosome 3q uniquely placing the GLUT2 gene between flanking markers D3S26 and D3S43. The genetic map consists of 23 loci (25 RFLPs and 2 (CA)n dinucleotide repeat markers) with 14 markers uniquely localized with odds of at least 1000:1. Three genes (FTHL4, TF, GLUT2) are integrated into the map, which spans a sex-average distance of 147.3 cM, 103.8 cM in males and 227.0 cM in females.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Mapping the human liver/islet glucose transporter (GLUT2) gene within a genetic linkage map of chromosome 3q using a (CA)n dinucleotide repeat polymorphism and characterization of the polymorphism in three racial groups. 163 77

Polymorphisms occur on the average of one out of every 500 base pairs of DNA, and these polymorphisms provide useful markers for genetic analysis. Hundreds of RFLP markers have been mapped at regular intervals throughout the human genome. Diabetes genes have not been mapped with these markers, however, only one MODY family has been partially evaluated. This type of analysis is further complicated if NIDDM is multigenic and/or polygenic. RFLPs have been used to evaluate specific candidate loci for NIDDM, e.g. the insulin, insulin receptor and glucose transporter genes. For these analyses, population and family studies (limited in number) have suggested that none of these loci are major contributors to the genetic susceptibility to NIDDM. In no case, however, could a contribution of 10% or less of these loci be confidently excluded, because of variable penetrance, different degrees of linkage disequilibrium between RFLPs and putative mutations, the frequencies of the RFLPs in non-diabetic populations, and inadequate sample size. The conclusions are clear: either (1) the correct candidate gene(s) has not been found, or (2) sample sizes need to be increased by at least an order of magnitude, or (3) newer methods of analysis must be adopted (e.g. use of extended haplotypes and associations with subphenotypes, or screening with allele specific oligonucleotide probes, denaturing gradient gel electrophoresis or direct genomic sequencing of polymerase chain reaction amplified DNA).
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PMID:Use of DNA polymorphisms for genetic analysis of non-insulin dependent diabetes mellitus. 167 85

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