Insulin and noradrenaline independently stimulate the translocation of glucose transporters from intracellular stores to the plasma membrane in mouse brown adipocytes.

The mechanism of the effect of noradrenaline on the transport of 3-O-methyl-D-[14C]glucose ([14C]-MG) was studied in mouse brown adipocytes. When cells were exposed to low concentrations (< 10(-8) M) of insulin, the [14C]-MG uptake by cells was enhanced by noradrenaline additively. The action of noradrenaline was mimicked by isoproterenol, and was completely blocked by propranolol. Exposing cells to noradrenaline induced both an increase in the transport activity of plasma membrane fractions and a decrease in that of microsomal fractions similar to insulin exposure, indicating that noradrenaline also induces the translocation of glucose transporters to the plasma membrane. The ratio of an increase in the transport activity of plasma membrane fraction to a decrease in the activity of microsomal fraction was lower in cells exposed to noradrenaline than in cells exposed to insulin. This quantitative disagreement suggests that there are at least two different modes involved in the regulation of the translocation of glucose transporters in mouse brown adipocytes.     

Partial characterization of the glucose transport activity in the golgi-rich fraction of fat cells

The glucose transport activity solubilized from the basal and plus insulin forms of the Golgi-rich fraction of adipocytes was partially characterized, and the results were compared with those of the activity obtained from the plus insulin form of the plasma membrane-rich fraction. The transport activity was determined in a cell-free, reconstituted, system. Prior to reconstitution, the activities in the three preparations were all (a) stable at 0°C for at least 4 h, but not at 37°C or above; (b) most stable at pH 7–9, and (c) less stable in Tes than in Tris buffer. After reconstitution, the three activities were all (d) stable at 0°C, (e) most active at pH 5.5, (f) mildly stimulated by divalent cations, (g) unaffected by insulin or 1 mM of several SH-blocking agents, (h) inhibited by heavy metal ions, 10–100 mM of monovalent salts, organic solvents, several sugar isomers, and specific sugar-transport inhibitors. The rates of d-glucose uptake by the three liposome preparations were all inhibited more strongly by 2-deoxy-d-glucose or $\text{3}\text{-O-}\text{methyl-}\text{d}\text{-glucose}$ than by d-glucose. These data indicate that the general properties of the glucose transport activity in the Golgi-rich fraction are similar to those of the activity in the plasma membrane-rich fraction.     

Insulin-stimulated glucose uptake involves the transition of glucose transporters to a caveolae-rich fraction within the plasma membrane: implications for type II diabetes.

BACKGROUND: Adipose and muscle tissues express an insulin-sensitive glucose transporter (GLUT4). This transporter has been shown to translocate from intracellular stores to the plasma membrane following insulin stimulation. The molecular mechanisms signalling this event and the details of the translocation pathway remain unknown. In type II diabetes, the cellular transport of glucose in response to insulin is impaired, partly explaining why blood-glucose levels in patients are not lowered by insulin as in normal individuals. MATERIALS AND METHODS: Isolated rat epididymal adipocytes were stimulated with insulin and subjected to subcellular fractionation and to measurement of glucose uptake. A caveolae-rich fraction was isolated from the plasma membranes after detergent solubilization and ultracentrifugal floatation in a sucrose gradient. Presence of GLUT4 and caveolin was determined by immunoblotting after SDS-PAGE. RESULTS: In freshly isolated adipocytes, insulin induced a rapid translocation of GLUT4 to the plasma membrane fraction, which was followed by a slower transition of the transporter into a detergent resistant caveolae-rich region of the plasma membrane. The insulin-stimulated appearance of transporters in the caveolae-rich fraction occurred in parallel with enhanced glucose uptake by cells. Treatment with isoproterenol plus adenosine deaminase rapidly inhibited insulin-stimulated glucose transport by 40%, and at the same time GLUT4 disappeared from the caveolae-rich fraction and from plasma membranes as a whole. CONCLUSIONS: Insulin stimulates glucose uptake in adipocytes by rapidly translocating GLUT4 from intracellular stores to the plasma membrane. This is followed by a slower transition of GLUT4 to the caveolae-rich regions of the plasma membrane, where glucose transport appears to take place. These results have implications for an understanding of the defect in glucose transport involved in type II diabetes.     

Hexose transport stimulation and membrane redistribution of glucose transporter isoforms in response to cholera toxin, dibutyryl cyclic AMP, and insulin in 3T3-L1 adipocytes

Exposure of 3T3-L1 adipocytes to 100 ng/ml of cholera toxin or 1 mM dibutyryl cyclic AMP caused a marked stimulation of deoxyglucose transport. A maximal increase of 10- to 15-fold was observed after 12-24 h of exposure, while 100 nM insulin elicited an increase of similar magnitude within 30 min. A short term exposure (4 h) of cells to cholera toxin or dibutyryl cyclic AMP resulted in a 3- to 4-fold increase in deoxyglucose transport which was associated with significant redistribution of both the HepG2/erythrocyte (GLUT1) and muscle/adipocyte (GLUT4) glucose transporters from low density microsomes to the plasma membrane fraction. Total cellular amounts of both transporter proteins remained constant. In contrast, cells exposed to cholera toxin or dibutyryl cyclic AMP for 12 h exhibited elevations in total cellular contents of GLUT1 (but not GLUT4) protein to about 1.5- and 2.5-fold above controls, respectively. Although such treatments of cells with cholera toxin (12 h) versus insulin (30 min) caused similar 10-fold enhancements of deoxyglucose transport, a striking discrepancy was observed with respect to the content of glucose transporter proteins in the plasma membrane fraction. While insulin elicited a 2.6-fold increase in the levels of GLUT4 protein in the plasma membrane fraction, cholera toxin increased the amount of this transporter by only 30%. Insulin or cholera toxin increased the levels of GLUT1 protein in the plasma membrane fraction equally (1.6-fold). Thus, a greater number of glucose transporters in the plasma membrane fraction is associated with transport stimulation by insulin compared to cholera toxin. We conclude that: 1) at early times (4 h) after the addition of cholera toxin or dibutyryl cyclic AMP to 3T3-L1 adipocytes, redistribution of glucose transporters to the plasma membrane appears to contribute to elevated deoxyglucose uptake rates, and 2) the stimulation of hexose uptake after prolonged treatment (12-18 h) of cells with cholera toxin may involve an additional increase in the intrinsic activity of one or both glucose transporter isoforms.     

Proposed mechanism of insulin-resistant glucose transport in the isolated guinea pig adipocyte. Small intracellular pool of glucose transporters

A marked resistance to the stimulatory action of insulin on glucose metabolism has previously been shown in guinea pig, compared to rat, adipose tissue and isolated adipocytes. The mechanism of insulin resistance in isolated guinea pig adipocytes has, therefore, been examined by measuring 125I-insulin binding, the stimulatory effect of insulin on 3-0-methylglucose transport and on lipogenesis from [3-3H]glucose, the inhibitory effect of insulin on glucagon-stimulated glycerol release, and the translocation of glucose transporters in response to insulin. The translocation of glucose transporters was assessed by measuring the distribution of specific D-glucose-inhibitable [3H]cytochalasin B binding sites among the plasma, and high and low density microsomal membrane fractions prepared by differential centrifugation from basal and insulin-stimulated cells. At a glucose concentration (0.5 mM) where transport is thought to be rate-limiting for metabolism, insulin stimulates lipogenesis from 30 to 80 fmol/cell/90 min in guinea pig cells and from 25 to 380 fmol/cell/90 min in rat cells with half-maximal effects at approximately 100 pM in both cell types. Insulin similarly stimulates 3-O-methylglucose transport from 0.40 to 0.70 fmol/cell/min and from 0.24 to 3.60 fmol/cell/min in guinea pig and rat fat cells, respectively. Nevertheless, guinea pig cells bind more insulin per cell than rat cells, and insulin fully inhibits glucagon-stimulated glycerol release. In addition, the differences between guinea pig and rat cells in the stimulatory effect of insulin on lipogenesis and 3-O-methylglucose transport cannot be explained by the greater cell size of the former compared to the latter (0.18 and 0.09 micrograms of lipid/cell, respectively). However, the number of glucose transporters in the low density microsomal membrane fraction prepared from basal guinea pig cells is markedly reduced compared to that from rat fat cells (12 and 70 pmol/mg of membrane protein, respectively) and the translocation of intracellular glucose transporters to the plasma membrane fraction in response to insulin is correspondingly reduced. These results suggest that guinea pig adipocytes are markedly resistant to the stimulatory action of insulin on glucose transport and that this resistance is the consequence of a relative depletion in the number of intracellular glucose transporters.     

Effects of fluorescein isothiocyanate on insulin actions in rat adipocytes.

The effects of fluorescein isothiocyanate II (FITC) on the actions of insulin in rat adipocytes were studied. When adipocytes were incubated with FITC at pH 7.4 (2 mM agent, 8 min), the cells were completely deprived of their specific insulin-binding activity and rendered unresponsive to the hormone. The effect of FITC on the insulin-binding activity was milder at pH 9.0, and cAMP phosphodiesterase in cells exposed to FITC at pH 9.0 was maximally stimulated if the insulin concentration was increased to 100 nM. Under identical conditions, however, glucose transport activity was rendered not only less sensitive but also less responsive to the hormone. When FITC was added to cells after insulin at pH 9.0, the glucose transport activity that had been stimulated by the hormone was considerably reduced. This reduction was largely, but not entirely, prevented if the cells were deprived of ATP, suggesting that FITC (a) elicited the ATP-dependent reversal of the hormonal effect and, simultaneously, (b) mildly inhibited the transport activity per se. Western blot assay of GLUT-4 (a major isoform of glucose transporter in adipocytes) indicated that FITC (a) partially blocked insulin-dependent translocation of GLUT-4 from the intracellular site to the plasma membrane while it (b) induced a mild "insulin-like" effect. It is concluded that FITC at pH 9.0 (a) renders both glucose transport and phosphodiesterase activities less insulin sensitive presumably by modifying the cellular hormone receptor and (b) makes glucose transport activity less responsive to insulin presumably by (i) blocking hormone-dependent translocation of glucose transporter and (ii) mildly inhibiting intrinsic glucose transport activity.     

Independent control of selected insulin-sensitive cell membrane and intracellular functions — the linkage of cell membrane and intracellular events controlled by insulin

Summary The effects of pH, oxidation reduction compounds and trypsin on insulin binding, hexose transport, and activation of glycogen synthase were studied utilizing rat adipocytes. In this paper the effect of pH is examined; while in the subsequent two papers the effects of glutathione and trypsin are examined. Increase in pH from 6 to 8.5 increased labelled glucose oxidation, 2-deoxyglucose transport as well as labelled insulin binding to the receptor. Enhanced insulin binding was due to an increased rate of association k₊₁ with no effect the rate of dissociation k₋₁ resulting in a decreased equilibrium dissociation constant K_D. Glycogen synthase activity was unaffected by increase in pH when adipocytes were incubated with or without glucose. Insulin in contrast to pH was effective in increasing the activity of glycogen synthase. With 2-deoxyglucose, % glycogen synthaseI activity was increased by an increase in pH. Glycogen synthase activity was thus stimulated by insulin by the direct mechanism, previously termed mechanism 1, involving the formation of a chemical mediator, and clearly distinguishable from the activation of hexose transport, previously termed mechanism 2(1). Increase in labelled glucose oxidation and in 2-deoxyglucose transport with increased pH, as well as insulin stimulation, was abolished by preincubation with trypsin, or cytochalasin B; suggesting that trypsin-sensitive and cytochalasin B-binding protein(s) presumably in the plasma membrane are involved in these effects of pH. Since increase in pH alone activates cell membrane-mediated hexose transport and insulin receptor binding under conditions where glycogen synthase is not activated, increase in pH acts presumably by a non-mediator mechanism. Insulin acts at the membrane to enhance further the effects of increased pH, via a mediator mechanism.     

Effects of temperature on basal and insulin-stimulated glucose transport activities in fat cells. Further support for the translocation hypothesis of insulin action

Effects of temperature on glucose transport in fat cells were studied. In this system, the basal (no insulin) glucose transport activity was higher at approximately 25-30 degrees C than at 37 degrees C, as previously reported (Vega, F. V., and Kono, T. (1979) Arch. Biochem. Biophys. 192, 120-127). The stimulatory effect of low temperature (or the insulin-like effect) was reversible and apparently required metabolic energy for both its forward and reverse reactions. By lowering the ATP level with 2,4-dinitrophenol, one could separately determine the insulin-like stimulatory effect of low temperature and its inhibitory effect on the transport process itself. The maximum level of stimulation by low temperature was greater at 10 degrees C than at 25-30 degrees C, but the rate of stimulation was considerably slower at 10 degrees C than at 25-30 degrees C. When cells were exposed to low temperature, the glucose transport activity in the plasma membrane-rich fraction was increased, while that in the Golgi-rich fraction was decreased. The Arrhenius plot of the basal glucose transport activity determined in the presence of dinitrophenol was apparently linear from 10 to 37 degrees C and parallel to that of the plus insulin activity measured either in the presence or absence of dinitrophenyl. Insulin itself slowly stimulated the glucose transport activity at 10 degrees C. These results are consistent with the view that (a) low temperature, like insulin, induces translocation of the glucose transport activity from an intracellular storage site to the plasma membrane, (b) insulin stimulates glucose transport activity without changing its activation energy, and (c) subcellular membranes do not entirely stop their movement at a low temperature, e.g, at 10 degrees C.     

Protein kinase C modulates insulin action in human skeletal muscle

There is good evidence from cell lines and rodents that elevated protein kinase C (PKC) overexpression/activity causes insulin resistance. Therefore, the present study determined the effects of PKC activation/inhibition on insulin-mediated glucose transport in incubated human skeletal muscle and primary adipocytes to discern a potential role for PKC in insulin action. Rectus abdominus muscle strips or adipocytes from obese, insulin-resistant, and insulin-sensitive patients were incubated in vitro under basal and insulin (100 nM)-stimulated conditions in the presence of GF 109203X (GF), a PKC inhibitor, or 12-deoxyphorbol 13-phenylacetate 20-acetate (dPPA), a PKC activator. PKC inhibition had no effect on basal glucose transport. GF increased (P < 0.05) insulin-stimulated 2-deoxyglucose (2-DOG) transport approximately twofold above basal. GF plus insulin also increased (P < 0.05) insulin receptor tyrosine phosphorylation 48% and phosphatidylinositol 3-kinase (PI 3-kinase) activity approximately 50% (P < 0.05) vs. insulin treatment alone. Similar results for GF on glucose uptake were observed in human primary adipocytes. Further support for the hypothesis that elevated PKC activity is related to insulin resistance comes from the finding that PKC activation by dPPA was associated with a 40% decrease (P < 0.05) in insulin-stimulated 2-DOG transport. Incubation of insulin-sensitive muscles with GF also resulted in enhanced insulin action ( approximately 3-fold above basal). These data demonstrate that certain PKC inhibitors augment insulin-mediated glucose uptake and suggest that PKC may modulate insulin action in human skeletal muscle.     

Cyclic AMP acutely stimulates translocation of the major insulin-regulatable glucose transporter GLUT4.

Facilitated glucose transport across plasma membranes is mediated by a family of transporters (GLUT1-GLUT5) that have different tissue distributions and Km values for transport. It has been shown that insulin stimulates glucose transport in fat and muscle tissues by causing the redistribution of one of these proteins (GLUT4) from inside the cell to the plasma membrane. Previous studies have shown that agents that change cAMP levels are able to modulate glucose transport in fat cells. The aim of this study was to investigate the mechanisms responsible for modulation of glucose transport by cAMP. 2-Deoxyglucose transport and insulin-regulatable glucose transporter (GLUT4) immunoreactivity in plasma and low density microsomal membranes were measured in adipocytes incubated for 30 min with insulin or dibutyryl-cAMP (Bt2cAMP). Low concentrations of Bt2cAMP (10 microM) increased 2-deoxyglucose uptake by translocating GLUT4 from low density microsomal membranes to the plasma membranes. Bt2cAMP at 1000 microM inhibited glucose transport below basal but further increased translocation of GLUT4. The effect of Bt2cAMP on translocation was additive to that of 7 nM insulin. We conclude that in rat adipocytes, Bt2cAMP acutely translocates GLUT4 but inhibits its activity to transport glucose.     

One transporter per vesicle: determination of the basis of the insulin effect on glucose transport

The basis for insulin stimulation of glucose transport in rat adipocytes has been investigated by determining the relative number of functional glucose transporters in the plasma and microsomal membranes from basal and insulin-treated cells. Each fraction was solubilized with cholate and then reconstituted into vesicles of about 500 A in diameter through removal of the cholate by dialysis. This procedure distributed the glucose transporters into the vesicles at a density of either one or none per vesicle. Consequently the fraction of the intravesicular volume that rapidly equilibrated with D-glucose provided an estimate of the relative number of functional transporters. By means of this one-transporter-per-vesicle method, it was found that insulin increased the number of transporters in the plasma membrane by a factor of 2.4 and decreased the number in the microsomes to 68% of the original value. These results provide independent evidence for the hypothesis that insulin causes the translocation of functional transporters from an intracellular location to the plasma membrane.     

Dissociation of insulin-stimulated glucose transport from the translocation of glucose carriers in rat adipose cells

Cycloheximide, a potent inhibitor of protein synthesis, has been used to examine the relationship between recruitment of hexose carriers and the activation of glucose transport by insulin in rat adipocytes. Adipocytes were preincubated +/- cycloheximide for 90 min then +/- insulin for a further 30 min. We measured 3-O-methylglucose uptake in intact cells and in isolated plasma membrane vesicles. The concentration of glucose transporters in plasma membranes and low density microsomes was measured using a cytochalasin B binding assay. Cycloheximide had no affect on basal or insulin-stimulated 3-O-methylglucose uptake in intact cells or in plasma membrane vesicles. However, the number of glucose carriers in plasma membranes prepared from cells incubated with cycloheximide and insulin was markedly reduced compared to that from cells incubated with insulin alone (14 and 34 pmol/mg protein, respectively). Incubation of cells with cycloheximide alone did not change the concentration of glucose carriers in either plasma membranes or in low density microsomes compared to control cells. When isolated membranes were analyzed with an antiserum prepared against human erythrocyte glucose transporter, decreased cross-reactivity was observed in plasma membranes prepared from cycloheximide/insulin-treated cells compared to those from insulin cells. The present findings indicate that incubation of adipocytes with cycloheximide greatly reduces the number of hexose carriers in the plasma membrane of insulin-stimulated cells. Despite this reduction, insulin is still able to maximally stimulate glucose uptake. Thus, these data suggest an apparent dissociation between insulin stimulation of glucose transport activity and the recruitment of glucose carriers by the hormone.     

Mechanism for markedly hyperresponsive insulin-stimulated glucose transport activity in adipose cells from insulin-treated streptozotocin diabetic rats. Evidence for increased glucose transporter intrinsic activity

The effects of insulin therapy in streptozotocin diabetic rats on the glucose transport response to insulin in adipose cells have been examined. At sequential intervals during subcutaneous insulin infusion, isolated cells were prepared and incubated with or without insulin, and 3-O-methylglucose transport was measured. Insulin treatment not only reversed the insulin-resistant glucose transport associated with diabetes, but resulted in a progressive hyperresponsiveness, peaking with a 3-fold overshoot at 7-8 days (12.1 +/- 0.3 versus 3.4 +/- 0.1 fmol/cell/min, mean +/- S.E.) and remaining elevated for more than 3 weeks. During the peak overshoot, glucose transporters in subcellular membrane fractions were assessed by cytochalasin B binding. Insulin therapy restored glucose transporter concentration in the plasma membranes of insulin-stimulated cells from a 40% depleted level previously reported in the diabetic state to approximately 35% greater than control (38 +/- 4 versus 28 +/- 2 pmol/mg of membrane protein). Glucose transporter concentration in the low-density microsomes from basal cells was also restored from an approximately 45% depleted level back to normal (50 +/- 4 versus 50 +/- 6 pmol/mg of membrane protein), whereas total intracellular glucose transporters were further increased due to an approximately 2-fold increase in low-density microsomal membrane protein. However, these increases remained markedly less than the enhancement of insulin-stimulated glucose transport activity in the intact cell. Thus, insulin treatment of diabetic rats produces a marked and sustained hyperresponsive insulin-stimulated glucose transport activity in the adipose cell with little more than a restoration to the non-diabetic control level of glucose transporter translocation. Because this enhanced glucose transport activity occurs through an increase in Vmax, insulin therapy appears to be associated with a marked increase in glucose transporter intrinsic activity.     

Translocation hypothesis of insulin action on glucose transport

This article reviews the experimental data that support the translocation hypothesis of insulin action on glucose transport in adipocytes. According to this hypothesis, 1) most of the glucose transport mechanism in the basal (no insulin) form of fat cells is associated with an unidentified subcellular structure (the storage site), which is separated into the Golgi-rich fraction by centrifugation, and 2) the function of insulin is to induce translocation of the glucose transport mechanism from the above storage site to the plasma membrane. This translocation of the transport mechanism is reversible, dependent on metabolic energy, and independent of protein synthesis.     

Inhibition of IRS-1 phosphorylation and the alterations of GLUT4 in isolated adipocytes from cachectic tumor-bearing rats

Cellular and molecular mechanisms of insulin resistance in isolated adipocytes from methylcholanthrene-induced sarcoma-bearing rats were investigated by measuring 3-O-[14C]methyl glucose transport activity, glucose transporter-4 (GLUT4) protein in both plasma membrane and low-density microsomes, and insulin-stimulated tyrosine phosphorylation of the insulin receptor (IR) and insulin receptor substrate-1 (IRS-1). Compared to both pair-fed and freely fed controls, tumor-bearing rats (TBR) had a decreased insulin-stimulated glucose transport activity with a lower Vmax and a higher EC50. GLUT4 protein in low-density microsomes from adipocytes maintained at the basal state was less in TBR than in controls. In insulin-stimulated adipocytes, GLUT4 protein in plasma membranes was also less in tumor-bearing rats than in controls. Insulin-induced tyrosine phosphorylation of IRS-1 was less in TBR than controls, but that of the IR was similar among the three groups. These data suggest that the insulin resistance seen in adipose cells of these tumor-bearing rats was caused in part by a decreased amount of GLUT4 protein in both basal and insulin-stimulated states resulting from the selective inhibition of insulin-stimulated phosphorylation of IRS-1.     

Insulin-responsive glucose transporters are concentrated in a cell surface-derived membrane fraction of 3T3-L1 adipocytes

The recently proposed mechanistic concept of a receptor-regulated entrance compartment for hexose transport formed by microvilli on 3T3-L1 adipocytes predicted a preferential localization of glucose transporters in these structures. The cytochalasin B-binding technique was used to determine in basal and insulin-stimulated cells the distribution of glucose transporters between plasma membranes, low density microsomes (LDM) and two cell surface-derived membrane fractions prepared by a hydrodynamic shearing technique. The shearing procedure applied prior to homogenization yielded a low density surface-derived vesicle (LDSV) fraction which contained nearly 60% of the cellular glucose transporters and the total insulin-sensitive transporter pool. The rest of the glucose transporter population was localized within the plasma membrane (5%) and the LDM fraction (37%). Pretreatment of the cells with insulin (20 mU/ml for 10 min) reduced the transporter content of the LDSV fraction by 40% and increased that of the plasma membrane fraction 4-fold. The transporter containing LDSV fraction was clearly differentiated from the LDM fraction by its low specific galactosyltransferase activity and its insulin-sensitivity. Scanning electron microscopy revealed that the LDSV fraction contained a rather uniform population of spherical vesicles of 100-200 nm in diameter.     

Protein synthesis inhibitors activate glucose transport without increasing plasma membrane glucose transporters in 3T3-L1 adipocytes

In this study, we tested the hypothesis that hexose transport regulation may involve proteins with relatively rapid turnover rates. 3T3-L1 adipocytes, which exhibit 10-fold increases in hexose transport rates within 30 min of the addition of 100 nM insulin, were utilized. Exposure of these cells to 300 microM anisomycin or 500 microM cycloheximide caused a maximal, 7-fold increase in 2-deoxyglucose transport rate after 4-8 h. The effects due to either insulin (0.5 h) or anisomycin (5 h) on the kinetics of zero-trans 3-O-methyl[14C]glucose transport were similar, resulting in 2.5-3-fold increases in apparent Vmax values (control Vmax = 1.6 +/- 0.3 x 10(-7) mmol/s/10(6) cells) coupled with approximately 2-fold decreases in apparent Km values (control Km = 23 +/- 3.3 mM). Insulin elicited the expected increases in plasma membrane levels of HepG2/erythrocyte (GLUT1) and muscle/adipocyte (GLUT4) transporters (1.6- and 2.8-fold, respectively) as determined by protein immunoblotting. In contrast, neither total cellular contents nor plasma membrane levels of these two transporter isoforms were increased when 3T3-L1 adipocytes were treated with either anisomycin or cycloheximide. 3-[125I]Iodo-4-azidophenethylamido-7-O-succinyldeacetylforskoli n labeling of glucose transporters in plasma membrane fractions of similarly treated cells was also unaffected by these agents. Thus, a striking discrepancy was observed between the marked increase in cellular hexose transport rates due to these protein synthesis inhibitors and the unaltered amounts of glucose transporter proteins in the plasma membrane fraction. These data indicate that short-term protein synthesis inhibition in 3T3-L1 adipocytes leads to large increases in the intrinsic catalytic activity of one or both of the GLUT1 and GLUT4 transporter isoforms.     

Rapid preparation of a plasma membrane fraction from adipocytes and muscle cells: application to detection of translocated glucose transporter 4 on the plasma membrane

The aim of this study was to establish a rapid preparation of plasma membrane from adipocytes and muscle cells to detect translocated glucose transporter (GLUT) 4. A plasma membrane fraction was prepared by sequential centrifugation with buffer containing detergents, and its purity was estimated by detecting insulin receptor beta-subunit (IRbeta). After insulin stimulus, GLUT4 translocation was observed in 3T3-L1 adipocytes and L6 myotubes. It was found that IRbeta and GLUT4 levels on the plasma membrane decreased in adipose and muscle with intake of a 29% lard diet for 14 weeks. Hence, this method should be useful for rapid preparation of the plasma membrane fraction.     

Characterization of the stimulatory action of insulin on insulin-like growth factor II binding to rat adipose cells. Differences in the mechanism of insulin action on insulin-like growth factor II receptors and glucose transporters

Insulin is known to increase the number of cell surface insulin-like growth factor II (IGF-II) receptors in isolated rat adipose cells through a subcellular redistribution mechanism similar to that for the glucose transporter. The effects of insulin on these two processes, therefore, have now been directly compared in the same cell preparations. 1) Insulin increases the steady state number of cell surface IGF-II receptors by 7-13-fold without affecting receptor affinity; however, insulin stimulates glucose transport activity by 25-40-fold. 2) The insulin concentration required for half-maximal stimulation of cell surface IGF-II receptor number is approximately 30% lower than that for the stimulation of glucose transport activity. 3) The half-time for the achievement of insulin's maximal effect at 37 degrees C is much shorter for IGF-II receptor number (approximately 0.8 min) than for glucose transport activity (approximately 2.6 min). 4) Reversal of insulin's action at 37 degrees C occurs more rapidly for cell surface IGF-II receptors (t1/2 congruent to 2.9 min) than for glucose transport activity (t1/2 congruent to 4.9 min). 5) When the relative subcellular distribution of IGF-II receptors is examined in basal cells, less than 10% of the receptors are localized to the plasma membrane fraction indicating that most of the receptors, like glucose transporters, are localized to an intracellular compartment. However, in response to insulin, the number of plasma membrane IGF-II receptors increases only approximately 1.4-fold while the number of glucose transporters increases approximately 4.5-fold. Thus, while the stimulatory actions of insulin on cell surface IGF-II receptors and glucose transport activity are qualitatively similar, marked quantitative differences suggest that the subcellular cycling of these two integral membrane proteins occurs by distinct processes.     

Vanadate induces the recruitment of glut-4 glucose transporter to the plasma membrane of rat adipocytes

Summary In rat adipocytes, the insulin stimulation of the rate of glucose uptake is due, at least partially, to the recruitment of glucose transporter proteins from an intracellular compartment to the plasma membrane.Vanadate is a known insulin mimetic agent and causes an increase in the rate of glucose transport in rat adipocytes similar to that seen with insulin. The objective of the present study was to determine whether vanadate exerts its effect through the recruitment of glucose transporters to the plasma membrane.We report that under conditions where vanadate stimulates the rate of 2-deoxyglucose uptake to the same extent as insulin, the concentration of GLUT-4 in the plasma membrane was increased similarly by both insulin and vanadate, and its concentration was decreased in the low density microsomal fraction. These results suggest that vanadate induces the recruitment of GLUT-4 to the plasma membrane. The effects of vanadate and insulin on the stimulation of 2-deoxyglucose uptake and recruitment of GLUT-4 were not additive.This is the first report of an effect of vanadate on the intracellular distribution of the glucose transporter.