Low-density Microsomes Research Articles

The glucose transporter GluT4 and secretory carrier membrane proteins (SCAMPs) colocalize in rat adipocytes and partially segregate during insulin stimulation.

Secretory carrier membrane proteins (SCAMPs) mark the recycling system for the insulin-responsive glucose transporter, GluT4, in rat adipocytes. Anti-GluT4 and anti-SCAMP antibodies each immunoadsorbed vesicles containing both antigens from a low density microsomal fraction that is enriched in both antigens. The immunoadsorbed vesicles also contain VAMPs (synaptobrevins), synaptic vesicle membrane proteins. All three antigens were colocalized in low density microsomal vesicles from both basal and insulin-stimulated adipocytes. The SCAMPs have the same electrophoretic mobility as a major polypeptides detected in GluT4 vesicles. During insulin stimulation, 40% each of GluT4 and VAMPs redistribute from low density microsomes to the plasma membrane fraction; however, < 10% of the SCAMPs redistribute. Immunocytochemical staining of adipose tissue shows almost complete coincidence of SCAMPs and GluT4 in the basal state and extensive redistribution of both antigens to the cell periphery during insulin stimulation. Segregation of antigens during stimulation is not as distinct as observed by fractionation, although there are regions at the cell border where the SCAMPs appear more concentrated than GluT4. These data suggest that during insulin stimulation, in contrast to the behaviour of GluT4, SCAMPs remain tightly associated with the recycling system.

Insulin- and contraction-stimulated translocation of GTP-binding proteins and GLUT4 protein in skeletal muscle.

Low molecular weight GTP-binding proteins and GLUT4 protein were isolated in purified plasma membrane and low density microsome fractions from rat skeletal muscle. GTP-binding proteins were detected via the ability of these proteins to bind [32P]GTP subsequent to Western blotting. GLUT4 protein was detected via the anti-GLUT4 antibody F349 subsequent to Western blotting. The possible involvement of GTP-binding proteins in the regulation of GLUT4 protein movement was investigated by examining the subcellular distribution of GTP-binding proteins and GLUT4 protein under basal conditions and following stimulation by insulin or muscle contraction. Insulin stimulation caused a 111 +/- 34.8% increase in the plasma membrane content of GTP-binding proteins which was paralleled by a 74 +/- 19.1% increase in the plasma membrane content of GLUT4 protein. The insulin-stimulated increase in plasma membrane GTP-binding proteins and GLUT4 protein occurred coincident with 27 +/- 4.6 and 33 +/- 7.4% decreases, respectively, in the low density microsome content of these proteins. In addition, muscle contraction significantly increased the plasma membrane content of GTP-binding proteins (63 +/- 18.1%) and GLUT4 protein (67 +/- 22.2%). However, with muscle contraction the concentrations of GTP-binding proteins and GLUT4 protein were not altered in low density microsome fractions. The similar patterns with which the GTP-binding proteins and GLUT4 protein responded to stimulation by insulin and muscle contraction suggests a possible, but yet unidentified functional relationship between these proteins.

Abundance and subcellular distribution of GTP‐binding proteins in 3T3‐L1 cells before and after differentiation to the insulin‐sensitive phenotype

The abundance and the subcellular distribution of GTP-binding proteins was studied in membrane fractions (plasma membranes and low-density microsomes) from 3T3-L1 cells before and after differentiation to the insulin-sensitive phenotype. After differentiation, the abundance of alpha i (alpha subunit of GTP-binding protein Gi), alpha o (alpha subunit of GTP-binding protein G(o)), and of a 47-kDa alpha s (alpha subunit of GTP-binding protein Gs) as detected by immunoblotting with specific antisera was reduced by 10-50% when normalized per membrane protein. In contrast, a 43-kDa alpha s was increased about threefold after differentiation. Furthermore, cholera-toxin-catalyzed ADP-ribosylation of both 43-kDa and 47-kDa alpha s was disproportionately increased ninefold and threefold, respectively, possibly reflecting the increased production of an ADP-ribosylation factor in the differentiated cells. The small GTP-binding protein Ha-ras was reduced by 50%, whereas rab1 and other small GTP-binding proteins tentatively identified as rab-isoforms (ras-homologous gene products from brain) were increased by 100% and 70%, respectively. Since the total protein content of 3T3-L1 cells was increased threefold after differentiation, the observed increase of the 43-kDa alpha s, rab1 and of the other rab isoforms was eightfold, sixfold and fivefold, respectively, when normalized/cell count. With the exception of the rab isoforms, all GTP-binding proteins were predominantly, if not exclusively, located in the plasma membrane; comparable amounts of the rab isoforms were found in plasma membranes and low-density microsomes. Insulin induced the characteristic redistribution of glucose transporters GLUT4 from low-density microsomes to the plasma membranes, but failed to alter the subcellular distribution of any of the GTP-binding proteins investigated. These data suggest that the increase in the abundance of the 43-kDa alpha s subunit and of several rab isoforms might be related to specific functions of the adipocyte-like phenotype, but that none of the investigated guanine-nucleotide-binding regulatory (G)-proteins appears to be tightly associated with the GLUT4.

Use of bismannose photolabel to elucidate insulin-regulated GLUT4 subcellular trafficking kinetics in rat adipose cells. Evidence that exocytosis is a critical site of hormone action.

The subcellular trafficking of tracer-tagged GLUT4 between the plasma membranes and low-density microsomes of rat adipose cells has been studied. Cell-surface GLUT4 have been initially tracer-tagged in the insulin-stimulated state with the [3H]bismanose photolabel 2-N-4-(1-azi-2,2,2-trifluoroethyl)benzoyl-1,3-bis-(D-mannos- 4-yloxy)-2- propylamine. The half-time for internalization of tracer-tagged GLUT4 when insulin is removed by collagenase treatment is similar to that observed for the decrease in immunodetectable GLUT4 in the plasma membranes and the decrease in glucose transport activity in the intact cells. In contrast, internalization of tracer-tagged GLUT4 also occurs when cells are maintained in the continuous presence of insulin even though the plasma membrane level of immunodetectable GLUT4 and glucose transport activity in the intact cells are unaltered. These data show, for the first time, that insulin has little, if any, effect on the rate constant for GLUT4 endocytosis, but instead, primarily increases the rate constant for exocytosis. Tracer-tagged GLUT4 that is returned to the low-density microsomes can be restimulated with fresh insulin to recycle to the plasma membranes and to a steady-state distribution level that is the same as that observed in cells that are maintained in the continuous presence of insulin. These data suggest that the cells' entire complement of GLUT4 is involved in the recycling process. Following insulin stimulation of adipose cells initially in the basal state, the increase in immunodetectable GLUT4 in the plasma membranes precedes the increase in accessibility of GLUT4 to exofacial 2-N-4-(1-azi-2,2,2-trifluoroethyl)benzoyl-1,3-bis(D-mannos-4 -yloxy)-2- propylamine photolabeling, and this in turn precedes the increase in cellular glucose transport activity. Such time course data suggest that there may be plasma membrane intermediate states in the GLUT4 trafficking pathway. The kinetic properties of GLUT4 translocation and its recycling have been interpreted in terms of a subcellular trafficking model that identifies exocytosis, possibly involving-hypothetical "docking" and "fusion" steps, as the critical site of hormone action.

Exercise training increases GLUT-4 protein in rat adipose cells.

The relative abundance and subcellular distribution of the GLUT-1 and GLUT-4 glucose transporter isoforms were determined in basal and insulin-stimulated adipose cells from wheel cage exercise-trained rats and compared with both age-matched sedentary controls and young cell size-matched sedentary controls. Exercise training increased total estimated GLUT-4 by 67 and 54% compared with age-matched and young controls, respectively. Total estimated GLUT-1 per cell was not significantly different among the three groups. Expressed per cell, plasma membrane GLUT-4 protein in basal adipose cells from exercise-trained and age-matched control rats was 2.5-fold greater than in young controls (P < 0.05) and was associated with higher basal rates of glucose transport in these cells (P < 0.02). In insulin-stimulated cells, plasma membrane GLUT-4 was 67% greater in the exercise-trained animals than young controls (P < 0.01), and 31% greater than in age-matched controls. Rates of glucose transport were correspondingly higher. In basal cells, low-density microsomal GLUT-4 from exercise-trained rats was approximately twofold greater than from age-matched controls and young controls. With insulin stimulation, GLUT-4 in low-density microsomes decreased to similar levels in all groups. We conclude that the total amount of GLUT-4 protein, but not GLUT-1, is increased in adipose cells by exercise training and that this increase in GLUT-4 is due primarily to an increase in intracellular GLUT-4.(ABSTRACT TRUNCATED AT 250 WORDS)

Insulin Induces an Unmasking of the Carboxyl Terminus of Gi Proteins in Rat Adipocytes

Several groups have shown a relationship between the insulin receptor and inhibitory G proteins, Gi. An antisera, 8729, to a peptide sequence (KNNLKDCGLF) corresponding to the carboxyl termini of Giα subunits was used to investigate this relationship by immunoelectron microscopy. Rat adipocytes were incubated in the absence or presence of 100 ng/ml insulin for 1 h and fixed for immunoelectron microscopy. Insulin-treated adipocytes stained with 8729 were labeled at the cell surface at a much higher density than control adipocytes. Subcellular fractionation of insulin-treated and control cells was followed by PAGE and Western blots of the plasma membrane and low-density microsomes with 8729. The density of the bands did not change in response to insulin treatment. Antibodies to noncarboxyl terminus sequences of the α subunit were used for immunoelectron microscopy and no difference was noted between insulin-treated and control adipocytes. These results indicated that 8729 was detecting a conformational change in the structure of Giα subunit in the plasma membrane in response to insulin. This unmasking of the carboxyl terminus was also seen in response to treatment with phenylisopropyladenosine and prostaglandin E2. Pertussis toxin-catalyzed ADP ribosylation also unmasked the carboxyl terminus. In contrast, isoproterenol, an agonist of stimulatory G proteins (Gs), did not induce an unmasking of the carboxyl terminus. These results support the hypothesis that some of insulin's effects are mediated through Gi proteins in adipocytes.

Insulin action on the internalization of the GLUT4 glucose transporter in isolated rat adipocytes

A novel method was developed to measure relative amounts of the GLUT4 glucose transporter on the surface of intact fat cells and to monitor the action of insulin on cell surface glucose transporters as they internalize into intracellular membranes. The method takes advantage of two predicted trypsin cleavage sites in the major exofacial loop of this transporter protein. Treatment of cyanide-poisoned rat adipocytes with 1 mg/ml trypsin at 37 degrees C for 30 min produced an immunoreactive GLUT4 protein species in subsequently isolated plasma membranes that migrated with higher mobility (apparent M(r) = 35,000) than native GLUT4 (apparent M(r) = 46,000) on SDS-polyacrylamide gel electrophoresis. This proteolyzed GLUT4 protein was absent in the intracellular low density microsomes. Insulin treatment of adipocytes for 20 min prior to sequential additions of cyanide and trypsin caused a 16-fold increase in the proteolytically cleaved GLUT4 species. Incubation of fresh fat cells with trypsin caused a rapid and progressive appearance of the proteolyzed GLUT4 species in the intracellular low density membranes as well as plasma membranes. After 5 min of trypsinization, 66% of the total cleaved GLUT4 in these cells had moved into the low density membranes. Insulin treatment markedly decreased the internalized cleaved GLUT4 to 20% of the total. These data indicate the following: 1) trypsinization of the GLUT4 transporter protein on intact fat cells is a convenient means to monitor the extent of transporter recruitment to the plasma membrane by insulin, as well as to estimate GLUT4 internalization rates; and 2) the action of insulin on glucose transporter redistribution to the cell surface is associated with a marked inhibition of the fraction of cell surface GLUT4 transporters internalized per unit time.

Comparison of GLUT4 and GLUT1 subcellular trafficking in basal and insulin-stimulated 3T3-L1 cells.

The two glucose transporter isoforms GLUT4 and GLUT1 present in 3T3-L1 cells were labeled in the insulin-stimulated and basal states with the impermeant bis-mannose photolabel, 2-N-4-(1-azi-2,2,2-trifluoroethyl)benzoyl-1,3-bis-(D-mannos- 4-yloxy)-2-propylamine. The redistributions of these labeled transporters from the plasma membrane to the low density microsome membrane fraction were followed while cells were maintained at either insulin-stimulated or basal steady states. In both these steady states GLUT4 and GLUT1 were continuously recycled. Analysis of the time courses for tracer-tagged GLUT4 and GLUT1 redistribution showed that the endocytosis rate constants were only approximately 30% slower in the insulin-stimulated (0.08 and 0.093 min-1) compared with the basal (0.116 and 0.121 min-1) state. In the insulin-stimulated state, the rate constants for GLUT4 and GLUT1 exocytosis (0.086 and 0.096 min-1) were similar to those of endocytosis. In contrast, the exocytosis rate constants of GLUT4 and GLUT1 in the basal state were 0.01 and 0.035 min-1. We therefore conclude that the main effect of insulin is to increase GLUT4 and GLUT1 exocytosis rate constants by approximately 9- and 3-fold, respectively, and that the unique feature of the GLUT4 isoform is the very slow rate of exocytosis in the basal state.

Biphasic alteration of glucose transport in 3T3-L1 cells during differentiation to the adipocyte-like phenotype.

Glucose transport activity and subcellular distribution of glucose transporters, GLUT1 and GLUT4 were studied in non-confluent (NCF), confluent (CF), and differentiated 3T3-L1 cells (A). During growth of the fibroblasts to confluence, basal transport activity decreased to 20% of that in non-confluent cells. Corresponding with the reduction in transport activity, the abundance of GLUT1 in plasma membranes as normalized per cell decreased by 75% during growth of the cells to confluence. This effect was mainly due to a reduction of total cellular GLUT1. In addition, the portion of GLUT1 located in intracellular vesicles (low-density microsomes) was moderately increased in confluent cells, and was further increased in cells differentiated to the adipocyte-like phenotype (in NCF 11%, in CF 24.5%, and in A 60% of the total GLUT1). GLUT4, in contrast, was approximately 10-times more abundant in low-density microsomes than in the plasma membranes of the differentiated cells. Insulin failed to stimulate glucose transport activity in non-confluent cells but produced an approximately 2-fold stimulation in confluent cells, probably through translocation of the GLUT1 from the intracellular compartment to the plasma membrane. In the differentiated adipocytes, insulin stimulated a 10-fold increase in glucose transport activity, the maximum levels approaching basal transport rates of non-confluent cells; both GLUT1 and GLUT4 were translocated in response to insulin. These data indicate that insulin sensitivity in 3T3-L1 cells develops in a biphasic pattern. In confluent fibroblasts, a moderate effect of insulin conferred exclusively by GLUT1 is detectable, probably reflecting the small intracellular compartment of GLUT1.(ABSTRACT TRUNCATED AT 250 WORDS)

GLUT-4 phosphorylation and its intrinsic activity. Mechanism of Ca(2+)-induced inhibition of insulin-stimulated glucose transport.

In this study, we examined the influence of high levels of cytosolic calcium on phosphorylation status and function of GLUT-4 in isolated rat adipocytes. Intracellular calcium was elevated by exposing adipocytes to either extracellular ATP (1.6 mM) or thapsigargin (100 nM). Both agents increased cytosolic calcium 2-3 fold. While basal glucose uptake was unaffected, both ATP and thapsigargin reduced insulin-stimulated glucose transport by 40-70% (p < 0.05). Neither ATP nor thapsigargin affected GLUT-4 content or its translocation from the low density microsomes to the plasma membrane (PM). In contrast, GLUT-4 immunoprecipitated from the PM of adipocytes exposed to either ATP or thapsigargin was phosphorylated to a greater extent than the GLUT-4 isolated from control cells. ATP and thapsigargin also abolished insulin-stimulated dephosphorylation of GLUT-4. At the same time, GLUT-4 intrinsic activity was significantly reduced in adipocytes with high levels of cytosolic calcium (p < 0.05). Preincubation of adipocytes with cAMP antagonist, RpcAMP (10(-4) M), and calcium channel blocker, nitrendipine (30 microM), improved the ability of insulin to dephosphorylate GLUT-4 and restored insulin-stimulated GLUT-4 intrinsic activity. We conclude that elevated levels of cytosolic calcium interfere with insulin's ability to dephosphorylate GLUT-4, thus reducing its intrinsic activity.

Genistein Inhibits Insulin-Stimulated Glucose Transport and Decreases Immunocytochemical Labeling of GLUT4 Carboxyl-Terminus without Affecting Translocation of GLUT4 in Isolated Rat Adipocytes: Additional Evidence of GLUT4 Activation by Insulin

A recent study from this laboratory (Abler et al., J. Biol. Chem. 267, 18172-18179, 1992) showed genistein blocked insulin-stimulated glucose oxidation without affecting receptor autophosphorylation or tyrosine kinase activity. The mechanism by which genistein inhibited insulin-stimulated glucose metabolism was investigated in the present study. Insulin caused a 12-fold increase in 3-O-methyl-D-glucose (30MG) uptake compared to that of control cells. Basal and insulin-stimulated 30MG transport was inhibited 40-60% by genistein in a concentration-dependent manner (10-100 μg/ml). Genistein had no effect on insulin-stimulated GLUT4 translocation from low density microsomes to plasma membranes as determined by Western blotting. These results suggested that genistein inhibited glucose transport in adipocytes by decreasing the intrinsic activity, rather than the number, of the plasma membrane-associated glucose transporters. We also previously reported that insulin treatment of adipocytes resulted in the immunocytochemically visualized unmasking of the carboxyl-terminus of plasma membrane-associated GLUT4 and suggested the unmasking might be related to an insulin-induced increase in the intrinsic activity of the glucose transporter (Smith et al, Proc. Natl. Acad. Sci. USA 88, 6893-6897, 1991). In the present study, genistein decreased immunocytochemical labeling of plasma membrane-associated GLUT4 by approximately 50% in control and insulin-treated adipocytes by carboxyl-terminus antibodies but had no effect on labeling observed in an amino-terminus antibody. Since genistein did not affect the number of plasma membrane-associated GLUT4 transporters, this result supports the hypothesis that conformational changes in the glucose transporter, reflected by the ability of anti-carboxyl-terminus antibodies to bind to the transporter, may be an indication of the intrinsic activity of the plasma membrane-associated transporter. We therefore conclude that conformational changes in and activation of glucose transporters, in addition to insulin-stimulated GLUT4 translocation, play an important role in insulin-regulated glucose transport in adipocytes.

Effect of streptozotocin-induced diabetes on GLUT-4 phosphorylation in rat adipocytes.

We have examined the regulation of GLUT-4 phosphorylation in adipocytes isolated from diabetic rats. Despite progressive (40-70%) reductions in GLUT-4 protein contents on the 2nd, 7th, and 14th day of diabetes, the phosphorylation of GLUT-4 was increased two- to fourfold. These alterations were accompanied by concomitant reductions (40-66%) in the insulin-stimulated 2-deoxyglucose transport. Insulin treatment of diabetic animals for 5 d restored glucose transport activity, GLUT-4 protein, and GLUT-4 phosphorylation to control levels whereas vanadate and phlorizin were ineffective. In control adipocytes, insulin promoted GLUT-4 translocation from the low density microsomal (LDM) pool to the plasma membranes (PM) and decreased the state of GLUT-4 phosphorylation. In adipocytes isolated from the diabetic rats, insulin failed to stimulate GLUT-4 translocation and to decrease GLUT-4 phosphorylation. To explore the mechanism of the diabetes-induced increases in the GLUT-4 phosphorylation, we investigated phosphoserine phosphatase (PSPase) activities using 32P-labeled GLUT-4 and phosphorylase "a" as substrates. Diabetes resulted in 50-60% increase in the particulate PSPase activity and concomitant reductions in cytosolic PSPase activities. Although reduced cytosolic PSPase activity correlated with an inadequate dephosphorylation of LDM GLUT-4, the existence of highly phosphorylated PM GLUT-4 in the presence of increased particulate PSPase activity required additional explanation. To address this problem, we used PM GLUT-4 from diabetic rats as a substrate of particulate PSPase. Highly active diabetic particulate PSPase, which dephosphorylated control GLUT-4 and phosphorylase a, failed to dephosphorylate PM GLUT-4 from diabetic rats. These data suggest that PM GLUT-4 from diabetic rats is unable to interact with PSPase or that its phosphorylation sites are not accessible to PSPase action. In summary, an induction of diabetes with streptozotocin resulted in significant increases in GLUT-4 phosphorylation. In contrast to normal cells, insulin failed to promote GLUT-4 recruitment to the plasma membranes and its dephosphorylation in diabetic adipocytes. At the same time, diabetes appears to induce redistribution of PSPases, resulting in lower cytosolic activity and higher particulate activity. It also appears that the existence of highly phosphorylated GLUT-4 in the plasma membranes of diabetic adipocytes resulted from its inability to interact with particulate PSPases.

Phosphorylation of the adipose/muscle-type glucose transporter (GLUT4) and its relationship to glucose transport activity.

The effects of protein phosphorylation and dephosphorylation on glucose transport activity reconstituted from adipocyte membrane fractions and its relationship to the phosphorylation state of the adipose/muscle-type glucose transporter (GLUT4) were studied. In vitro phosphorylation of membranes in the presence of ATP and protein kinase A produced a stimulation of the reconstituted glucose transport activity in plasma membranes and low-density microsomes (51% and 65% stimulation respectively), provided that the cells had been treated with insulin prior to isolation of the membranes. Conversely, treatment of membrane fractions with alkaline phosphatase produced an inhibition of reconstituted transport activity. However, in vitro phosphorylation catalysed by protein kinase C failed to alter reconstituted glucose transport activity in membrane fractions from both basal and insulin-treated cells. In experiments run under identical conditions, the phosphorylation state of GLUT4 was investigated by immunoprecipitation of glucose transporters from membrane fractions incubated with [32P]ATP and protein kinases A and C. Protein kinase C stimulated a marked phosphate incorporation into GLUT4 in both plasma membranes and low-density microsomes. Protein kinase A, in contrast to its effect on reconstituted glucose transport activity, produced a much smaller phosphorylation of the GLUT4 in plasma membranes than in low-density microsomes. The present data suggest that glucose transport activity can be modified by protein phosphorylation via an insulin-dependent mechanism. However, the phosphorylation of the GLUT4 itself was not correlated with changes in its reconstituted transport activity.

Subcellular distribution and activity of glucose transporter isoforms GLUT1 and GLUT4 transiently expressed in COS-7 cells

In adipose and muscle cells, the glucose transporter isoform GLUT4 is mainly located in an intracellular, vesicular compartment from which it is translocated to the plasma membrane in response to insulin. In order to test the hypothesis that this preferential targeting of a glucose transporter to an intracellular storage site is conferred only by its primary sequence, we compared the subcellular distribution of the fat/muscle glucose transporter GLUT4 with that of the erythrocyte/brain-type glucose transporter GLUT1 after transient expression in COS-7 cells. Full-length cDNA was ligated into the expression vector pCMV that is driven by the cytomegalovirus promoter, and introduced into COS cells by the DEAE-dextran method. Cells were homogenized and fractionated by differential centrifugation to yield plasma membranes and a Golgi-enriched fraction of intracellular membranes (low-density microsomes). In these membrane fractions, the abundance of glucose transporters was assessed by immunoblotting with specific antibodies against GLUT1 and GLUT4, and their transport activity was assayed after solubilization and reconstitution into lecithin liposomes. Uptake rates of 2-deoxyglucose assayed in parallel samples were higher in cells expressing GLUT1 or GLUT4 as compared with control cells (transfection of pCMV without transporter cDNA). Reconstituted glucose transport activity in plasma membranes was about 5-fold higher after expression of GLUT1 and GLUT4 as compared with control cells. The relative amount of GLUT4 in the low-density microsomes as detected by reconstitution and immunoblotting exceeded that of the GLUT1, but was much lower than that observed in typical insulin-sensitive cells, e.g., rat fat cells or 3T3-L1 adipocytes. These data indicate that COS-7 cells transfected with glucose transporter cDNA express the active transport proteins and can be used for functional studies.

Demonstration of an insulin-insensitive storage pool of glucose transporters in rat hepatocytes and HepG2 cells.

The subcellular distribution of glucose transporters in rat hepatocytes and HepG2 cells was studied in the absence and in the presence of insulin. Glucose transporters were quantitated by measuring glucose-sensitive cytochalasin B binding and by protein immunoblotting using isoform-specific antibodies. Plasma membrane contamination into subcellular fractions was assessed by measuring distribution of 5'-nucleotidase and cell surface carbohydrate label. In hepatocytes, GLUT-2 occurred in a low-density microsomal (LDM) fraction at a significant concentration, and as much as 15% of cellular GLUT-2 was found intracellularly that cannot be accounted for by plasma membrane contamination. In HepG2 cells which express GLUT-1 and GLUT-2, the two isoforms showed distinct subcellular distribution patterns: GLUT-2 was highly concentrated in LDM while very little GLUT-1 was found in this fraction, indicating that a large portion of GLUT-2 occurs in intracellular organelles. Insulin treatment did not change the subcellular distribution patterns of glucose transporters in both cell types. Our results suggest that rat hepatocytes and HepG2 cells possess an intracellular storage pool for GLUT-2, but lack the insulin-responsive glucose transporter translocation mechanism.

Effects of fish and safflower oil feeding on subcellular glucose transporter distributions in rat adipocytes

Effects of fish oil feeding on glucose transport systems and cell size in rat adipocytes were examined and compared with those of safflower oil or carbohydrate feeding under isoenergy intake conditions. Glucose transport activity was assessed by measuring 3-O-methyl-D-glucose transport. The concentration of erythrocyte type glucose transporter (GLUT-1) and muscle/fat type transporter (GLUT-4) was measured by immunoblotting. The amount of each transporter in intact cells was estimated by the amount of transporter and protein of each membrane fraction and by the recovery of marker enzymes. In cells from safflower-fed rats compared with those from carbohydrate-fed rats, insulin-stimulated glucose transport activity per cell decreased to 51% after a 1-wk feeding, and cell size increase became larger with these effects and continued for at least 4 wk. At 1 wk of feeding, GLUT-1 and GLUT-4 per cell in plasma membrane from insulin-treated cells decreased to 62 and 35%, respectively, with concomitant transporter decreases in the low-density microsome fraction. In cells from high-fish oil-fed rats in which two-thirds of safflower oil was replaced by fish oil, when compared with those from safflower oil-fed rats, insulin-stimulated glucose transport activity increased 1.7-fold after 1 wk of feeding with concomitant cellular GLUT-1 and GLUT-4 increases, but its effect declined thereafter. Parallel with this time course, cell size increase was smaller after 1 wk, but this effect also declined thereafter.(ABSTRACT TRUNCATED AT 250 WORDS)

Members of the VAMP family of synaptic vesicle proteins are components of glucose transporter-containing vesicles from rat adipocytes.

Existing data support the hypothesis that insulin triggers the exocytosis of small vesicles containing the GluT4 isoform of the glucose transporter. The data also suggest that these vesicles reform through endocytosis of GluT4. These processes resemble those described for synaptic vesicles after depolarization of nerve cells. To determine whether GluT4 vesicles are related to synaptic vesicles, rat adipocyte low density microsomes (LDM), which are rich in GluT4 vesicles, were screened for the synaptic vesicle proteins synaptotagmin, synaptophysin, SV2, p29, rab3, and VAMP (synaptobrevin) by immunoblotting. Two polypeptides that reacted with antibodies against the VAMPs were identified, one with the same apparent size as the two isoforms of VAMP in the brain (18 kDa) and one that was slightly smaller (17 kDa). These members of the VAMP family were highly enriched in GluT4 vesicles isolated by immunoadsorption and translocated from the LDM to the plasma membrane in response to insulin. With the exception of rab3, which was observed in the LDM but was not localized in the GluT4 vesicles, the other synaptic vesicle proteins were not detected. The presence of the VAMPs in both GluT4 and synaptic vesicles suggests that the genesis and/or exocytosis of these two types of vesicles involve shared processes.

Characterization of GTP-binding proteins in Golgi-associated membrane vesicles from rat adipocytes.

We have previously reported that guanine nucleotides inhibit glucose transport activity reconstituted from adipocyte membrane fractions. In order to further investigate the hypothetical involvement of guanine-nucleotide-binding proteins (GTP-binding proteins) in the regulation of insulin-sensitive glucose transport activity, we studied their subcellular distribution in adipocytes treated or not with insulin. Adipocytes were homogenized and fractionated to yield plasma membranes (PM) and a Golgi-enriched fraction of intracellular membranes (low-density microsomes, LDM). In these membrane fractions, total guanosine 5'-[gamma-[35S]thio]triphosphate ([35S]GTP[S]) binding, alpha- and beta-subunits of heterotrimeric G-proteins, proto-oncogenes Ha-ras and K-ras, and 23-28 kDa GTP-binding proteins were assayed. The levels of alpha s and alpha i (the alpha-subunits of Gs and Gi) were approx. 8-fold lower in LDM than in PM; beta-subunits, Ha-ras and K-ras were not detectable in LDM. Total GTP[S]-binding sites and 23-28 kDa GTP-binding proteins were present in LDM in approximately the same concentrations as in PM. Insulin gave rise to the characteristic translocation of glucose transporters, but failed to alter the subcellular distribution of any of the GTP-binding proteins. Fractionation of the LDM on a discontinuous sucrose gradient revealed that alpha s and alpha i, as detected with antiserum against a common peptide sequence (alpha common), and the bulk of the 23-28 kDa G-proteins sedimented at different sucrose densities. None of the GTP-binding proteins co-sedimented with glucose transporters. Furthermore, the inhibitory effect of GTP[S] on the reconstituted transport activity was lost in the peak fractions of glucose transporters partially purified on the sucrose gradient. These data indicate that LDM from adipocytes contain several GTP-binding proteins in discrete vesicle populations. However, the intracellular GTP-binding proteins are not tightly associated with the vesicles containing the glucose transporter.

Transport function and subcellular distribution of purified human erythrocyte glucose transporter reconstituted into rat adipocytes

In order to delineate the insulin-independent (constitutive) and inssulin-dependent regulations of the plasma membrane glucose transporter concentrations in rat adipocytes, we introduced purified human erythrocyte GLUT-1 (HEGT) into rat adipocytes by poly(ethylene glycol)-induced vesicle-cell fusion and its transport function and subcellular distribution in the host cell were measured. HEGT in adipocytes catalysed 3-O-methylglucose equilibrium exchange with a turnover number that is indistinguishable from that of the basal adipocyte transporters. However, insulin did not stimulate significantly the HEGT function in adipocytes where it stimulated the native transporter function by 7-8-fold. The steady state distribution and the transmembrane orientation assays revealed that more than 85% of the HEGT that were inserted in the physiological, cytoplasmic side-in orientation at the adipocytes plasma membrane were moved into low-density microsomes (LDM), while 90% of the HEGT that were inserted in the wrong, cytoplasmic side-out orientation were retained in the plasma membrane. Furthermore, more than 70% of the LDM-associated HEGT were found in a small subset of LDM that also contained 80% of the LDM-associated GLUT-4, the insulin-regulatable, native adipocyte glucose transporter. However, insulin did not cause redistribution of HEGT from LDM to the plasma membrane under the condition where it recruited GLUT-4 from LDM to increase the plasma membrane GLUT-4 content 4–5-fold. These results demonstrate that the erythrocyte GLUT-1 introduced in adipocytes transports glucose with an intrinsic activity similar to that of the adipocyte GLUT-1 and/or GLUT-4, and enters the constitutive GLUT-4 translocation pathway of the host cell provided it is in physiological transmembrane orientation, but fails to enter the insulin-dependent GLUT-4 recruitment pathway. We suggested that the adipocyte plasma membrane glucose transporter concentration is constitutively kept low by a mechanism where a cell-specific constitutent interacts with a cytoplasmic domain common to GLUT-1 and GLUT-4, while the insulin-dependent recruitment requires a cytoplasmic domain specific to GLUT-4.

Phosphatidylinositol-3-kinase in isolated rat adipocytes. Activation by insulin and subcellular distribution.

Insulin increases phosphatidylinositol-3-kinase (PI-3-kinase) activity in Chinese hamster ovary cells transfected with human insulin receptor (Ruderman, N. B., Kapeller, R., White, M. F., and Cantley, L. C. (1990) Proc. Natl. Acad. Sci. U.S.A. 87, 1411-1415). The subcellular distribution of PI-3-kinase has not been investigated, and it is unclear if insulin has a stimulatory effect on PI-3-kinase in a nonproliferating target tissue, and, if so, whether this effect is subject to counter-regulation. To address these questions, we studied the effect of insulin on PI-3-kinase activity in isolated rat adipocytes. Activity was measured in plasma membranes, intracellular membranes, and cytosol of control and insulin-treated adipocytes, and in anti-Tyr(P) immunoprecipitates prepared from these fractions and from whole cell lysates. Treatment of adipocytes with insulin (200 nM) caused a half-maximal increase in anti-Tyr(P)-immunoprecipitable PI-3-kinase activity in whole cell lysates within 2 min. This effect was concentration-dependent, and it was sensitive to inhibition by norepinephrine. In insulin-stimulated cells, 75% of anti-Tyr(P)-immunoprecipitable PI-3-kinase activity was found in the low density microsomes. This fraction also exhibited the highest specific activity of PI-3-kinase, and insulin caused a further increase in this activity. Anti-Tyr(P)-immunoprecipitable PI-3-kinase activity was also found in the plasma membranes of insulin-treated cells, but this accounted for only a minor portion of the total and anti-Tyr(P)-immunoprecipitable PI-3-kinase activity. The majority of PI-3-kinase activity (90%) in control cells was cytosolic, but this was not increased in response to insulin nor was it anti-Tyr(P)-immunoprecipitable. These data demonstrate that insulin increases the activity of PI-3-kinase in adipocytes and this effect is subject to inhibition by a physiological antagonist of insulin action. The data also indicate that the effect of insulin to increase PI-3-kinase activity is expressed primarily in the low density intracellular membranes and to a lesser extent in the plasma membranes.