Characterization of vesicles containing insulin-responsive intracellular glucose transporters isolated from 3T3-L1 adipocytes by an improved procedure

Our previously described immunoadsorption method for the isolation of vesicles containing the insulin-responsive intracellular glucose transporters from 3T3-L1 adipocytes has been improved in two ways. First, the minimal number of g minutes required to sediment the plasma membranes from the cell homogenate has been determined and, as a result, the supernatant used for immunoadsorption in the new procedure contained twice as much of the intracellular transporters. Second, the immunoadsorption has been performed with affinity-purified antibodies directed against the carboxy terminal peptide of the transporter, rather than against the entire protein. 10(7) cells (10 mg protein) yielded about 12 micrograms of vesicular protein and 11 micrograms of vesicular phospholipid. The transporter constituted 3% of the protein in the vesicles; this amount equates to approx. eight copies of the transporter per 50 nm vesicle. The polypeptide composition of the vesicles was determined by gel electrophoresis and protein staining. Major components, other than the glucose transporter, are polypeptides of Mr 270,000, 245,000, 165,000 and 115,000. The vesicles contained several phosphoproteins; the major ones have a Mr of 245,000, 190,000, 115,000 and 25,000. Insulin treatment of adipocytes did not significantly change the phosphoprotein composition of the vesicles. The vesicles were not enriched in the Golgi marker enzyme, galactosyltransferase. The cellular content of the marker for the trans-Golgi reticulum, sialyltransferase, was too low to detect.     

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.     

Insulin stimulates the tyrosine phosphorylation of a 165 kDa protein that is associated with microsomal membranes of rat adipocytes

The beta-subunit of the insulin receptor possesses an insulin-stimulatable protein tyrosine kinase activity. It has been widely postulated that this activity may mediate the transduction of the insulin signal by phosphorylation of cellular substrates involved in the mechanism of insulin action. We have identified, by immunoblotting with antiphosphotyrosine antibodies, a 165 kDa protein in rat adipocytes that is rapidly phosphorylated in response to insulin. Phosphorylation of this protein (pp165) occurs within 5-10 s of exposure to 10 nM insulin, suggesting that it may be a direct substrate for the insulin receptor. This protein was recovered in an intracellular membrane that fractionates with the low-density microsomes. Using discontinuous sucrose density-gradient centrifugation, pp165-containing vesicles were separated from other vesicles of the low-density microsomes including the glucose transporter-containing vesicles, indicating that pp165 is probably not a regulatory component of the vesicles that translocate glucose transporters in response to insulin. However, pp165 may be involved in conveying receptor activation at the cell surface to an intracellular site of insulin action.     

Insulin-stimulated translocation of glucose transporters in the isolated rat adipose cells: characterization of subcellular fractions

Insulin stimulates glucose transport in rat adipose cells through the translocation of glucose transporters from an intracellular pool to the plasma membrane. A detailed characterization of the morphology, protein composition and marker enzyme content of subcellular fractions of these cells, prepared by differential ultracentrifugation, and of the distribution of glucose transporters among these fractions is now described. Glucose transporters were measured using specific D-glucose-inhibitable [3H]cytochalasin B binding. In the basal state, roughly 90% of the cells' glucose transporters are associated with a low-density microsomal, Golgi marker enzyme-enriched membrane fraction. However, the distributions of glucose transporters and Golgi marker enzyme activities over all fractions are clearly distinct. Incubation of intact cells with insulin increases the number of glucose transporters in the plasma membrane fraction 4-5 fold and correspondingly decreases the intracellular pool, without influencing any other characteristics of the subcellular fractions examined or the estimated total number of glucose transporters (3.7 X 10(6)/cell). Insulin does not influence the Kd of the glucose transporters in the plasma membrane fraction for cytochalasin B binding (98 nM), but lowers that in the intracellular pool (from 141 to 93 nM). The calculated turnover numbers of the glucose transporters in the plasma membrane vesicles from basal and insulin-stimulated cells are similar (15 X 10(3) mol of glucose/min per mol of transporters at 37 degrees C), whereas insulin appears to increase the turnover number in the plasma membrane of intact cells roughly 4-fold. These results suggest that (1) the intracellular pool of glucose transporters may comprise a specialized membrane species, (2) intracellular glucose transporters may undergo conformational changes during their cycling to the plasma membrane in response to insulin, and (3) the translocation of glucose transporters may represent only one component in the mechanism through which insulin regulates glucose transport in the intact cell.     

Purification of insulin-dependent exocytic vesicles containing the glucose transporter

In muscle and fat, insulin causes the cellular redistribution of glucose transporters and insulin-like growth factor II receptors from an intracellular pool of membranes (low density microsomes) to the plasma membrane. This translocation is a major mechanism by which insulin stimulates cellular glucose uptake. Our aim was to purify and characterize the insulin-regulatable exocytic intracellular membranes that are enriched in glucose transporter. Low density microsome and plasma membrane fractions were isolated from basal and insulin-stimulated rat adipocytes by differential centrifugation. In cells exposed to insulin, glucose transporters were decreased in the low density microsomes and correspondingly increased in the plasma membranes as determined by immunoblotting and cytochalasin B binding. Low density microsomes were further fractionated by sucrose density gradient centrifugation. Membranes containing glucose transporters were separated from the major protein-containing peaks and from plasma membranes, Golgi, and endoplasmic reticulum. Further fractionation was achieved by agarose gel electrophoresis. Overall, the intracellular membranes enriched in transporter were purified 9-fold compared to low density microsomes. These purified membranes had the following characteristics: 1) uniformly sized vesicles, diameter 60-100 nm; 2) insulin-regulatable protein composition, one constituent being an Mr 43,000 protein that co-migrated with immunoblotted glucose transporters; 3) enrichment in insulin-like growth factor II receptors, but of a lesser degree than the enrichment in transporters. Thus, using a three-step procedure, insulin-sensitive translocatable vesicles from adipocytes have been highly purified. These are similar in size and density to endosomes, and the glucose transporter is a major constituent of this distinct vesicle population.     

Subcellular localization and trafficking of the GLUT4 glucose transporter isoform in insulin-responsive cells

The rate-limiting step in the uptake and metabolism of Dglucose by insulin target cells is thought to be glucose transport mediated by glucose transporters (primarily the GLUT4 isoform) localized to the plasma membrane. However, subcellular fractionation, photolabelling and immunocytochemical studies have shown that the pool of GLUT4 present in the plasma membrane is only one of many subcellular pools of this protein. GLUT4 has been found in occluded vesicles at the plasma membrane, clathrin-coated pits and vesicles, early endosomes, and tubulo-vesicular structures; the latter are analogous to known specialized secretory compartments. Tracking the movement of GLUT4 through these compartments, and defining the mechanism and site of action of insulin in stimulating this subcellular trafficking, are major topics of current investigation. Recent evidence focuses attention on the exocytosis of GLUT4 as the major site of insulin action. Increased exocytosis may be due to decreased retention of glucose transporters in an intracellular pool, or possibly to increased assembly of a vesicle docking and fusion complex. Although details are unknown, the presence in GLUT4 vesicles of a synaptobrevin homologue leads us to propose that a process analogous to that occurring in synaptic vesicle trafficking is involved in the assembly of GLUT4 vesicles into a form suitable for fusion with the plasma membrane. Evidence that the pathways of signalling from the insulin receptor and of GLUT4 vesicle exocytosis may converge at the level of the key signalling enzyme, phosphatidylinositol 3-kinase, is discussed.     

Insulin-stimulated translocation of glucose transporters in the isolated rat adipose cells: Characterization of subcellular fractions

Insulin stimulates glucose transport in rat adipose cells through the translocation of glucose transporters from an intracellular pool to the plasma membrane. A detailed characterization of the morphology, protein composition and marker enzyme content of subcellular fractions of these cells, prepared by differential ultracentrifugation, and of the distribution of glucose transporters among these fractions is now described. Glucose transporters were measured using specific d-glucose-inhibitable [³H]cytochalasin B binding. In the basal state, roughly 90% of the cells' glucose transporters are associated with a low-density microsomal, Golgi marker enzyme-enriched membrane fraction. However, the distributions of glucose transporters and Golgi marker enzyme activities over all fractions are clearly distinct. Incubation of intact cells with insulin increases the number of glucose transporters in the plasma membrane fraction 4–5-fold and correspondingly decreases the intracellular pool, without influencing any other characteristics of the subcellular fractions examined or the estimated total number of glucose transporters (3.7·10⁶/cell). Insulin does not influence the K_d of the glucose transporters in the plasma membrane fraction for cytochalasin B binding (98 nM), but lowers that in the intracellular pool (from 141 to 93 nM). The calculated turnover numbers of the glucose transporters in the plasma membrane vesicles from basal and insulin-stimulated cells are similar (15·10³ mol of glucose/min per mol of transporters at 37°C), whereas insulin appears to increase the turnover number in the plasma membrane of intact cells roughly 4-fold. These results suggest that (1) the intracellular pool of glucose transporters may comprise a specialized membrane species, (2) intracellular glucose transporters may undergo conformational changes during their cycling to the plasma membrane in response to insulin, and (3) the translocation of glucose transporters may represent only one component in the mechanism through which insulin regulates glucose transport in the intact cell.     

Insulin-induced translocation of glucose transporters from post-Golgi compartments to the plasma membrane of 3T3-L1 adipocytes

A semiquantitative method using immunocytochemistry on ultrathin cryosections and the protein A-gold technique was performed to study the effect of insulin on the cellular distribution of the glucose transporters in cultured 3T3-L1 adipocytes. In basal cells a substantial portion of the label was present in a tubulovesicular structure at the trans side of the Golgi apparatus, likely to represent the trans-Golgi reticulum, and in small vesicles present in the cytoplasm. Treatment with insulin induced a rapid translocation of transporters from the tubulovesicular structure to the plasma membrane. The transporter labeling of the plasma membrane increased three-fold and that of the tubulovesicular structure decreased by half. There was no effect of insulin on the degree of label in the small cytoplasmic vesicles. Removal of insulin from stimulated cells rapidly reversed the distribution of transporters to that seen in basal cells. This study thus provides the first morphological evidence for the occurrence of transporter translocation in insulin action and identifies for the first time the intracellular location of the responsive transporters.     

Insulin regulation of the two glucose transporters in 3T3-L1 adipocytes

The amounts of the brain type and muscle type glucose transporters (designated Glut 1 and 4, respectively) in 3T3-L1 adipocytes have been determined by quantitative immunoblotting with antibodies against their carboxyl-terminal peptides. There are about 950,000 and 280,000 copies of Glut 1 and 4, respectively, per cell. Insulin caused the translocation of both types of transporters from an intracellular location to the plasma membrane. The insulin-elicited increase in cell surface transporters was assessed by labeling the surface transporters with a newly developed, membrane-impermeant, photoaffinity labeling reagent for glucose transporters. The increases in Glut 1 and 4 averaged 6.5- and 17-fold, respectively, whereas there was a 21-fold in hexose transport. These results indicate that the translocation of Glut 4 could largely account for the insulin effect on transport rate, but only if the intrinsic activity of Glut 4 is much higher than that of Glut 1. The two transporters are colocalized intracellularly: vesicles (average diameter 72 nm) isolated from the intracellular membranes by immunoadsorption with antibodies against Glut 1 contained 95% of the Glut 4 and, conversely, vesicles isolated with antibodies against Glut 4 contained 85% of the Glut 1.     

Insulin regulates soluble amyloid precursor protein release via phosphatidyl inositol 3 kinase-dependent pathway.

Several lines of biochemical evidence correlate the presence of energy metabolic defects with the functional alterations associated with brain aging and with the pathogenesis of neurodegenerative disorders such as Alzheimer's disease. Within this context we tested the ability of insulin to regulate the amyloid precursor protein (APP) processing in SH-SY5Y neuroblastoma cells. Our findings show that insulin promotes APP metabolism by a glucose-independent mechanism. We demonstrate a novel intracellular pathway that increases the rate of secretion of soluble APP through the activity of phosphatidyl-inositol 3 kinase (PI3-K). This pathway, downstream of insulin receptor tyrosine kinase activity, does not involve either the activation of protein kinase C or the mitogen-activated protein kinase (MAP-K) pathway. Because of the physiological role of PI3-K in the translocation of glucose transporter-containing vesicles, we speculate that PI3-K involvement in APP metabolism may act at the level of vesicular trafficking.     

Insulin-regulated glucose uptake in rat adipocytes is mediated by two transporter isoforms present in at least two vesicle populations

We have recently described a monoclonal antibody (1F8) that recognizes a form of glucose transporter unique to fat and muscle (James, D. E., Brown, R., Navarro, J., and Pilch, P. F. (1988) Nature 333, 183-185), tissues that respond acutely to insulin by markedly increasing their glucose uptake. Here, we report that rat adipocytes possess two immunologically distinct glucose-transporters: one recognized by 1F8, and one reactive with antibodies raised against the human erythrocyte glucose transporter. Immunoadsorption experiments indicate that these glucose transporters reside in different vesicle populations and that both transporter isoforms translocate from intracellular sites to the plasma membrane in response to insulin. The insulin-regulatable transporter resides in a unique vesicle that comprises 3% or less of the low density microsomes of fat cells and has a limited protein composition that does not include the bulk of another translocatable protein, the insulin-like growth factor II receptor. Immunoprecipitation with 1F8 of microsomal glucose transporters photoaffinity labeled with [3H]cytochalasin B brings down 90% of the label. Similarly, immunoprecipitation with 1F8 of glucose transporters from insulin-stimulated plasma membranes photolabeled with 3-[125I]iodo-4-azidophenethylamido-7-O-succinyldeacetyl-f ors kolin, another transporter-selective reagent, results in 75% of the labeled transporter localized in the immunoprecipitate. Thus, insulin action involves the combined effect of translocation from at least two vesicle pools each containing different glucose transporters. The 1F8-reactive transporter comprises the majority of the total transporter pool that is responsible for the insulin-induced increase in glucose transporter number.     

Insulin stimulates the acute release of adipsin from 3T3-L1 adipocytes

The release of adipsin, a serine proteinase with complement factor D activity, from 3T3-L1 adipocytes was measured by quantitative immunoblotting. This protein is secreted constitutively from 3T3-L1 adipocytes, and there is a 2-fold increase in the amount of adipsin released from cells treated with insulin for 1 to 10 min. Longer exposure to insulin had no further effect on the rate of adipsin release. Adipsin does not appear to be anchored by a glycosylphosphatidylinositol moiety, since adipsin which was been released with Triton X-114 from an intracellular membrane fraction partitions into the aqueous phase. Using a previously described procedure for the isolation of vesicles containing the insulin-responsive intracellular glucose transporters (GT vesicles), we show here that these GT vesicles contain an insulin-responsive pool of adipsin. Thus, insulin stimulates the secretion of a soluble protein, adipsin, as well as translocation to the plasma membrane of integral membrane proteins, including the glucose transporter, the transferrin receptors, and the insulin-like growth factor II receptor.     

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.     

Regulation of glucose transporters in diabetes

It is now widely accepted that insulin stimulates glucose metabolism in its target tissues via recruitment of transporters from a large intracellular pool to the plasma membrane. Recent studies, however, suggest a two-step model for insulin action, of transporter translocation and transporter activation. Data confirming this hypothesis for the first time are presented. It is shown that insulin significantly enhances the intrinsic activity of glucose transporters in human and rat adipose cells, in physiological as well as in diabetic state. The functional activity of transporters is impaired in the diabetic state, but surprisingly, 'diabetic' transporters exhibit normal or even enhanced intrinsic activity. In both noninsulin-dependent diabetes mellitus and streptozotocin-diabetic rats, insulin resistance is associated with 50% transporter depletion in the intracellular pool, thus leading to a decreased number of transporters appearing in the plasma membrane in response to insulin. It is concluded that impaired glucose transport in diabetes is secondary (1) to intracellular transporter depletion, and (2) to the presence of inhibitory factors interfering with the full expression of glucose transporters at the plasma membrane, thus contributing to postreceptor insulin resistance.     

Localization of transferrin receptors and insulin-like growth factor II receptors in vesicles from 3T3-L1 adipocytes that contain intracellular glucose transporters

Transferrin receptors in detergent extracts of subcellular membrane fractions prepared from 3T3-L1 adipocytes were measured by a binding assay. There was a small but significant increase (1.2-fold) in the amount of receptor in a crude plasma membrane fraction and a 40% decrease in the number of transferrin receptors in microsomal membranes prepared from insulin-treated cells, when compared with corresponding fractions from control cells. Intracellular vesicles containing insulin-responsive glucose transporters (GT) have been isolated by immunoadsorption from the microsomal fraction (Biber, J. W., and G. E. Lienhard. 1986. J. Biol. Chem. 261:16180-16184). All of the transferrin receptors in this fraction were localized in these vesicles; however, because the GT vesicles contain approximately 30-fold fewer transferrin receptors than GT, on the average only one vesicle in three contains a transferrin receptor. The binding of 125I-pentamannose 6-phosphate BSA to 3T3-L1 adipocytes at 4 degrees C was used to monitor surface insulin-like growth factor II (IGF-II)/mannose 6-phosphate receptors. Exposure of cells to insulin at 37 degrees C for 5 min resulted in a 2.5-4.5-fold increase in surface receptors. There was a corresponding 20% decrease in the amount of IGF-II receptors in the microsomal membranes prepared from insulin-treated cells, as assayed by immunoblotting. Moreover, the IGF-II receptors and GT were located in the same intracellular vesicles, since antibodies to the carboxyterminal peptide of either protein immunoadsorbed vesicles containing 70-95% of both proteins initially present in the microsomal fraction. In conjunction with other studies, these results indicate that in 3T3-L1 adipocytes, three membrane proteins (the GT, the transferrin receptor, and the IGF-II receptor) respond similarly to insulin, by redistributing to the surface from intracellular compartment(s) in which they are colocalized.     

Proposed mechanism for increased insulin-mediated glucose transport in adipose cells from young, obese Zucker rats. Large intracellular pool of glucose transporters

The mechanism for hyperresponsive insulin-mediated glucose transport in adipose cells from 30-day-old obese Zucker rats was examined. Glucose transport was assayed by measuring 3-O-methylglucose transport, and the concentration of glucose transporters was estimated by measuring specific D-glucose-inhibitable cytochalasin B binding. Insulin increased glucose transport activity by approximately 17 fmol/cell/min in cells from obese rats compared to 3 fmol/cell/min in lean littermates. Insulin increased the concentration of glucose transporters in the plasma membrane fraction by about 15 pmol/mg of membrane protein in both groups. The insulin-mediated decrease in the concentration of transporters in the low-density microsomal fraction was 30 pmol/mg of membrane protein for the obese rats compared to 15 pmol/mg of membrane protein for the lean controls. An estimated number of glucose transporters was calculated using membrane protein and enzyme recoveries for each group. Insulin increased the number of transporters in the plasma membrane by 3 X 10(6) sites/cell for the obese rats and only 0.6 X 10(6) sites/cell for the lean controls. In addition, insulin decreased the number of transporters/cell in the intracellular membrane pool by approximately 4 X 10(6) sites/cell for the obese rats and 0.9 X 10(6) sites/cells for the lean rats. The total number of transporters/cell was about 7 X 10(6) sites/cell for the obese animals and 1.6 X 10(6) sites/cell for the lean controls. In the basal state, more than 80% of these transporters were located in the intracellular pool for both the lean and obese rats. Thus, the marked hyperresponsive insulin-mediated glucose transport observed in adipose cells from 30-day-old obese Zucker rats may be the consequence of a marked increase in the number of glucose transporters in the intracellular pool.     

Insulin-mediated translocation of glucose transporters from intracellular membranes to plasma membranes: sole mechanism of stimulation of glucose transport in L6 muscle cells

Plasma membranes and light microsomes were isolated from fused L6 muscle cells. Pre-treatment of cells with insulin did not affect marker enzyme or protein distribution in isolated membranes. The number of glucose transporters in the isolated membranes was calculated from the D-glucose-protectable binding of [3H]cytochalasin B. Glucose transporter number was higher in plasma membranes and lower in intracellular membranes derived from insulin-treated cells than in the corresponding fractions from untreated cells. The net increase in glucose transporters in plasma membranes was identical to the net decrease in glucose transporters in light microsomes (2 pmol/1.23 x 10(8) cells). The fold increase in glucose transporter number/mg protein in plasma membranes (2-fold) was similar to the fold increase in glucose transport caused by insulin. This suggests that recruitment of glucose transporters from intracellular membranes to the plasma membrane is the major mechanism of stimulation of hexose transport in L6 muscle cells. This is the first report of isolation of the two insulin-sensitive membrane elements from a cell line, and the results indicate that, in contrast to rat adipocytes, there is not change in the intrinsic activity of the transporters in response to insulin.     

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.     

Endoproteolytic cleavage of TUG protein regulates GLUT4 glucose transporter translocation

To promote glucose uptake into fat and muscle cells, insulin causes the translocation of GLUT4 glucose transporters from intracellular vesicles to the cell surface. Previous data support a model in which TUG traps GLUT4-containing vesicles and tethers them intracellularly in unstimulated cells and in which insulin mobilizes this pool of vesicles by releasing this tether. Here we show that TUG undergoes site-specific endoproteolytic cleavage, which separates a GLUT4-binding, N-terminal region of TUG from a C-terminal region previously suggested to bind an intracellular anchor. Cleavage is accelerated by insulin stimulation in 3T3-L1 adipocytes and is highly dependent upon adipocyte differentiation. The N-terminal TUG cleavage product has properties of a novel 18-kDa ubiquitin-like modifier, which we call TUGUL. The C-terminal product is observed at the expected size of 42 kDa and also as a 54-kDa form that is released from membranes into the cytosol. In transfected cells, intact TUG links GLUT4 to PIST and also binds Golgin-160 through its C-terminal region. PIST is an effector of TC10α, a GTPase previously shown to transmit an insulin signal required for GLUT4 translocation, and we show using RNAi that TC10α is required for TUG proteolytic processing. Finally, we demonstrate that a cleavage-resistant form of TUG does not support highly insulin-responsive GLUT4 translocation or glucose uptake in 3T3-L1 adipocytes. Together with previous results, these data support a model whereby insulin stimulates TUG cleavage to liberate GLUT4 storage vesicles from the Golgi matrix, which promotes GLUT4 translocation to the cell surface and enhances glucose uptake.     

Recruitment of GLUT-4 glucose transporters by insulin in diabetic rat skeletal muscle

The cause of reduced insulin-stimulated glucose transport in skeletal muscle of diabetic rats was investigated. Basal and insulin-stimulated glucose uptake into hindquarter muscles of 7-day diabetic rats were 70% and 50% lower, respectively, than in nondiabetic controls. Subcellular fractionation of hindquarter muscles yielded total crude membranes, plasma membranes and intracellular membranes. The number of GLUT-4 glucose transporters was lower in crude membranes, plasma membranes and intracellular membranes, relative to non-diabetic rat muscles. These results were paralleled by reductions in D-glucose-protectable binding of cytochalasin B. Insulin caused a redistribution of GLUT-4 transporters from intracellular membranes to plasma membranes, in both control and diabetic rat muscles. This redistribution was also recorded using binding of cytochalasin B. The insulin-dependent decrement in glucose transporters in intracellular membranes was similar for both animal groups, but the gain and final amount of transporters in the plasma membrane were 50% lower in the diabetic group. The results suggest that insulin signalling and recruitment of GLUT-4 glucose transporters occur in diabetic rat muscle, and that the diminished insulin response may be due to fewer glucose transporters operating in the muscle plasma membrane.