Biochemical and functional heterogeneity of rat adipocyte glucose transporters

We have studied the biochemical mechanism of insulin action on glucose transport in the rat adipocyte. Plasma membranes and low-density microsomes were prepared by differential ultracentrifugation of basal and insulin-stimulated cells. The photochemical cross-linking agent hydroxysuccinimidyl-4-azidobenzoate was used to covalently bind [3H]cytochalasin B to the glucose transporter which migrated as a 45-50-kDa protein on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Isoelectric focusing of the eluted 40-55-kDa proteins revealed two peaks of D-glucose-inhibitable [3H]cytochalasin B radioactivity focusing at pH 6.4 and 5.6 when low-density microsomes were used as the starting material. In contrast, only one D-glucose inhibitable peak, focusing at pH 5.6, was found in plasma membranes. Pretreatment of the cells with insulin led to a marked redistribution of the pH 5.6 form of the glucose transporter from low-density microsomes to plasma membranes with no effect on the pH 6.4 form of the glucose transporter. Following isolation from the isoelectric focusing and sodium dodecyl sulfate-polyacrylamide gels, both glucose transporter isoforms were shown to cross-react with an antiserum raised against the purified human erythrocyte glucose transporter. Following incubation of [3H]cytochalasin B-labeled low-density microsomal and plasma membranes with neuraminidase, the pH 5.6 transporter isoform was shifted on isoelectric focusing to a more basic pH, while the pH 6.4 isoform was not affected. These data demonstrate that: there is a heterogeneity of glucose transporter species in the intracellular pool while the plasma membrane transporters are more uniform in structure. The pH 5.6 glucose transporter isoform is translocated by insulin from the low-density microsomes to the plasma membrane but the pH 6.4 isoform is not sensitive to insulin. Differential sensitivity of the glucose transporter isoforms to neuraminidase suggests that the heterogeneity is at least partially due to differences in glycosylation state.     

Biochemical and functional characterization of the rat liver glucose-transport system. Comparisons with the adipocyte glucose-transport system.

The properties of the glucose-transport systems in rat adipocytes and hepatocytes were compared in cells prepared from the same animals. Hormones and other agents which cause a large stimulation of 3-O-methylglucose transport in adipocytes were without acute effect in hepatocytes. Hepatocytes displayed a lower affinity for 3-O-methylglucose (20 mM) and alternative substrates than adipocytes (6 mM), whereas inhibitor affinities were similar in both cell types. The concentration and distribution of glucose transporters were determined by Scatchard analysis of D-glucose-inhibitable [3H]cytochalasin B binding to subcellular fractions. In liver, most of the transporters were located in the plasma membrane (42 +/- 5 pmol/mg of protein) with a small amount (4 +/- 3 pmol/mg) in the low-density microsomal fraction ('microsomes'), the reverse of the situation in adipocytes. Glucose transporters were covalently labelled with [3H]cytochalasin B by using the photochemical cross-linking agent hydroxysuccinimidyl-4-azidobenzoate and analysed by SDS/polyacrylamide-gel electrophoresis. A single D-glucose-inhibitable peak with a molecular mass of 40-50 kDa was seen in both plasma membrane and low-density microsomes. This peak was further characterized by isoelectric focusing and revealed a single peak of specific [3H]cytochalasin B binding at pI 6.05 in both low-density microsomes and plasma membrane, compared with peaks at pI 6.4 and 5.6 in adipocyte membranes. In summary: the glucose-transport system in hepatocytes has a lower affinity and higher capacity than that in adipocytes, and is also not accurately modulated by insulin; the subcellular distribution of glucose transporters in the liver suggests that few intracellular transporters would be available for translocation; the liver transporter has a molecular mass similar to that of the adipocyte transporter; the liver glucose transporter exists as a single charged form (pI 6.05), compared with the multiple forms in adipocytes. This difference in charge could reflect a functionally important difference in molecular structure between the two cell types.     

The D-glucose transporter is tissue-specific. Skeletal muscle and adipose tissue have a unique form of glucose transporter

Using isotopic equilibration with [3H]D-glucose and measurement of D-glucose inhibitable cytochalasin B binding, I show that the erythrocytes of embryonic and newborn rats contain D-glucose transporters. On the basis of cytochalasin B binding and the time course of isotopic exchange, the number of transporters in rat embryonic erythrocytes is only 5% of that in human erythrocytes. Antibodies raised against the human erythrocyte glucose transporter were used as a probe to investigate the structural similarity between transporters. On this basis, the polypeptides of the glucose transporter of human erythrocytes and of embryonic rat erythrocytes are similar but not identical; in addition, certain antibodies showed similar reactivity toward the transporter of rat embryonic erythrocytes and that of rat brain. These antibodies, however, react with brain transporters 5 to 10 times better than with those of skeletal muscle and adipocytes suggesting that insulin responsive tissues may have a different type of glucose transporter. The cellular location of glucose transporters in skeletal muscle, determined by immunofluorescence, is on the plasma membrane or very close to the plasma membrane.     

Identification of the D-glucose-inhibitable cytochalasin B binding site as the glucose transporter in rat diaphragm plasma and microsomal membranes

[3H]Cytochalasin B binding and its competitive inhibition by D-glucose have been used to identify, the glucose transporter in plasma and microsomal membranes prepared from intact rat diaphragm. Scatchard plot analysis of [3H]cytochalasin B binding yields a binding site with a dissociation constant of roughly 110 nM. Since the inhibition constant of cytochalasin B for D-glucose uptake by diaphragm plasma membranes is similar to this value, this site is identified as the glucose transporter. Plasma membranes prepared from diaphragms bind approx. 17 pmol of cytochalasin B/mg of membrane protein to the D-glucose-inhibitable site. If 280 nM (40000 microunits/ml) insulin is present during incubation, cytochalasin B binding is increased roughly 2-fold without alteration in the dissociation constant of this site. In addition, membranes in the microsomal fraction contain 21 pmol of D-glucose-inhibitable cytochalasin B binding sites/mg of membrane protein. In the presence of insulin during incubation the number of these sites in the microsomal fraction is decreased to 9 pmol/mg of membrane protein. These results suggest that rat diaphragm contain glucose transporters with characteristics identical to those observed for the rat adipose cell glucose transporter. In addition, insulin stimulates glucose transport in rat diaphragm through a translocation of functionally identical glucose transporters from an intracellular membrane pool to the plasma membrane without an alteration in the characteristics of these sites.     

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.     

Photoaffinity labeling of insulin-sensitive hexose transporters in intact rat adipocytes. Direct evidence that latent transporters become exposed to the extracellular space in response to insulin

Irradiation of intact rat adipocytes with high intensity ultraviolet light in the presence of 0.5 microM [3H] cytochalasin B results in the labeling of Mr 43,000 and 46,000 proteins that reside in the plasma membrane fraction. In contrast to the Mr 46,000 protein, the Mr 43,000 component is not observed in the microsome fraction and exhibits lower affinity for [3H]cytochalasin B. Photolabeling of the Mr 43,000 protein is inhibited by cytochalasin D, indicating it is not a hexose transporter component. The Mr 46,000 protein exhibits characteristics expected for the glucose transporter such that D-glucose or 3-O-methylglucose but not cytochalasin D inhibits its photolabeling with [3H] cytochalasin B. Furthermore, insulin addition to intact cells either prior to or after photoaffinity labeling of the Mr 46,000 protein causes a redistribution of this component from the low density microsomes to the plasma membrane fraction, as expected for the hexose transporter. Photolabeling of transporters in both the low density microsome and plasma membrane fractions is inhibited when intact cells are equilibrated with 50 mM ethylidene glucose prior to irradiation with [3H]cytochalasin B. Incubation of intact cells with 50 mM ethylidene glucose for 1 min at 15 degrees C leads to an intracellular concentration of only 2 mM. Under these conditions, the photoaffinity labeling in intact cells of hexose transporters that fractionate with the low density microsomes is unaffected, indicating these transporters are not exposed to the extracellular medium. In contrast, photolabeling in intact insulin-treated cells of hexose transporters that fractionate with the plasma membrane is inhibited under these incubation conditions. The results demonstrate that insulin action results in the exposure to the extracellular medium of previously sequestered hexose transporters.     

Effect of physical training on glucose transporters in fat cell fractions

Physical training increases maximally insulin-stimulated glucose assimilation and 3-O-methylglucose transport in epididymal fat cells. In the present report, glucose-inhibitable cytochalasin B binding in subcellular fractions of epididymal adipocytes was measured to assess changes in number of glucose transporters induced by training. Groups of rats trained by swimming were compared to control groups of the same age, matched with respect to body weight by restricted feeding. It was found that in trained rats the number of glucose transporters in the low density microsome fractions from non-insulin-stimulated fat cells was larger than in untrained rats. In both groups of rats, insulin stimulation of adipocytes decreased the number of glucose transporters in low-density microsomes by about 60% and increased the number of glucose transporters in the plasma membrane fractions. The number of glucose transporters in the plasma membrane fractions from maximally insulin-stimulated fat cells was larger in trained rats than in control rats. [U-¹⁴C]Glucose incorporation into lipids varied in proportion to plasma membrane cytochalasin B binding per cell under all conditions tested. The results explain the enhancing effect of training on insulin responsiveness transport of hexose in fat cells.     

Identification of the d-glucose-inhibitable cytochalasin B binding site as the glucose transporter in rat diaphragm plasma and microsomal membranes

[³H]Cytochalasin B binding and its competitive inhibition by d-glucose have been used to identify the glucose transporter in plasma and microsomal membranes prepared from intact rat diaphragm. Scatchard plot analysis of [³H]cytochalasin B binding yields a binding site with a dissociation constant of roughly 110 nM. Since the inhibition constant of cytochalasin B for d-glucose uptake by diaphragm plasma membranes is similar to this value, this site is identified as the glucose transporter. Plasma membranes prepared from diaphragms bind approx. 17 pmol of cytochalasin B/mg of membrane protein to the d-glucose-inhibitable site. If 280 nM (40 000 μunits/ml) insulin is present during incubation, cytochalasin B binding is increased roughly 2-fold without alteration in the dissociation constant of this site. In addition, membranes in the microsomal fraction contain 21 pmol of d-glucose-inhibitable cytochalasin B binding sites/mg of membrane protein. In the presence of insulin during incubation the number of these sites in the microsomal fraction is decreased to 9 pmol/mg of membrane protein. These results suggest that rat diaphragm contain glucose transporters with characteristics identical to those observed for the rat adipose cell glucose transporter. In addition, insulin stimulates glucose transport in rat diaphragm through a translocation of functionally identical glucose transporters from an intracellular membrane pool to the plasma membrane without an alteration in the characteristics of these sites.     

Cycloheximide decreases glucose transporters in rat adipocyte plasma membranes without affecting insulin-stimulated glucose transport.

This study examines the relationship between insulin-stimulated glucose transport and insulin-induced translocation of glucose transporters in isolated rat adipocytes. Adipose cells were incubated with or without cycloheximide, a potent inhibitor of protein synthesis, for 60 min and then for an additional 30 min with or without insulin. After the incubation we measured 3-O-methylglucose transport in the adipose cells, and subcellular membrane fractions were prepared. The numbers of glucose transporters in the various membrane fractions were determined by the cytochalasin B binding assay. Basal and insulin-stimulated 3-O-methylglucose uptakes were not affected by cycloheximide. Furthermore, cycloheximide affected neither Vmax. nor Km of insulin-stimulated 3-O-methylglucose transport. In contrast, the number of glucose transporters in plasma membranes derived from cells preincubated with cycloheximide and insulin was markedly decreased compared with those from cells incubated with insulin alone (10.5 +/- 0.8 and 22.2 +/- 1.8 pmol/mg of protein respectively; P less than 0.005). The number of glucose transporters in cells incubated with cycloheximide alone was not significantly different compared with control cells. SDS/polyacrylamide-gel-electrophoretic analysis of [3H]cytochalasin-B-photolabelled plasma-membrane fractions revealed that cycloheximide decreases the amount of labelled glucose transporters in insulin-stimulated membranes. However, the apparent molecular mass of the protein was not changed by cycloheximide treatment. The effect of cycloheximide on the two-dimensional electrophoretic profile of the glucose transporter in insulin-stimulated low-density microsomal membranes revealed a decrease in the pI-6.4 glucose-transporter isoform, whereas the insulin-translocatable isoform (pI 5.6) was decreased. Thus the observed discrepancy between insulin-stimulated glucose transport and insulin-induced translocation of glucose transporters strongly suggests that a still unknown protein-synthesis-dependent mechanism is involved in insulin activation of glucose transport.     

Long term regulation of glucose transporters by insulin in mature 3T3-F442A adipose cells. Differential effects on two glucose transporter subtypes

The question of a long term regulatory role of insulin on adipocyte glucose transporter content was addressed using the differentiating or fully mature 3T3-F442A adipocytes. Glucose transport was measured in intact cells. Glucose transporter content in plasma membranes and low density microsomes (LDM) was assessed by cytochalasin B binding and Western analysis. In insulin- versus spontaneously differentiated adipocytes, glucose transport and glucose transporters content of plasma membranes and LDM were increased 5-, 4-, and 2-fold, respectively. Insulin deprivation for 24 h induced a redistribution of glucose transporters in those cells which then displayed 2-fold higher glucose transport and glucose transporter content in plasma membranes than spontaneously differentiated cells and 3-fold more glucose transporters in LDM. When fully insulin-differentiated adipocytes were insulin-deprived for 4 days, there was a marked decrease in glucose transporters in both membrane fractions that was fully reversible by reexposing the cells to insulin for 4 days. Glucose uptake changes were closely proportionate to changes in glucose transporter content of plasma membranes as assessed by an antiserum to the C-terminal peptide of the erythrocyte/HepG2/brain-type glucose transporter. When Western blots were immunoblotted with 1F8 monoclonal antibody, specific for glucose transporter in insulin responsive tissues, an abundant immunoreactive protein was detected in both plasma membranes and LDM but the amount of this glucose transporter did not change with insulin exposure in any membrane fractions. In conclusion, insulin plays a long term regulatory role on cultured adipocyte glucose transporter content through a selective effect on the erythrocyte/HepG2/brain-type glucose transporter.     

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.     

Immunological identification of an insulin-responsive glucose transporter

Microsomes and plasma membranes were isolated from basal and insulintreated rat adipocytes. The content of glucose transporter in these fractions, as determined by cytochalasin B binding, was 1.9 times higher in the basal microsomes than in the insulin ones and 3.3 times higher in the insulin plasma membranes than the basal ones. A 45,000 dalton polypeptide in these membrane fractions was found to react with antiserum raised against the human erythrocyte glucose transporter. This protein has been tentatively identified as the adipocyte glucose transporter because the relative amounts of it in the fractions are in approximate agreement with the values given above.     

Regulation of hexose transporters in chicken embryo fibroblasts: stimulation by the phorbol ester TPA leads to increased numbers of functioning transporters

As has been observed with many types of cultured cells, chicken embryo fibroblasts (CEF) when exposed to the tumor promoter 12-O-tetradecanoyl-phorbol-13-acetate (TPA) develop a 3- to 4-fold increase in hexose transport activity in 4 h. This increase in transport activity occurred despite a modest decline of 20% in [3H]leucine incorporation into acid insoluble fractions. Cycloheximide largely, but not completely, blocked the increase in transport activity during TPA exposure. The effects of TPA were somewhat similar to those of glucose starvation induced enhancement of hexose transport activity. Furthermore, with TPA there was no additive effect to that produced by glucose starvation. Plasma membrane enriched fractions were prepared from CEF treated with or without TPA. Membranes prepared from TPA exposed cells had a two-fold enhancement of stereospecific D-glucose transport activity as well as D-glucose inhibitable [3H]cytochalasin B binding as compared to the membranes from control CEF. There was no effect on transport when membranes were exposed to TPA in vitro. These results provide strong evidence that TPA exposure leads to an increase in the number of functioning transporters, an effect largely requiring protein synthesis.     

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.     

Reconstitution of the glucose transporter from bovine heart

Reconstitution of the glucose transporter from heart should be useful as an assay in its purification and in the study of its regulation. We have prepared plasma membranes from bovine heart which display D-glucose reversible binding of cytochalasin B (33 pmol sites/mg protein; Kd = 0.2 muM). The membrane proteins were reconstituted into liposomes by the freeze-thaw procedure. Reconstituted liposomes showed D-glucose transport activity which was stereospecific, saturable and inhibited by cytochalasin B, phloretin, and mercuric chloride. Compared to membrane proteins reconstituted directly, proteins obtained by dispersal of the membranes with low concentrations of cholate or by cholate solubilization showed 1.2- or 2.3-fold higher specific activities for reconstituted transport, respectively. SDS-polyacrylamide gel electrophoresis followed by electrophoretic protein transfer and labeling with antisera prepared against the human erythrocyte transporter identified a single band of about 45 kDa in membranes from both dog and bovine hearts, a size similar to that reported for a number of other glucose transporters in various animals and tissues.     

Studies with antipeptide antibody suggest the presence of at least two types of glucose transporter in rat brain and adipocyte

Three antipeptide antibodies were prepared by immunizing rabbits with synthesized short peptides corresponding to residues 215-226, 466-479, and 478-492 predicted from the cDNA of both the human hepatoma HepG2 and rat brain glucose transporters. All three antibodies were found to precipitate quantitatively the [3H]cytochalasin B photoaffinity-labeled human erythrocyte glucose transporter. Each antibody also recognized the rat brain protein of Mr 45,000 on immunoblots, and a similar molecular weight protein was labeled with [3H]cytochalasin B in a D-glucose-inhibitable manner, suggesting that this protein is glucose transporter. However, only up to 30% of the labeled rat brain glucose transporters were precipitated, even by repeated rounds of immunoprecipitation. In addition, these antibodies were observed to be unable to immunoprecipitate significantly the [3H]cytochalasin B-labeled rat adipocyte glucose transporter. Further, one-dimensional peptide maps of [3H]cytochalasin B-labeled human erythrocyte and adipocyte glucose transporters generated distinct tryptic fragments. Although Mr 45,000 protein in rat adipocyte low density microsomes was detected on immunoblots and its amount was decreased in insulin-treated cells, the rat adipocyte low density microsomes were much less reactive on immunoblots than the rat brain membranes in spite of the fact that the rat adipocyte low density microsomes contained more [3H]cytochalasin B-labeled glucose transporters. In addition, the ratio of cytochalasin B-labeled glucose transporter per unit HepG2-type glucose transporter mRNA was more than 10-fold higher in rat adipocyte than in rat brain. These results indicate that virtually all the human erythrocyte glucose transporters are of the HepG2 type, whereas this type of glucose transporter constitutes only approximately 30 and 3% of all the glucose transporters present in rat brain and rat adipocyte, respectively; and the rest, of similar molecular weight, is expressed by a different gene.     

Distribution of glucose transporters and insulin receptors in the plasma membrane and transverse tubules of skeletal muscle

The distribution of glucose transporters and of insulin receptors on the surface membranes of skeletal muscle was studied, using isolated plasma membranes and transverse tubule preparations. (i) Plasma membranes from rabbit skeletal muscle were prepared according to Seiler and Fleischer (1982, J. Biol. Chem. 257, 13862-13871), and transverse tubules from rabbit skeletal muscle were prepared according to Rosemblatt et al. (1981, J. Biol. Chem. 256, 8140-8148) as modified by Hidalgo et al. (1983, J. Biol. Chem. 258, 13937-13945). The membranes were identified by the abundance of nitrendipine receptors in the transverse tubules, and their relative absence from the plasma membranes. (ii) Plasma membranes and transverse tubules were also isolated from rat skeletal muscle, according to a novel procedure that isolates both fractions from the same common homogenate. (iii) Glucose transporters were detected by D-glucose protectable binding of the specific inhibitor [3H]cytochalasin B, and insulin receptors were detected by saturable binding of 125I-insulin. The concentration of glucose transporters was about threefold (rabbit) or fivefold (rat) higher in the transverse tubule membrane compared to the plasma membrane, whereas the insulin receptor concentration was about the same in both membranes. These results indicate that the glucose transporters on the surface of the muscle are preferentially segregated to the transverse tubules, and this poses interesting consequences on the functional response of glucose transport to insulin in skeletal muscle.     

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-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.     

Cytochalasin B as a probe of protein structure and substrate recognition by the galactose/H+ transporter of Escherichia coli.

Cytochalasin B is a potent inhibitor of mammalian passive glucose transporters. The recent demonstration of sequence similarities between these proteins and several bacterial proton-linked sugar transporters suggested that cytochalasin B might be a useful tool for investigation of the galactose/H+ symport protein (GalP) of Escherichia coli. Equilibrium binding studies using membranes from a GalP-constitutive (GalPc) strain of E. coli revealed a single set of high affinity binding sites for cytochalasin B with a Kd of 0.8-2.2 microM. Binding was inhibited by D-glucose, but not by L-glucose. UV irradiation of the membranes in the presence of [4-3H]cytochalasin B photolabeled principally a protein of apparent Mr 38,000, corresponding to the GalP protein. Labeling was inhibited by greater than 80% in the presence of 500 mM D-glucose or D-galactose, the major substrates of the GalP system. The extent of inhibition of photolabeling by different sugars and sugar analogues showed that the substrate specificity of GalP closely resembles that of the mammalian passive glucose transporters. Structural similarity to the latter was revealed by tryptic digestion of [4-3H]cytochalasin B-photolabeled GalP, which yielded a radiolabeled fragment of apparent Mr 17,000-19,000, similar to that previously reported for the human erythrocyte glucose transporter.