cytochalasin-b and Obesity

In this article we have described the hypothesis that insulin stimulates glucose transport through glucose transporter translocation from an intracellular pool to the plasma membrane. In addition, we have shown that changes in the numbers and subcellular distributions of glucose transporters correlate with alterations in insulin-stimulated glucose transport activity in several experimental models of insulin resistance and hyperresponsiveness. However, in experiments with counterregulatory hormones and with hyperresponsive states induced by nutritional repletion following deprivation, changes in insulin responsiveness cannot be fully explained by such alterations in the numbers and/or subcellular distribution of glucose transporters. Thus, evidence has been presented for changes in glucose transporter intrinsic activity that both inhibit and augment insulin-stimulated glucose transport rates. Finally, we have discussed data suggesting that the translocation process is applicable to human tissue and that significant changes in adipose cell glucose transport activity have been correlated with total glucose disposal in various metabolic states in humans. Determining the physiologic factors involved in modulating these events at the cellular level is an important area for further investigation.

Topics: Adipose Tissue; Aging; Animals; Biological Transport; Cell Membrane; Cytochalasin B; Diabetes Mellitus, Experimental; Fasting; Glucose; Humans; Insulin; Insulin Resistance; Microsomes; Models, Biological; Monosaccharide Transport Proteins; Muscles; Obesity

Lithium's impact on glucose metabolism was compared with that of insulin in isolated rat soleus muscle. Lithium chloride (20 mmol/l) induced a 4.8-fold more pronounced increment over basal glycogen synthase activity than insulin (10 nmol/l) (nmol UDP-glucose into glycogen in synthase activity assay.g-1.min-1: lithium, +22.1 +/- 1.8 vs. insulin, +4.6 +/- 3.9; P < 0.01). In parallel, lithium was less efficient than insulin in stimulating glucose transport (counts per minute 2-deoxy-D-[3H]glucose.mg-1.h-1: lithium, +211 +/- 19 vs. insulin, +311 +/- 57; P < 0.05) and lactate release (mumol.g-1.h-1: lithium, +1.0 +/- 0.5 vs. insulin, +3.9 +/- 0.5; P < 0.01), and similar increments were induced in glycogen synthesis (mumol glucose into glycogen.g-1.h-1: lithium, +3.32 +/- 0.43 vs. insulin, +3.46 +/- 0.47; not significant). Full additivity of glycogenic effects and divergent dependency on phosphatidylinositol 3-kinase activation provided further evidence for different mechanisms of action. In muscle from insulin-resistant obese Zucker rats (fa/fa), failure of lithium to reverse deficits in glucose metabolism suggested a primary deficit in muscle glucose uptake rather than glycogen synthesis. Hence lithium distinctly stimulates glycogen synthase activity in skeletal muscle and may therefore be regarded as a candidate for the treatment of disorders associated with primary deficits in the glycogenic pathway.

Topics: Androstadienes; Animals; Biological Transport; Cytochalasin B; Dantrolene; Deoxyglucose; Glucose; Glycogen; Glycogen Synthase; In Vitro Techniques; Insulin; Insulin-Like Growth Factor I; Isoproterenol; Kinetics; Lactates; Lithium Chloride; Male; Muscle, Skeletal; Obesity; Rats; Rats, Sprague-Dawley; Rats, Zucker; Wortmannin

The effects of a similar exercise training stimulus on maximal insulin-stimulated (MIS) plasma membrane glucose transporter number and glucose transport were determined in lean and obese SHHF/Mcc-facp rats. Six-week-old lean and obese male rats were randomly divided into four groups: lean sedentary (LSed), obese sedentary (OSed), lean exercise (LEx), and obese exercise (OEx). An 8- to 12-wk treadmill running program equalized daily muscular work for LEx and OEx. Plasma membranes were isolated from control and MIS muscles of mixed fiber types. MIS significantly increased glucose transport (3.4- and 2.8-fold) in LSed and OSed, respectively. MIS significantly increased glucose transporter number (2.5-fold) in LSed, but there was no increase in glucose transporter number in OSed. Peak oxygen uptake and citrate synthase activity were increased a similar amount for LEx and OEx groups, demonstrating a similar training stimulus. MIS significantly and similarly increased glucose transport in LEx and OEx (4.4- and 5.1-fold, respectively). The effects of MIS on plasma membrane glucose transporter number in the exercise-trained rats were similar to the responses observed in the sedentary lean and obese groups. MIS significantly increased glucose transporter number (2.6-fold) in LEx, whereas there was no increase in glucose transporter number in OEx. The reduction in MIS glucose transport in OSed appears to be related to a defect in the processes associated with the translocation of glucose transporters to the plasma membrane. Exercise training of the obese rats apparently did not alter this defect. Similar increases in peak oxygen uptake, citrate synthase, and MIS glucose transport in LEx and OEx groups suggest that insulin resistance does not limit the ability of the glucose transport system to adapt to exercise training in the obese male SHHF/Mcc-facp rats.

Topics: 4-Nitrophenylphosphatase; Animals; Blood Glucose; Cell Membrane; Citrate (si)-Synthase; Cytochalasin B; Glucose Transporter Type 4; Glycogen; Insulin; Insulin Resistance; Male; Monosaccharide Transport Proteins; Muscle Proteins; Muscle, Skeletal; Obesity; Organ Size; Oxygen Consumption; Physical Conditioning, Animal; Rats; Rats, Inbred Strains

To study the contribution of glucose transporters (GLUT) to insulin resistance in aging, GLUT intrinsic activity was assessed in a cell-free system. Adipocytes were isolated from 18-month-old rats and young controls and incubated either with or without 7 nM insulin. Plasma membrane (PM) and low density microsomal fractions were prepared from the cells, and GLUT levels were assessed in these fractions before and after reconstitution into liposomes. Glucose transport rates were measured in intact cells and liposomes. Functional and intrinsic activities of GLUT were assessed from the ratio between these transport rates and GLUT levels in the respective fractions. Basal 3-O-methylglucose transport rates were unaffected by aging, which is consistent with unchanged levels of GLUT in PM. Insulin-stimulated glucose transport was 60% lower in aging, as was the extent of GLUT recruitment to PM. The effect of insulin stimulation of GLUT functional activity by 6-fold at PM was attenuated by 40% in aging. Conversely, the basal intrinsic activity of GLUT was significantly enhanced in aging (by 280% and 230% in PM and density microsomal liposomes, respectively) and was further stimulated by insulin by about 160% in PM, compared to only about 117% stimulation in controls. In conclusion, our data show that insulin stimulates the intrinsic activity of GLUT in rat adipocytes, and this activity is further enhanced in aging. Impaired glucose uptake in aging can be attributed to depleted GLUT4 levels and impaired function of GLUT at the cell surface. The discrepancy observed between impaired function and enhanced intrinsic activity of GLUT suggests the presence of additional factors that modulate the full functional expression of GLUT at the cell surface.

Topics: Adipocytes; Aging; Animals; Cytochalasin B; Liposomes; Male; Monosaccharide Transport Proteins; Obesity; Rats; Rats, Sprague-Dawley; Subcellular Fractions; Tissue Distribution

The genetically obese Zucker rat (fa/fa) is characterized by a severe resistance to the action of insulin to stimulate skeletal muscle glucose transport. The goal of the present study was to identify whether the defect associated with this insulin resistance involves an alteration of transporter translocation and/or transporter activity. Various components of the muscle glucose transport system were investigated in plasma membranes isolated from basal or maximally insulin-treated skeletal muscle of lean and obese Zucker rats. Measurements of D- and L-glucose uptake by membrane vesicles under equilibrium exchange conditions indicated that insulin treatment resulted in a four-fold increase in the Vmax for carrier-mediated transport for lean animals [from 4.5 to 17.5 nmol/(mg.s)] but only a 2.5-fold increase for obese rats [from 3.6 to 9.1 nmol/(mg.s)]. In the lean animals, this increase in glucose transport function was associated with a 1.8-fold increase in the transporter number as indicated by cytochalasin B binding, a 1.4-fold increase in plasma membrane GLUT4 protein, and a doubling of the average carrier turnover number (intrinsic activity). In the obese animals, there was no change in plasma membrane transporter number measured by cytochalasin B binding, or in GLUT4 or GLUT1 protein. However, there was an increase in carrier turnover number similar to that seen in the lean litter mates. Measurements of GLUT4 mRNA in red gastrocnemius muscle showed no difference between lean and obese rats. We conclude that the insulin resistance of the obese rats involves the failure of translocation of transporters, while the action of insulin to increase the average carrier turnover number is normal.

Topics: Animals; Biological Transport; Blood Glucose; Cell Membrane; Cytochalasin B; Glucose; Insulin; Insulin Resistance; Monosaccharide Transport Proteins; Muscles; Obesity; Phosphorylation; Rats; Rats, Zucker; RNA, Messenger

The regulation of glucose transport in normal and insulin-resistant obese rat hearts have been studied by measuring glucose transport via the efflux of labelled 3-0-methyl-D-glucose. Glucose transporters in obese rat hearts were also investigated using the labelled cytochalasin B-binding assay. Basal, and insulin- or increasing workload-induced stimulation of glucose transport was decreased in obese rat hearts compared to those of normal ones. Total number of glucose transporters (plasma membrane plus microsomal ones) was about half that previously reported for normal rat hearts. Insulin or workload favoured the translocation of glucose transporters from an intercellular pool (microsomes) to the plasma membrane, as they do in normal rats. Due to the measured decrease in total number of transporters of obese rat hearts, those present in the plasma membrane (under basal conditions, or following stimulation by insulin or workload) were less than those previously found in normal rat hearts tested under identical conditions. In obese rat hearts, regulation of plasma membrane transporters was perturbed. The Hill coefficient (an index of positive cooperativity amongst glucose transporters) was paradoxically decreased by insulin while leaving affinity values unaltered. The Hill coefficient was unaltered by workload, although the affinity values were increased compared to respective controls. To sum up, obese rat hearts have decreased total transporter number, and although the two stimuli studied favour the translocation of available transporters, they fail to "activate" them adequately once present in the plasma membrane.

Topics: 3-O-Methylglucose; Animals; Biological Transport, Active; Cell Membrane; Cytochalasin B; Heart; In Vitro Techniques; Insulin; Intracellular Membranes; Kinetics; Male; Methylglucosides; Methylglycosides; Microsomes; Monosaccharide Transport Proteins; Myocardium; Obesity; Perfusion; Rats; Rats, Mutant Strains; Rats, Zucker; Reference Values

Topics: Animals; Antigens; Arginine; Cyclic AMP; Cytochalasin B; Diabetes Mellitus; Disease Models, Animal; Dose-Response Relationship, Drug; Glucose; In Vitro Techniques; Insulin; Insulin Secretion; Iodine Radioisotopes; Islets of Langerhans; Male; Mice; Obesity; Radioimmunoassay; Rats; Secretory Rate; Theophylline; Time Factors; Vincristine

Topics: Acetates; Adipose Tissue; Animals; Carbon Radioisotopes; Colchicine; Cytochalasin B; Glucose; Hyperglycemia; Male; Mice; Obesity; Tritium; Water