Differential regulation of the GLUT-1 and GLUT-4 glucose transport systems by glucose and insulin in L6 muscle cells in culture

The regulation by glucose and insulin of the muscle-specific facilitative glucose transport system GLUT-4 was investigated in L6 muscle cells in culture. Hexose transport activity, mRNA expression, and the subcellular localization of the GLUT-4 protein were analyzed. As observed previously (Walker, P. S., Ramlal, T., Sarabia, V., Koivisto, U.-M., Bilan, P. J., Pessin, J. E., and Klip, A. (1990) J. Biol. Chem. 265, 1516-1523), 24 h of glucose starvation and 24 h of insulin treatment each increase glucose transport activity severalfold. Here we report a differential regulation of the GLUT-4 and GLUT-1 transport systems under these conditions. (a) The level of GLUT-4 mRNA was not affected by glucose starvation and was diminished by prolonged (24 h) administration of insulin; in contrast, the level of GLUT-1 mRNA was elevated under both conditions. (b) Glucose starvation and prolonged insulin administration increased the amount of both GLUT-4 and GLUT-1 proteins in the plasma membrane. (c) In intracellular membranes, glucose starvation elevated, and prolonged insulin administration reduced, the GLUT-4 protein content. In contrast, the GLUT-1 protein content in these membranes decreased with glucose starvation and increased with insulin treatment. Glucose transport was rapidly curbed upon refeeding glucose to glucose-starved cells, with half-maximal reversal after 30 min and maximal reversal after 4 h. This was followed by a marked decrease in the levels of GLUT-1 mRNA without major changes in GLUT-4 mRNA. Neither 2-deoxy-D-glucose nor 3-O-methyl-D-glucose could substitute for D-glucose in these effects. It is proposed that glucose and insulin differentially regulate the two glucose transport systems in L6 muscle cells and that the rapid down-regulation of hexose transport activity by glucose is regulated by post-translational mechanisms.     

The effects of sulfhydryl modifying reagents on nonhormonal and hormonally regulated hexose transport in cultured human skin fibroblasts

The effects of various sulfhydryl modifying reagents on hexose transport in cultured human skin fibroblasts were studied. H2O2 was observed to have no effect on 2-deoxy-D-glucose transport in serum-starved glucose-fed cells. The elevation of hexose transport rates in cells by glucose deprivation, insulin, or serum stimulation rendered them sensitive to H2O2. Hexose transport in glucose-deprived cells was inhibited 51-55% by 1-2 mM H2O2, while hexose transport in insulin or serum-stimulated glucose-fed cells was inhibited 45% and 46%, respectively. H2O2 inhibition was blocked or reversed by 8 mM dithiothreitol. N-ethyl-maleimide (NEM), a permeant, sulfhydryl reagent, elicited effects on hexose transport similar to those effected by H2O2 (i.e., in glucose-deprived and insulin-stimulated cells, inhibition of hexose transport was 44% and 23%, respectively). Impermeant sulfhydryl reagents such as dithio(bis)nitrobenzoic acid (DTNB) and N-iodoacetyl-N'-(5-sulfo-1-naphthly-ethylenediame (1,5,-I-AEDANS) had no inhibitory effect on hexose transport under any conditions (i.e., glucose-fed, glucose-deprived, and insulin-stimulated cells). DTNB and 1,5-I-AEDANS afforded no protection from the action of H2O2 on hexose transport. The data suggest that the sensitive sites are thiol in nature and are located at an intramembrane or intracellular site and probably not exofacial.     

Regulation of glucose transport in Clone 9 cells by thyroid hormone.

Triiodothyronine (T3) is found to stimulate cytochalasin B-inhibitable glucose transport in Clone 9 cells, a 'non-transformed' rat liver cell line. After an initial lag period of more than 3 h, glucose transport rate is significantly increased at 6 h and reaches more than 3-times the control rate at 24 h. The enhancement of glucose transport by T3 is due to an increase in transport Vmax and occurs in the absence of a change in either the Km for glucose transport (approximately 3 mM) or the Ki for inhibition of transport by cytochalasin B ((1-2).10(-7) M). Consistent with the observed Ki for cytochalasin B, Northern blot analysis of RNA from control and T3-treated cells employing cDNA probes encoding GTs of the human erythrocyte/rat brain/HepG2 cell transporter (GLUT-1), rat muscle/fat cell transporter (GLUT-4), and rat liver transporter (GLUT-2) types indicates expression of only the GLUT-1 mRNA isoform in these cells. The abundance of GLUT-1 mRNA increases approx. 1.9-fold after 24 h of T3 treatment and is accompanied by an approx. 1.3-fold increase in the abundance of GLUT-1 in whole-cell extracts as demonstrated by Western blot analysis employing a polyclonal antibody directed against the 13 amino acid C-terminal peptide of GLUT-1. The more than 3-fold stimulation of glucose transport at 24 h substantially exceeds the fractional increment in transporter abundance suggesting that, in addition to increasing total GLUT-1 abundance, exposure to T3 may result in a translocation of transporters to the plasma membrane or an activation of pre-existing membrane transporter sites.     

Inhibitors of protein synthesis cause increased hexose transport in cultured human fibroblasts by a mechanism other than transporter translocation.

We have investigated the effect of various inhibitors of protein synthesis on hexose transport in human skin fibroblasts using 2-deoxy-D-glucose (2-DG) and 3-0-methyl-D-glucose (3-OMG) to measure hexose transport. Exposure of glucose-fed, serum-free cultures to cycloheximide (CHX) (50 micrograms/ml) for 6 h resulted in increased 2-DG transport (3.81 +/- .53 vs. 6.62 +/- .88 nmoles/mg protein/2 min; n = 9) and 3-OMG transport (1.36 +/- .66 vs. 3.18 +/- .83 nmoles/mg protein/30 sec; n = 4) in the CHX exposed group. Under these conditions inhibition of protein synthesis was greater than 90%. This CHX induced transport increase was time dependent (approaching maximum within 1 h of exposure to CHX) and related to an increase in the Vmax of hexose transport in the CHX exposed group (18.4 +/- 2.4 vs. 4.8 +/- 1.1 nmoles 2-DG/mg protein/min) with no difference in the transport Km (1.55 +/- .63 vs. 2.92 +/- .59 mM). Further, the CHX induced increase in hexose transport was reversible. Exposure of human fibroblasts to inhibitors of protein synthesis with different mechanisms of action (e.g., puromycin, pactamycin, or CHX) all generated hexose transport increases in a concentration-dependent fashion correlating with their increasing inhibitory effects on protein synthesis. Nucleotidase enriched (i.e., plasma membrane) fractions of control and CHX-exposed cells showed no differences in D-glucose inhibitable cytochalasin B binding activity. Further, quantitative Western analysis of nucleotidase enriched fractions indicated CHX exposure resulted in no significant increase in glucose transporter mass compared with control plasma membrane fractions. Glucose deprived cells, however, which exhibited increased sugar transport comparable to the CHX-exposed group, did show increased glucose transporter mass in the plasma membrane fraction. The data indicate that inhibitors of protein synthesis can cause a significant elevation in hexose transport and that the hexose transporter mass in the isolated plasma membrane fractions did not reflect the whole cell transport change. It is suggested that a mechanism other than glucose transporter translocation to the plasma membrane may be involved in causing this sugar transport increase.     

Regulation of glucose transporters by connective tissue activating peptide-III isoforms.

Connective tissue activating peptide-III (CTAP-III) is a component of platelet alpha-granules which elicits a series of responses in connective tissue cells referred to as activation, including increased glucose consumption and mitogenesis and increased secretion of hyaluronic acid and glycosaminoglycans. As anticipated by a requirement for glucose or glucose precursors in the activation process, an early event following CTAP-III activation of connective tissue cells is an increase in glucose transport. The present study investigates the molecular basis for this increase in glucose transport. Murine 3T3-F442A fibroblasts were found to respond to CTAP-III in a manner similar to human connective tissue cells (synovial cells, chondrocytes, skin fibroblasts). CTAP-III increases the rate of glucose transport to similar extents at 4 and 24 h, and at physiologic (micrograms/ml) concentrations of CTAP-III. A proteolytic cleavage product of recombinant CTAP-III (rCTAP-III-Leu-21 (des-1-15)), also known as neutrophil-activating peptide-2 (NAP-2), was found to be equally effective as CTAP-III, whereas NAP-1/interleukin-8, another member of the CTAP-III super-family, was ineffective in stimulating glucose transport. This contrasts with neutrophil chemotaxis, in which CTAP-III (des-1-15)/NAP-2 acts similarly to NAP-1/interleukin 8 while CTAP-III is ineffective. CTAP-III appears to elicit a different type of glucose transport response than many other growth factors in that its response is sustained (greater than or equal to 24 h) rather than transient (peak approximately 4 h) in confluent as well as in subconfluent cells. Western blot analysis using antibodies to the GLUT-1 glucose transporter revealed an increased level of GLUT-1 protein in response to CTAP-III isoforms that corresponded in magnitude (on a percentage basis) to the increased level of glucose transport. The increased levels of GLUT-1 protein in response to CTAP-III and rCTAP-III-Leu-21 (des-1-15)/NAP-2 were accompanied by an increase in levels of GLUT-1 mRNA of a magnitude sufficient to account for observed increased levels of GLUT-1. These results are consistent with CTAP-III isoforms stimulating glucose transport in connective tissue cells by increasing levels of GLUT-1 mRNA and is one of the few known instances in which increases in levels of GLUT-1 mRNA and protein are sufficient to account for observed increases in glucose transport. They also provide further evidence that CTAP-III (des-1-15)/NAP-2 binds to more than one type of receptor and that CTAP-III acts in a manner different than other well characterized growth factors (e.g. platelet-derived growth factor, transforming growth factor-beta) in that it causes a sustained (greater than or equal to 24 h) elevation in glucose transport in confluent as well as subconfluent cells.     

Differential regulation of the HepG2 and adipocyte/muscle glucose transporters in 3T3L1 adipocytes. Effect of chronic glucose deprivation.

Glucose transport in 3T3L1 adipocytes is mediated by two facilitated diffusion transport systems. We examined the effect of chronic glucose deprivation on transport activity and on the expression of the HepG2 (GLUT 1) and adipocyte/muscle (GLUT 4) glucose transporter gene products in this insulin-sensitive cell line. Glucose deprivation resulted in a maximal increase in 2-deoxyglucose uptake of 3.6-fold by 24 h. Transport activity declined thereafter but was still 2.4-fold greater than the control by 72 h. GLUT 1 mRNA and protein increased progressively during starvation to values respectively 2.4- and 7.0-fold greater than the control by 72 h. Much of the increase in total immunoreactive GLUT 1 protein observed later in starvation was the result of the accumulation of a non-functional or mistargeted 38 kDa polypeptide. Immunofluorescence microscopy indicated that increases in GLUT 1 protein occurred in presumptive plasma membrane (PM) and Golgi-like compartments during prolonged starvation. The steady-state level of GLUT 4 protein did not change during 72 h of glucose deprivation despite a greater than 10-fold decrease in the mRNA. Subcellular fractionation experiments indicated that the increased transport activity observed after 24 h of starvation was principally the result of an increase in the 45-50 kDa GLUT 1 transporter protein in the PM. The level of the GLUT 1 transporter in the PM and low-density microsomes (LDM) was increased by 3.9- and 1.4-fold respectively, and the GLUT 4 transporter content of the PM and LDM was 1.7- and 0.6-fold respectively greater than that of the control after 24 h of glucose deprivation. These data indicate that newly synthesized GLUT 1 transporters are selectively shuttled to the PM and that GLUT 4 transporters undergo translocation from an intracellular compartment to the PM during 24 h of glucose starvation. Thus glucose starvation results in an increase in glucose transport in 3T3L1 adipocytes via a complex series of events involving increased biosynthesis, decreased turnover and subcellular redistribution of transporter proteins.     

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.     

Hypoxia increases expression of selective facilitative glucose transporters (GLUT) and 2-deoxy-D-glucose uptake in human adipocytes

Hypoxia modulates the production of key inflammation-related adipokines and may underlie adipose tissue dysfunction in obesity. Here we have examined the effects of hypoxia on glucose transport by human adipocytes. Exposure of adipocytes to hypoxia (1% O₂) for up to 24 h resulted in increases in GLUT-1 (9.2-fold), GLUT-3 (9.6-fold peak at 8 h), and GLUT-5 (8.9-fold) mRNA level compared to adipocytes in normoxia (21% O₂). In contrast, there was no change in GLUT-4, GLUT-10 or GLUT-12 expression. The rise in GLUT-1 mRNA was accompanied by a substantial increase in GLUT-1 protein (10-fold), but there was no change in GLUT-5; GLUT-3 protein was not detected. Functional studies with [³H]2-deoxy-d-glucose showed that hypoxia led to a stimulation of glucose transport (4.4-fold) which was blocked by cytochalasin B. These results indicate that hypoxia increases monosaccharide uptake capacity in human adipocytes; this may contribute to adipose tissue dysregulation in obesity.     

Glucose deprivation and hexose transporter polypeptides of murine fibroblasts

The effect of Glc deprivation (starvation) on hexose transporter (GT) polypeptide(s) (pp) was studied in 3T3-C2 murine fibroblasts. Cells deprived of Glc exhibit 5-fold increases in hexose transport and Glc-displaceable cytochalasin B binding. Immunoblots of membranes reveal a Mr 55,000 GT pp in fed (4 g of Glc/liter) cells and Mr 55,000 and Mr 42,000 GT pp in starved cells. A 10-40-fold increase in total GT pp occurs upon Glc deprivation; part of this accumulation (2-5-fold) is in the Mr 55,000 GT pp, and the remaining increase is in the Mr 42,000 GT pp. During the first 12 h of Glc deprivation only the Mr 55,000 GT pp accumulates. At later times (24-72 h) the Mr 42,000 GT pp appears and constitutes a larger fraction of the total accumulation. Similarly, the Glc concentration dependence of these phenomena reveals that the Mr 55,000 GT pp accumulates at higher concentrations of Glc (less than or equal to g/liter) than the Mr 42,000 GT pp (less than or equal to 0.5 g/liter). Using alternative nutrients, sugar analogs, and inhibitors we observed that the accumulation of total GT pp is dependent upon both hexose phosphate metabolism and the interaction of substrate with the GT. The role(s) of oligosaccharide biosynthesis, protein synthesis, and the transport process itself in the Glc deprivation-induced accumulation of GT pp were examined. The appearance of the Mr 42,000 GT pp but not the Mr 55,000 GT pp was dependent upon protein synthesis. The Glc deprivation-induced accumulation of GT pp is reversible upon refeeding with Glc (4 g/liter, 12 h). This reversal was dependent upon protein synthesis. The electrophoretic mobility of the Mr 42,000 GT pp is similar to the GT pp observed after tunicamycin treatment. The Mr 55,000 but not the Mr 42,000 GT pp binds specifically to agarose-bound wheat germ agglutinin and is sensitive to endoglycosidase F digestion. Oligosaccharide-stripped GT pp and the Mr 42,000 GT pp have the same Mr. The results suggest that the accumulation of total GT pp induced by Glc deprivation is partially independent of the effect of Glc deprivation on glycoprotein biogenesis. The appearance of the Mr 42,000 GT pp with aglyco characteristics is the result of the latter. The accumulation of total GT pp, however, is the result of a specialized and sensitive adaptation of the cell to Glc deprivation. The GT pp synthesized during chronic Glc deprivation has an Mr of 42,000; fed cells synthesize the Mr 55,000 GT pp. Neither the level of in vitro translatable GT mRNA nor the rate of GT pp synthesis are increased by Glc deprivation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Regulation of hexose transport in aortic endothelial cells by vascular permeability factor and tumor necrosis factor-alpha, but not by insulin

Vascular permeability factor (VPF) is mitogenic for bovine aortic endothelial (BAE) cells, whereas tumor necrosis factor (TNF) is cytostatic and was found to completely block the mitogenic response to VPF. In contrast to the apparently antagonistic mitogenic effects that these two factors elicit, chronic exposure of BAE cells to either VPF of TNF resulted in significant (about 3-fold) increases in the rates of hexose transport. The concentrations required for half-maximal stimulation were 2 ng/ml (40 pM) for TNF and 4 ng/ml (100 pM) for VPF. Exposure to both factors simultaneously resulted in a greater stimulation of transport (about 7-fold) than exposure to either factor alone. Northern blot analysis indicated that the amount of message for the GLUT-1/erythrocyte form of the glucose transporter was specifically increased by treatment with VPF (5-fold), TNF (25-fold), or to both cytokines together (35-fold). Expression of mRNAs for the insulin-sensitive muscle/adipose transporter (GLUT-4), brain/fetal skeletal muscle transporter (GLUT-3), or the hepatic transporter (GLUT-2) were not detected in either control or treated cells. Acute or chronic exposure to insulin (10(-9) to 10(-6) M) did not activate hexose transport in BAE cells. Thus, glucose transport in aortic endothelial cells can be up-regulated by either VPF, a growth stimulator, or by TNF, a growth inhibitor, but not by insulin. The additive effect of the two cytokines together may be important in the control of increased glucose metabolism at sites of inflammation.     

Regulation of sugar transport in cultured diploid human skin fibroblasts

The regulation of hexose transport under glucose-starvation conditions was studied in cultured human skin fibroblasts. Glucose starvation enhanced the transport of 2-DG and 3-O-methyl-D-glucose (3-OMG) but not of L-glucose. Glucose-starvation enhanced transport was inhibited by cytochalasin B (10 μM). The starvation-induced change in 2-DG transport was due to an increase in the V_max of both the high and low affinity transport sites (2.8- and 2.4-fold, respectively) with no effect on their K_ms. The presence of 5.55 mM galactose, fructose, or L-glucose in the medium resulted in transport increases similar to those seen in glucose-starved cells, while the presence of 5.55 mM glucose, mannose, or 3-OMG repressed 2-DG transport. Glucose-starvation enhancement of 2-DG transport was blocked by cycloheximide (20 μg/ml) but not by actinomycin D (0.03 μg/ml) or α-amanitin (3.5 μM). Readdition of glucose (5.55 mM) for six hours to glucose-starved cells led to a rapid decrease in hexose transport that could be blocked by cycloheximide but not actinomycin D. Although readdition of 3-OMG to glucose-starved cells had little effect on reversing the transport increases, glucose plus 3-OMG were more effective than glucose alone. Serum containing cultures (10% v/v) of glucose-fed or glucose-starved cells exhibited rapid decreases in 2-DG transport when exposed to glucose-containing serum-free medium. These decreases were prevented by employing glucose-free, serum-free medium. The data indicate that hexose transport regulation in cultured human fibrob asts involves protein synthesis of hexose carriers balanced by interactions of glucose with a regulatory protein(s) and glucose metabolism as they affect the regulation and/or turnover of the carrier molecules.     

Glucose as a regulator of insulin-sensitive hexose uptake in 3T3 adipocytes

In the present study we examined the role of glucose in the regulation of its own transport activity in the cultured 3T3 fat cell. A regulatory control of glucose became apparent after these cells were cultured in the absence of glucose. Glucose deprivation of the cells was accompanied by a specific time and protein synthesis-dependent increase in dGlc (2-deoxyglucose) uptake (up to 5-fold), which was due to an increase in the apparent Vmax of the transport system. Concomitantly, the stimulatory effect of insulin on hexose uptake almost completely disappeared. Addition of glucose to the glucose-deprived cells rapidly reversed the deprivation effects. Cycloheximide experiments revealed that the glucose deprivation-induced increase in hexose uptake required protein synthesis as well as a protein synthesis-independent response to glucose deprivation that retarded the turnover of hexose transport activity. Taken together, these data indicate that glucose deprivation is accompanied by retardation of the rate of degradation, internalization, or inactivation of hexose transporters while the increase in dGlc uptake requires at least the continuation of protein synthesis-dependent de novo synthesis, insertion, or activation of hexose transporters. Hexose competitively taken up with dGlc, including the nonmetabolizable glucose analogue 3-O-methylglucose, could replace glucose in the process of prevention and reversal of the deprivation effects, indicating that competitive transport but not the metabolism of hexose is a prerequisite for the regulatory effect of glucose on the activity of its own transport system. In conclusion, our results indicate that in cultured 3T3 fat cells glucose itself is involved in the regulation of the activity of its own transport system by influencing the rate of degradation, internalization, or inactivation of hexose transporters by a protein synthesis-independent mechanism.     

Coupling of insulin-responsive glucose transport to receptors for insulin-like growth factor 1 in primary human fibroblasts

We have recently described an insulin-resistant patient with leprechaunism (leprechaun G.) having a homozygous leucine----proline mutation at amino acid position 233 in the alpha-chain of the insulin receptor. The mutation results in a loss of insulin binding to cultured fibroblasts. Fibroblasts from the patient and control individuals were used to quantify the stimulation of 2-deoxyglucose uptake by insulin and insulin-like growth factor 1 (IGF-1). Insulin hardly stimulates basal 2-deoxyglucose uptake in the patient's fibroblasts whereas in control fibroblasts the uptake of 2-deoxyglucose is stimulated by insulin approximately 1.7 times. In contrast, IGF-1 stimulates hexose uptake in the patient's fibroblasts 1.8 times, a similar value to that obtained by stimulation of control fibroblasts with insulin or IGF-1. With both types of fibroblasts, maximal IGF-1 response is reached at about 10 nM IGF-1, the ED50 being approximately 4 nM. The results indicate that the insulin responsive glucose transport in primary fibroblasts is functionally linked to the receptor for IGF-1. Insulin binds with an approximately 200-fold lower affinity to IGF-1 receptors, compared to homologous IGF-1 binding. As an insulin concentration of 10 microM is unable to give maximal stimulation of glucose uptake in the patient's fibroblasts, which is already seen with 10 nM IGF-1, it seems that occupation of IGF-1 receptors by insulin on the patient's cells is less efficient at stimulating hexose uptake compared to homologous activation.     

Evidence that erythroid-type glucose transporter intrinsic activity is modulated by cadmium treatment of mouse 3T3-L1 cells

Previous studies suggest that regulation of hexose uptake in Chinese hamster ovary fibroblasts can occur by alterations in glucose transporter intrinsic activity without changes in cell surface transporter number (Harrison, S. A., Buxton, J. M., Helgerson, A. L., MacDonald, R. G., Chlapowski, F. J., Carruthers, A., and Czech, M. P. (1990) J. Biol. Chem. 265, 5793-5801). We tested this hypothesis using 3T3-L1 fibroblasts and adipocytes which exhibit 5-6-fold increases in 2-deoxyglucose or 3-O-methylglucose uptake when exposed to low micromolar concentrations of cadmium for 18 h. Cadmium treatment decreased the apparent Km of 3T3-L1 fibroblasts for 3-O-methylglucose influx from approximately 28 to 9 mM and increased the apparent Vmax by 2-3-fold. These fibroblasts lack the skeletal muscle/adipocyte-type (GLUT4) transporter and showed only a small increase in total cellular immunoreactive HepG2 type (GLUT1) transporter in response to cadmium. Furthermore, cell surface GLUT1 levels did not change in 3T3-L1 fibroblasts exposed to cadmium, as assessed by the binding to intact cells of an antibody which recognizes an extracellular GLUT1 epitope. Insulin enhanced 2-deoxyglucose uptake 2-fold in 3T3-L1 fibroblasts, but did not further stimulate cadmium-activated transport rates. In contrast, insulin stimulated hexose transport 15-fold in 3T3-L1 adipocytes, which express both GLUT1 and GLUT4 proteins, and this effect was fully additive with the 5-fold effect of cadmium. Cadmium had little or no effect on immunoreactive GLUT1 or GLUT4 in isolated 3T3-L1 adipocyte plasma membranes. In contrast, insulin action led to marked recruitment (3-fold) of GLUT4 to the plasma membrane fraction in adipocytes treated with or without cadmium. Taken together, these data are consistent with the hypothesis that cadmium-activated sugar uptake is catalyzed by GLUT1, whereas insulin-stimulated sugar uptake is catalyzed predominantly by GLUT4 in 3T3-L1 adipocytes. Furthermore, the data suggest that the GLUT1 transporter can undergo significant increases in intrinsic catalytic activity in response to cadmium treatment of 3T3-L1 fibroblasts and adipocytes.     

Glucose deprivation induces the selective accumulation of hexose transporter protein GLUT-1 in the plasma membrane of normal rat kidney cells

Antibody to the carboxyl-terminal of hexose transporter protein GLUT-1 was used to localize this carrier in normal rat kidney (NRK) cells during D-glucose (Glc) deprivation. Glc-deprivation of NRK cells induces increased hexose transport, inhibits the glycosylation of GLUT-1, and increases the content of both native, 55,000 apparent mol wt (Mr) and aglyco, 38,000 Mr GLUT-1 polypeptides. The distribution of GLUT-1 protein in subcellular fractions isolated from Glc-fed NRK cells shows that the 55,000 Mr polypeptide is most abundant in intracellular membrane fractions. Glc-fed cells that have been tunicamycin treated contain principally the 38,000 Mr GLUT-1 polypeptide, which is found predominantly in intracellular membrane fractions. In Glc-deprived cells the 55,000 Mr GLUT-1 polypeptide localizes predominantly in the Golgi and plasma membrane fractions, whereas the more abundant 38,000 Mr GLUT-1 polypeptide is distributed throughout all membrane fractions. In Glc-deprived but fructose-fed cells only the 55,000 Mr GLUT-1 polypeptide is detected, and it is found predominantly in the plasma membrane and Golgi fractions. The localization of GLUT-1 protein was directly and specifically visualized in NRK cells by immunofluorescence microscopy. Glc-fed cells show little labeling of cell borders and a small punctate juxtanuclear pattern suggestive of localization to the Golgi and, perhaps, endoplasmic reticulum. Glc-fed cells that have been tunicamycin treated show large punctate intracellular accumulations suggestive of localization to distended Golgi and perhaps endoplasmic reticulum. Glc-deprived cells exhibited intense labeling of cell borders as well as intracellular accumulations. Glc-deprived but fructose-fed cells show fewer intracellular accumulations, and the labeling is, in general, limited to the cell borders. Our results suggest that Glc deprivation induces the selective accumulation of GLUT-1 in the plasma membrane of NRK cells.