Properties of the 3-o-methyl-D-glucose transport system in Acholeplasma laidlawii.

Transport of 3-O-methyl-D-glucose (3-O-MG) by Acholeplasma laidlawii cells was studied. The 3-O-MG transport system appeared to be constitutive in cells grown on 3-O-MG and glucose; the transport process depended on the concentration of substrate used and exhibited typical saturation kinetics, with an apparent Km of 4.6 muM. 3-O-MG was transported as a free carbohydrate and was not metabolized further in the cell. Dependence on pH and temperature and the results of efflux and "counterflow" experiments demonstrated the carrier nature of the transport system. 6-Deoxyglucose and glucose competitively inhibited 3-O-MG transport, whereas maltose inhibited in non-competitively. p-Chloromercuribenzoate, p-chloromercuribenzene sulfonate, N-ethylmaleimide, and iodoacetate inhibited transport of 3-O-MG. Cells were able to accumulate 3-O-MG against a concentration gradient. Some electron transfer inhibitors (rotenone and amytal), arsenate, dicyclohexylcarbodiimide, and proton conductors such as 2,4-dinitrophenol, carbonylcyanide, m-chlorophenylhydrazone, pentachlorophenol, and tetrachlorotrifluoromethylbenzimidazole inhibited this process.     

Utilization of n-Alkanes by Cladosporium resinae

Four different isolates of Cladosporium resinae from Australian soils were tested for their ability to utilize liquid n-alkanes ranging from n-hexane to n-octadecane under standard conditions. The isolates were unable to make use of n-hexane, n-heptane, and n-octane for growth. In fact, these hydrocarbons, particularly n-hexane, exerted an inhibitory effect on spore germination and mycelial growth. All higher n-alkanes from n-nonane to n-octadecane were assimilated by the fungus, although only limited growth occurred on n-nonane and n-decane. The long chain n-alkanes (C(14) to C(18)) supported good growth of all isolates, but there was no obvious correlation between cell yields and chain lengths of these n-alkanes. Variation in growth responses to individual n-alkane among the different isolates was also observed. The cause of this variation is unknown.     

Functional limitations to glucose uptake in muscles comprised of different fiber types

Skeletal muscle glucose uptake requires delivery of glucose to the sarcolemma, transport across the sarcolemma, and the irreversible phosphorylation of glucose by hexokinase (HK) inside the cell. Here, a novel method was used in the conscious rat to address the roles of these three steps in controlling the rate of glucose uptake in soleus, a muscle comprised of type I fibers, and two muscles comprised of type II fibers. Experiments were performed on conscious rats under basal conditions or during hyperinsulinemic euglycemic clamps. Rats received primed, constant infusions of 3-O-methyl-[3H]glucose (3-O-MG) and [1-14C]mannitol. Total muscle glucose concentration and the steady-state ratio of intracellular to extracellular 3-O-MG concentration, which distributes based on the transsarcolemmal glucose gradient (TSGG), were used to calculate glucose concentrations at the inner and outer sarcolemmal surfaces ([G](im) and [G](om), respectively) in muscle. Muscle glucose uptake was much lower in muscle comprised of type II fibers than in soleus under both basal and insulin-stimulated conditions. Under all conditions, the TSGG in type II muscle exceeded that in soleus, indicating that glucose transport plays a more important role to limit glucose uptake in type II muscle. Although hyperinsulinemia increased [G](im) in soleus, indicating that phosphorylation was a limiting factor, type II muscle was limited primarily by glucose delivery and glucose transport. In conclusion, the relative importance of glucose delivery, transport, and phosphorylation in controlling the rate of insulin-stimulated muscle glucose uptake varies between muscle fiber types, with glucose delivery and transport being the primary limiting factors in type II muscle.     

Diverse effects of insulin-induced hyperpolarization on 3-O-methyl-D-glucose (3-O-MG) transport in frog skeletal muscles

It has been suggested that the insulin-induced hyperpolarization might be a mediator of the stimulatory action of insulin on glucose transport. The purpose of the present study was to investigate the relationship between the insulin-induced hyperpolarization and the stimulatory action of insulin on glucose transport in skeletal muscle. Satorius muscles dissected from bullfrogs (Rana catesbeiana) were used. Insulin induced a hyperpolarization of the membrane and an increase in the 3-O-Methyl-D-glucose (3-O-MG) uptake and extrusion. In the presence of valinomycin, insulin had no significant effect on the membrane potential. Insulin still had the stimulatory action on both the 3-O-MG uptake and extrusion even in the presence of valinomycin, under whose condition insulin had no significant effect on the membrane potential. The magnitude of the stimulatory action of insulin on the 3-O-MG uptake in the presence of valinomycin was smaller than that in the absence of valinomycin. The magnitude of the stimulatory action of insulin on the 3-O-MG extrusion was, on the contrary, larger than that in the absence of valinomycin. The abolishment of the insulin-induced hyperpolarization decreased the 3-O-MG uptake and increased the 3-O-MG extrusion. The observation in the present study concludes that insulin has two different actions on glucose transport. One of them is developed through the insulin-induced hyperpolarization, which increases the 3-O-MG uptake and decreases the 3-O-MG extrusion. The other action is irrelevant of the insulin-induced hyperpolarization and stimulates both the 3-O-MG uptake and extrusion.     

Inhibition of 3-O-methylglucose transport in human erythrocytes by forskolin

The effect of forskolin, an activator of adenylate cyclase, was investigated on glucose transport in human erythrocytes. Forskolin was found to be a potent inhibitor of 3-O-methylglucose (3-O-MG) influx in human erythrocytes. The inhibition of 3-O-MG transport was instantaneous and reversible. The inhibitory effect of forskolin was concentration-dependent, having an IC50 value of 7.5 microM. Forskolin caused a decrease in Vmax of carrier-mediated 3-O-MG transport from 35.32 to 1.56 mumol/ml of cell X min in the presence of 50 microM forskolin. Inhibition of influx was not reversed at high concentrations of 3-O-MG. In addition, forskolin inhibited the influx of other carbohydrates including galactose, ribose, and fructose. In contrast, forskolin was without effect on adenosine transport. To unravel the underlying mechanism responsible for the inhibitory action of forskolin, the possible involvement of cyclic AMP in controlling glucose transport was examined. Erythrocytes treated with 50 microM forskolin exhibited an increase in cyclic AMP content from the basal levels of 258 fmol/ml of cell to 334 fmol/ml of cell within 10 s after forskolin exposure. However, erythrocytes in which cyclic AMP was allowed to accumulate in excess of 10,000 times the basal level, by means of preincubation with exogenous cyclic AMP, displayed 3-O-MG transport indistinguishable from that of cyclic AMP-poor control cells. In view of the finding that cyclic AMP plays no discernible role in the erythrocyte 3-O-MG transport, it is suggested that the forskolin inhibition is mediated by a mechanism other than by stimulating adenylate cyclase activity. Moreover, forskolin appears to directly inactivate the 3-O-MG transport system since glucose-sensitive cytochalasin B binding to erythrocyte membranes is virtually abolished by 50 microM forskolin.     

Limitations to basal and insulin-stimulated skeletal muscle glucose uptake in the high-fat-fed rat

Rats fed a high-fat diet display blunted insulin-stimulated skeletal muscle glucose uptake. It is not clear whether this is due solely to a defect in glucose transport, or if glucose delivery and phosphorylation are also impaired. To determine this, rats were fed standard chow (control rats) or a high-fat diet (HF rats) for 4 wk. Experiments were then performed on conscious rats under basal conditions or during hyperinsulinemic euglycemic clamps. Rats received primed constant infusions of 3-O-methyl-[(3)H]glucose (3-O-MG) and [1-(14)C]mannitol. Total muscle glucose concentration and the steady-state ratio of intracellular to extracellular 3-O-MG concentration [which distributes based on the transsarcolemmal glucose gradient (TSGG)] were used to calculate glucose concentrations at the inner and outer sarcolemmal surfaces ([G](im) and [G](om), respectively) in soleus. Total muscle glucose was also measured in two fast-twitch muscles. Muscle glucose uptake was markedly decreased in HF rats. In control rats, hyperinsulinemia resulted in a decrease in soleus TSGG compared with basal, due to increased [G](im). In HF rats during hyperinsulinemia, [G](im) also exceeded zero. Hyperinsulinemia also decreased muscle glucose in HF rats, implicating impaired glucose delivery. In conclusion, defects in extracellular and intracellular components of muscle glucose uptake are of major functional significance in this model of insulin resistance.     

Na+-sensitive component of 3-O-methylglucose uptake in frog skeletal muscle

Summary A Na⁺-sensitive uptake of 3-O-methylglucose (3-O-MG), a nonmetabolized sugar, was characterized in frog skeletal muscle. A removal of Na⁺ from the bathing solution reduced 3-O-MG uptake, depending on the amount of Na⁺ removed. At a 3-O-MG concentration of 2mm, the Na⁺-sensitive component of uptake in Ringer's solution was estimated to be about 26% of the total uptake. The magnitude of Na⁺-sensitive component sigmoidally increased with an increase of 3-O-MG in bathing solution, whereas in Na⁺-free Ringer's solution the uptake was proportional to the concentration. The half saturation of the Na⁺-sensitive component was at a 3-O-MG concentration of about 13mm, and the Hill coefficient was 1.4 to 1.6. Phlorizin (5mm), a potent inhibitor specific for Na⁺-coupled glucose transport, reduced the uptake in a solution containing Na⁺ to the level in Na⁺-free Ringer's solution. Glucose of concentrations higher than 20mm suppressed 3-O-MG uptake to a level slightly lower than that in Na⁺-free Ringer's solution. These observations indicate that there are Na⁺-coupled sugar transport systems in frog skeletal muscle which are shared by both glucose and 3-O-MG.     

Uptake and Metabolism of d-Glucose by Neocosmospora vasinfecta E. F. Smith

Freshly harvested, nongrowing mycelium of Neocosmospora vasinfecta E. F. Smith rapidly absorbed exogenous glucose but converted a greater proportion to trehalose and glucan than to respiratory CO(2). This effect was accentuated in mycelium preincubated for 3.5 hours in water before exposure to glucose. Glucose was absorbed via two uptake systems, both apparently constitutive, with apparent Km values for glucose of 0.02 mm (high affinity) and 2 mm (low affinity). The glucose derivative 3-O-methylglucose (3-O-MG) was also absorbed by two apparently constitutive systems with apparent Km values for 3-O-MG of 0.065 mm and 1.9 mm. Absorption of 3-O-MG by both freshly harvested and preincubated mycelium led to its accumulation. Freshly harvested mycelium lost accumulated 3-O-MG rapidly to water, whereas preincubated mycelium showed reduced or no leakage. The reduction in leakage due to preincubation was prevented by 5 mug/ml cycloheximide in the preincubation medium. Glucose competitively inhibited 3-O-MG uptake via the high affinity system and induced loss of previously accumulated 3-O-MG from preincubated mycelium. The uptake of both glucose and 3-O-MG was associated with a transient alkalinization of the uptake medium. It is concluded that uptake of both glucose and 3-O-MG by at least the high affinity system is energy-linked and probably mediated by proton cotransport.     

Effect of K+ channel-blockers on sugar uptake by isolated chicken enterocytes

The effects of Ba2+, quinine, verapamil, and Ca2(+)-free saline solutions on sugar active transport have been investigated in isolated chicken enterocytes. Ba2+, quinine, and verapamil, which have been shown to inhibit Ca2(+)-activated K+ channels, decreased basal and theophylline-dependent 3-O-methylglucose (3-O-MG) accumulation. Ca2(+)-free conditions reduced 3-O-MG uptake in theophylline-treated enterocytes, but it had no effect in control cells. On the other hand, the uptake of a non-actively transported sugar, 2-deoxyglucose (2-DOG), by control or theophylline-treated cells was not modified by the presence of verapamil or by Ca2(+)-removal. 3-O-MG increased ouabain-sensitive Na(+)-efflux, but had no effect on either K+ efflux or K+ uptake. However, in the presence of Ba2+, K+ uptake was stimulated by 3-O-MG, and this increase was prevented by ouabain. All these findings are discussed in terms of the role that K+ permeability may play in cellular homeostasis during sugar active transport.     

The inhibition of hexose transport and metabolism by small amounts of adenosine 5′-triphosphate in isolated rat adipocytes

The effects of ATP on glucose transport and metabolism were studied in rat adipocytes. Over a concentration range of 10–250 μm, ATP was found to inhibit several aspects of adipocyte glucose metabolism, particularly when stimulated by insulin. Much of the effect of ATP on glucose metabolism appeared related to impairment of glucose transport, reflected by inhibition of both basal and insulin-stimulated rates of 3-O-methylglucose transport. ATP inhibited the V of insulin-stimulated 3-O-methylglucose transport, but had no effect on the K_m. The inhibitory effects of ATP were much less apparent when cells were preincubated with insulin, suggesting that ATP inhibited only the components of hexose transport not yet activated by the hormone. At very high medium glucose concentrations, where transport was no longer rate limiting for metabolism, there was no inhibition of glucose oxidation by 250 μm ATP. However, when hexose transport was blocked with cytochalasin B (50 μm), a small inhibitory effect of ATP persisted on basal and insulin-stimulated glucose and fructose oxidation, suggesting that intracellular metabolism was impaired. The mechanism of the intracellular effect did not appear to be caused by uptake of exogenous ATP. These studies provide further evidence that energy metabolism may play an important role in the regulation of facilitated glucose transport.     

Ileal resection and dietary content of sucrose influence the intestinal uptake of monosaccharides

The intestinal uptake of 0.5 and 40 mM glucose, galactose, and 3-O-methyl glucose (3-O-MG) was examined in vitro in rabbits fed a high (HS) or a low (LS) sucrose diet. In animals with an intact intestinal tract, the jejunal uptake of 0.5 mM 3-O-MG was unaffected by the dietary content of sucrose, whereas the uptake of 40 mM 3-O-MG was lower in LS than HS. The uptake of 40 mM galactose was higher in LS than HS and the uptake of 0.5 mM galactose was similar in HS and LS, whereas the uptake of 0.5 mM but not 40 mM glucose was lower in LS than HS. In animals subjected 6 weeks previously to an ileal resection, the adaptive changes in the jejunal uptake of the hexoses in response to alterations in the dietary content of sucrose differed from the changes observed in rabbits with an intact intestinal tract. For example, feeding HS to ileal resected animals was associated with increased jejunal uptake of 40 mM galactose, decreased uptake of 40 mM glucose, and unchanged uptake of 40 mM 3-O-MG; whereas in control animals with an intact intestinal tract, feeding HS resulted in increased uptake of 40 mM 3-O-MG, decreased uptake of 40 mM galactose, and no change in the uptake of 40 mM glucose. A similar adaptive pattern was noted in the jejunum and ileum for the effect of dietary sucrose on the uptake of 0.5 and 40 mM glucose.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hexose transport by brain slices: Further studies on energy dependence

We studied the uptake of [3H]2-deoxyglucose [( 3H]2DG) by slices of rat cerebral cortex in vitro as a model of glucose transport by brain. Slices were incubated with [3H]2DG, or with L-[3H]glucose as a marker for diffusion; the difference between [3H]2DG uptake and L-[3H]glucose uptake was defined as net [3H]2DG transport. Net [3H]2DG transport was a function of incubation temperature, with an estimated temperature coefficient of 1.87 from 15 degrees C to 25 degrees C. The net uptake of [3H]2DG was not inhibited by phlorizin or phloretin in concentrations well above the reported Ki of these inhibitors for hexose uptake in other systems. To examine the hypothesis that [3H]2DG transport by brain slices is dependent on mitochondrial energy, we studied net [3H]2DG uptake by slices which had been preincubated in media designed to alter intracellular ATP stores. The transport process was very sensitive to inhibition by DNP, but the correlation between [3H]2DG transport and ATP levels was unclear. In contrast to our published hypothesis that the transport process required mitochondrial energy, these data indicate that dependence on energy is not absolute.     

Direct interaction of phenylarsine oxide with hexose transporters in isolated rat adipocytes

It has previously been shown that phenylarsine oxide (PhAsO), an inhibitor of protein internalization, also inhibits stereospecific uptake of D-glucose and 2-deoxyglucose in both basal and insulin-stimulated rat adipocytes. This inhibition of hexose uptake was found to be dose-dependent. PhAsO rapidly inhibited sugar transport into insulin-stimulated adipocytes, but at low concentrations inhibition was transient. Low doses of PhAsO (1 microM) transiently inhibit stereospecific hexose uptake and near total (approx. 90%) recovery of transport activity occurs within 20 min. Interestingly, once recovered, the adipocytes can again undergo rapid inhibition and recovery of transport activity upon further treatment with PhAsO (1 microM). In addition, PhAsO is shown to inhibit cytochalasin B binding to plasma membranes from insulin-stimulated adipocytes in a concentration-dependent manner which parallels the dose-response inhibition of hexose transport by PhAsO. The data presented suggest a direct interaction between the D-glucose transporter and PhAsO, resulting in inhibition of transport. The results are consistent with the current recruitment hypothesis of insulin activation of sugar transport and indicate that a considerable reserve of intracellular glucose carriers exists within fat cells.     

Ascorbic acid-dependent GLUT3 inhibition is a critical step for switching neuronal metabolism

Intracellular ascorbic acid is able to modulate neuronal glucose utilization between resting and activity periods. We have previously demonstrated that intracellular ascorbic acid inhibits deoxyglucose transport in primary cultures of cortical and hippocampal neurons and in HEK293 cells. The same effect was not seen in astrocytes. Since this observation was valid only for cells expressing glucose transporter 3 (GLUT3), we evaluated the importance of this transporter on the inhibitory effect of ascorbic acid on glucose transport. Intracellular ascorbic acid was able to inhibit (3)H-deoxyglucose transport only in astrocytes expressing GLUT3-EGFP. In C6 glioma cells and primary cultures of cortical neurons, which natively express GLUT3, the same inhibitory effect on (3)H-deoxyglucose transport and fluorescent hexose 2-[N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)amino]-2-deoxyglucose (2-NBDG) was observed. Finally, knocking down the native expression of GLUT3 in primary cultured neurons and C6 cells using shRNA was sufficient to abolish the ascorbic acid-dependent inhibitory effect on uptake of glucose analogs. Uptake assays using real-time confocal microscopy demonstrated that ascorbic acid effect abrogation on 2-NBDG uptake in cultured neurons. Therefore, ascorbic acid would seem to function as a metabolic switch inhibiting glucose transport in neurons under glutamatergic synaptic activity through direct or indirect inhibition of GLUT3.     

Sphingolipids inhibit insulin and phorbol ester stimulated uptake of 2-deoxyglucose

Studies are presented demonstrating inhibition of both insulin and phorbol myristate acetate stimulated uptake of 2-deoxyglucose uptake by 3T3-L1 fibroblasts. Greatest inhibition of uptake was seen with sphinganine while sphingosine was also potent in this regard. Ceramide inhibited phorbol myristate acetate but not insulin stimulation of uptake. It is suggested that sphingolipid inhibition of glucose transport relates to the previously demonstrated effect of corticosteroids to increase membrane sphingomyelin and inhibit glucose transport.     

Inhibition of glucose metabolism by n-hexadecane in Cladosporium (Amorphotheca) resinae.

When Cladosporium resinae is provided with n-hexadecane and glucose, n-hexadecane is used preferentially. Studies using [14C]glucose indicated that n-hexadecane did not inhibit glucose uptake but did retard oxidation of glucose to CO2 and assimilation of glucose carbon into trichloroacetic acid-insoluble material. Glucose could be recovered quantitatively from hydrocarbon-grown cells that had been transferred to glucose. Four enzymes that may be involved in glucose metabolism, hexokinase, glucose-6-phosphate dehydrogenase, glucose-phosphate isomerase, and succinate dehydrogenase, were not detected in cells grown on hexadecane but were present in cells grown on glucose. Addition of hexadecane to extracts of glucose-grown cells resulted in immediate loss of activity for each of the four enzymes, but two other enzymes did not directly involved in glucose metabolism, adenosine triphosphatase and alanine-ketoacid aminotransferase, were not inhibited by hexadecane in vitro. Cells grown on hexadecane and transferred to glucose metabolize intracellular hexadecane; after 1 day, activity of hexokinase, glucose-6-phosphate dehydrogenase, glucosephosphate isomerase, and succinate dehydrogenase could be detected and 22% of the intracellular hydrocarbon had been metabolized. Hexadecane-grown cells transferred to glucose plus cycloheximide showed the same level of activity of all the four enzymes as cells transferred to glucose alone. Thus, intracellular n-hexadecane or a metabolite of hexadecane can inthesis of those enzymes is not inhibited.     

Glucose uptake by the cellulolytic ruminal anaerobe Bacteroides succinogenes.

Glucose uptake by Bacteroides succinogenes S85 was measured under conditions that maintained anaerobiosis and osmotic stability. Uptake was inhibited by compounds which interfere with electron transport systems, maintenance of proton or metal ion gradients, or ATP synthesis. The most potent inhibitors were proton and metal ionophores. Oxygen strongly inhibited glucose uptake. Na+ and Li+, but not K+, stimulated glucose uptake. A variety of sugars, including alpha-methylglucoside, did not inhibit glucose uptake. Only cellobiose and 2-deoxy-D-glucose were inhibitory, but neither behaved as a competitive inhibitor. Metabolism of both sugars appeared to be responsible for the inhibition. Cells grown in cellobiose medium transported glucose at one-half the rate of glucose-grown cells. Spheroplasts transported glucose as well as whole cells, indicating glucose uptake is not dependent on a periplasmic glucose-binding protein. Differences in glucose uptake patterns were detected in cells harvested during the transition from the lag to the log phase of growth compared with cells obtained during the log phase. These differences were not due to different mechanisms for glucose uptake in the cell types. Based on the results of this study, B. succinogenes contains a highly specific, active transport system for glucose. Evidence of a phosphoenolpyruvate-glucose phosphotransferase system was not found.     

Nigericin inhibits insulin-stimulated glucose transport in 3T3-L1 adipocytes

We used nigericin, a K+/H+ exchanger, to test whether glucose transport in 3T3-L1 adipocytes was modulated by changes in intracellular pH. Our results showed that nigericin increased basal but decreased insulin-stimulated glucose uptake in a time- and dose-dependent manner. Whereas the basal translocation of GLUT1 was enhanced, insulin-stimulated GLUT4 translocation was inhibited by nigericin. On the other hand, the total amount of neither transporter protein was altered. The finding that insulin-stimulated phosphoinositide 3-kinase (PI 3-kinase) activity was not affected by nigericin implies that nigericin exerted its inhibition at a step downstream of PI 3-kinase activation. At maximal dose, nigericin rapidly lowered cytosolic pH to 6.7; however, this effect was transient and cytosolic pH was back to normal in 20 min. Removal of nigericin from the incubation medium after 20 min abolished its enhancing effect on basal but had little influence on its inhibition of insulin-stimulated glucose transport. Moreover, lowering cytosolic pH to 6.7 with an exogenously added HCl solution had no effect on glucose transport. Taken together, it appears that nigericin may inhibit insulin-stimulated glucose transport mainly by interfering with GLUT4 translocation, probably by a mechanism not related to changes in cytosolic pH.     

Isolation of Eikenella corrodens in a General Hospital

The carbon source markedly influenced the qualitative and quantitative composition of cellular hydrocarbons in Cladosporium resinae. Total lipid and hydrocarbon content was greater in cells grown on n-alkanes than in cells grown on glucose or glutamic acid. Glucose-grown cells contained a spectrum of aliphatic hydrocarbons from C(7) to C(36); pristane and n-hexadecane comprised 98% of the total. Cells grown on glutamic acid contained C(7) to C(23) hydrocarbons; n-tridecane, n-tetradecane, n-hexadecane, and pristane made up 74% of the total. n-Decane-grown cells yielded C(8) to C(32) compounds, and n-hexadecane (96%) was the major hydrocarbon. Cells grown on individual n-alkanes from C(11) to C(15) all contained C(11) to C(28) hydrocarbons, and cells grown on n-hexadecane contained C(11) to C(32) hydrocarbons. In n-undecane-grown cells, n-hexadecane and pristane made up 92% of the total, but in cells grown on C(12) to C(16)n-alkanes the major cellular hydrocarbon was the one on which the cells were grown. This suggests that cells cultured on n-alkanes of C(12) or longer accumulate n-alkanes prior to oxidizing them.     

A GSK-3/TSC2/mTOR pathway regulates glucose uptake and GLUT1 glucose transporter expression

Glucose transport is a highly regulated process and is dependent on a variety of signaling events. Glycogen synthase kinase-3 (GSK-3) has been implicated in various aspects of the regulation of glucose transport, but the mechanisms by which GSK-3 activity affects glucose uptake have not been well defined. We report that basal glycogen synthase kinase-3 (GSK-3) activity regulates glucose transport in several cell types. Chronic inhibition of basal GSK-3 activity (8-24 h) in several cell types, including vascular smooth muscle cells, resulted in an approximately twofold increase in glucose uptake due to a similar increase in protein expression of the facilitative glucose transporter 1 (GLUT1). Conversely, expression of a constitutively active form of GSK-3beta resulted in at least a twofold decrease in GLUT1 expression and glucose uptake. Since GSK-3 can inhibit mammalian target of rapamycin (mTOR) signaling via phosphorylation of the tuberous sclerosis complex subunit 2 (TSC2) tumor suppressor, we investigated whether chronic GSK-3 effects on glucose uptake and GLUT1 expression depended on TSC2 phosphorylation and TSC inhibition of mTOR. We found that absence of functional TSC2 resulted in a 1.5-to 3-fold increase in glucose uptake and GLUT1 expression in multiple cell types. These increases in glucose uptake and GLUT1 levels were prevented by inhibition of mTOR with rapamycin. GSK-3 inhibition had no effect on glucose uptake or GLUT1 expression in TSC2 mutant cells, indicating that GSK-3 effects on GLUT1 and glucose uptake were mediated by a TSC2/mTOR-dependent pathway. The effect of GSK-3 inhibition on GLUT1 expression and glucose uptake was restored in TSC2 mutant cells by transfection of a wild-type TSC2 vector, but not by a TSC2 construct with mutated GSK-3 phosphorylation sites. Thus, TSC2 and rapamycin-sensitive mTOR function downstream of GSK-3 to modulate effects of GSK-3 on glucose uptake and GLUT1 expression. GSK-3 therefore suppresses glucose uptake via TSC2 and mTOR and may serve to match energy substrate utilization to cellular growth.