Isolated Rat Adipose Cells Research Articles

Insulin Regulates Fusion of GLUT4 Vesicles Independent of Exo70-mediated Tethering

Insulin regulates cellular glucose uptake by changing the amount of glucose transporter-4 (GLUT4) in the plasma membrane through stimulation of GLUT4 exocytosis. However, how the particular trafficking, tethering, and fusion steps are regulated by insulin is still debated. In a 3T3-L1 adipocyte cell line, the Exocyst complex and its Exo70 subunit were shown to critically affect GLUT4 exocytosis. Here we investigated the effects of Exo70 on tethering and fusion of GLUT4 vesicles in primary isolated rat adipose cells. We found that Exo70 wild type was sequestered away from the plasma membrane in non-stimulated cells, and its overexpression had no effect on GLUT4 trafficking. The addition of insulin increased the amount of Exo70 in the vicinity of the plasma membrane and stimulated the tethering and fusion of GLUT4 vesicles, but the rates of fusion and GLUT4 exposure were not affected by overexpression of Exo70. Surprisingly, the Exo70-N mutant induced insulin-independent tethering of GLUT4 vesicles, which, however, did not lead to fusion and exposure of GLUT4 at the plasma membrane. Upon insulin stimulation, the stationary pretethered GLUT4 vesicles in Exo70-N mutant cells underwent fusion without relocation. Taken together, our data suggest that fusion of GLUT4 vesicles is the rate-limiting step regulated by insulin downstream of Exo70-mediated tethering.

7-Hydroxystaurosporine (UCN-01) Inhibition of Akt Thr308 but not Ser473 Phosphorylation

7-hydroxystaurosporine (UCN-01) infused for 72 hours by continuous i.v. infusion induced insulin resistance during phase I clinical trials. To understand the mechanism for this observation, we examined the effect of UCN-01 on insulin-stimulated glucose transport activity with 3-O-methylglucose in isolated rat adipose cells. UCN-01 inhibits glucose transport activity in a dose-dependent manner at all insulin concentrations. At the clinically relevant concentration of 0.25 mumol/L UCN-01, glucose transport is inhibited 66, 29, and 26% at insulin concentrations of 10, 50, and 100,000 (100K) microunits/mL respectively, thus shifting the dose-response curve to the right. Increasing concentrations of UCN-01 up to 2.5 mumol/L progressively shift the insulin dose-response curve even further. As Akt is known to mediate in part action initiated at the insulin receptor, we also studied the effect of UCN-01 on Akt activation in whole-cell homogenates of these cells. Decreased glucose transport activity directly parallels decreased Akt Thr308 phosphorylation in both an insulin and UCN-01 dose-dependent manner, whereas Akt Ser473 phosphorylation is inhibited only at the lowest insulin concentration, and then, only modestly. UCN-01 also inhibits insulin-induced Thr308 but not Ser473 phosphorylation of Akt associated with the plasma membranes and low-density microsomes and inhibits translocation of GLUT4 from low-density microsomes to plasma membranes as expected from the glucose transport activity measurements. These data suggest that UCN-01 induces clinical insulin resistance by blocking Akt activation and subsequent GLUT4 translocation in response to insulin, and this effect appears to occur by inhibiting Thr308 phosphorylation even in the face of almost completely unaffected Ser473 phosphorylation.

Effects of Leptin and Insulin on CA III Expression in Rat Adipose Tissue

Studies on the biochemical and molecular mechanisms underlying obesity have shown that the expression of some proteins was decreased with obesity in rat adipose tissue. One of these proteins is carbonic anhydrase III (CA III) which constitutes 24% of the cytosolic protein content and its function is unclear. A freshly isolated rat adipose cell culture model was used to examine the effect of leptin and insulin on CA III expression. It was found that leptin decreased CA III expression while insulin increased it which suggests that the decrease in CA III expression observed in obesity in rat adipose tissue may be related to hyperleptinemia.

Insulin-Regulated Trafficking of Dual-Labeled Glucose Transporter 4 in Primary Rat Adipose Cells

In isolated rat adipose cells, physiologically relevant insulin target cells, glucose transporter 4 (GLUT4) subcellular trafficking can be assessed by transfection of exofacially HA-tagged GLUT4. To simultaneously visualize the transfected GLUT4, we fused GFP with HA-GLUT4. With the resulting chimeras, GFP-HA-GLUT4 and HA-GLUT4-GFP, we were able to visualize for the first time the cell-surface localization, total expression, and intracellular distribution of GLUT4 in a single cell. Confocal microscopy reveals that the intracellular proportions of both GFP-HA-GLUT4 and HA-GLUT4-GFP are properly targeted to the insulin-responsive aminopeptidase-positive vesicles. Dynamic studies demonstrate close similarities in the trafficking kinetics between the two constructs and with native GLUT4. However, while the basal subcellular distribution of HA-GLUT4-GFP and the response to insulin are indistinguishable from those of HA-GLUT4 and endogenous GLUT4, most of the GFP-HA-GLUT4 is targeted to the plasma membrane with little further insulin response. Thus, HA-GLUT4-GFP will be useful to study GLUT4 trafficking in vivo while GFP on the N-terminus interferes with intracellular retention.

GLUT4 trafficking in insulin-stimulated rat adipose cells: evidence that heterotrimeric GTP-binding proteins regulate the fusion of docked GLUT4-containing vesicles

Agents that activate the G-protein Gi (e.g. adenosine) increase, and agents that activate Gs [e.g. isoprenaline (isoproterenol)] decrease, steady-state insulin-stimulated glucose transport activity and cell-surface GLUT4 in isolated rat adipose cells without changing plasma membrane GLUT4 content. Here we have further examined the effects of RsGs and RiGi ligands (in which Rs and Ri are Gs- and Gi-coupled receptors respectively) on insulin-stimulated cell-surface GLUT4 and the kinetics of GLUT4 trafficking in these same cells. Rat adipose cells were preincubated for 2 min with or without isoprenaline (200 nM) and adenosine deaminase (1 unit/ml), to stimulate Gs and decrease the stimulation of Gi respectively, followed by 0-20 min with insulin (670 nM). Treatment with isoprenaline and adenosine deaminase decreased insulin-stimulated glucose transport activity by 58%. Treatment with isoprenaline and adenosine deaminase also resulted in similar decreases in insulin-stimulated cell-surface GLUT4 as assessed by both bis-mannose photolabelling of the substrate-binding site and biotinylation of the extracellular carbohydrate moiety when evaluated under similar experimental conditions. After stimulation with insulin in the absence of Gs and the presence of Gi agents, a distinct sequence of plasma membrane events took place, starting with an increase in immunodetectable GLUT4, then an increase in the accessibility of GLUT4 to bis-mannose photolabel, and finally an increase in glucose transport activity. Pretreatment with isoprenaline and adenosine deaminase before stimulation with insulin did not affect the time course of the increase in immunodetectable GLUT4 in the plasma membrane, but did delay both the increase in accessibility of GLUT4 to photolabel and the increase in glucose transport activity. These results suggest that RsGs and RiGi modulate insulin-stimulated glucose transport by influencing the extent to which GLUT4 is associated with occluded vesicles attached to the plasma membrane during exocytosis, perhaps by regulating the fusion process through which the GLUT4 in docked vesicles becomes exposed on the cell surface.

GLUT4 trafficking in insulin-stimulated rat adipose cells: evidence that heterotrimeric GTP-binding proteins regulate the fusion of docked GLUT4-containing vesicles

Agents that activate the G-protein G(i) (e.g. adenosine) increase, and agents that activate G(s) [e.g. isoprenaline (isoproterenol)] decrease, steady-state insulin-stimulated glucose transport activity and cell-surface GLUT4 in isolated rat adipose cells without changing plasma membrane GLUT4 content. Here we have further examined the effects of R(s)G(s) and R(i)G(i) ligands (in which R(s) and R(i) are G(s)- and G(i)-coupled receptors respectively) on insulin-stimulated cell-surface GLUT4 and the kinetics of GLUT4 trafficking in these same cells. Rat adipose cells were preincubated for 2 min with or without isoprenaline (200 nM) and adenosine deaminase (1 unit/ml), to stimulate G(s) and decrease the stimulation of G(i) respectively, followed by 0-20 min with insulin (670 nM). Treatment with isoprenaline and adenosine deaminase decreased insulin-stimulated glucose transport activity by 58%. Treatment with isoprenaline and adenosine deaminase also resulted in similar decreases in insulin-stimulated cell-surface GLUT4 as assessed by both bis-mannose photolabelling of the substrate-binding site and biotinylation of the extracellular carbohydrate moiety when evaluated under similar experimental conditions. After stimulation with insulin in the absence of G(s) and the presence of G(i) agents, a distinct sequence of plasma membrane events took place, starting with an increase in immunodetectable GLUT4, then an increase in the accessibility of GLUT4 to bis-mannose photolabel, and finally an increase in glucose transport activity. Pretreatment with isoprenaline and adenosine deaminase before stimulation with insulin did not affect the time course of the increase in immunodetectable GLUT4 in the plasma membrane, but did delay both the increase in accessibility of GLUT4 to photolabel and the increase in glucose transport activity. These results suggest that R(s)G(s) and R(i)G(i) modulate insulin-stimulated glucose transport by influencing the extent to which GLUT4 is associated with occluded vesicles attached to the plasma membrane during exocytosis, perhaps by regulating the fusion process through which the GLUT4 in docked vesicles becomes exposed on the cell surface.

Insulin regulates lipoprotein lipase activity in rat adipose cells via wortmannin- and rapamycin-sensitive pathways

Lipoprotein lipase (LPL) hydrolyzes the triacylglycerol component of circulating lipoprotein particles, mediating the uptake of fatty acids into adipose tissue and muscle. Insulin is the principal factor responsible for regulating LPL activity in adipose tissue, yet the mechanisms whereby insulin controls LPL expression are unknown. The current studies used wortmannin, a specific inhibitor of phosphatidylinositol (PI) 3-kinase, and rapamycin, a specific inhibitor of activation of phosphoprotein 70 ribosomal protein S6 kinase (p70 s6k), to explore some of the components of the insulin signaling pathway controlling LPL activity in adipose cells. Preincubation of isolated rat adipose cells with wortmannin completely abrogated the stimulation of LPL activity by insulin, while preincubation with rapamycin caused approximately a 60% inhibition of insulin-stimulated LPL activity. Thus, the current studies show that the regulation of adipose tissue LPL by insulin is mediated via a wortmannin-sensitive pathway, most likely PI 3-kinase, and that a rapamycin-sensitive pathway, most likely p70 s6k, constitutes an important downstream component in the insulin signaling pathway through which LPL is regulated.

Morphological effects of wortmannin on the endosomal system and GLUT4-containing compartments in rat adipose cells.

Studies using functional and pharmacological approaches have implicated PI 3-kinase as a key intermediate in the glucose transport and GLUT4 translocation responses to insulin. Confocal microscopy was used to investigate the effects of the PI 3-kinase inhibitor wortmannin in isolated rat adipose cells. Independent of insulin, wortmannin induces the appearance of phase-lucent vacuoles containing the endosomal markers TfR, Rab4, M6PR, and cellubrevin. When added before or with insulin, wortmannin blocks insulin-stimulated GLUT4 translocation, but does not influence the basal VAMP2-containing GLUT4 compartment. These results substantiate the concept of a specialized basal GLUT4 compartment mostly distinct from that of the recycling receptors. However, when added after insulin, wortmannin induces a rapid redistribution of GLUT4 from the cell surface into those endosomal-derived vacuoles where the GLUT4 co-localize with TfR, Rab4, cellubrevin, and VAMP2, but not with clathrin, M6PR, Golgi complex markers TGN38-mannosidase II and gamma-adaptin, and lysosomal marker lgp-120. Therefore, wortmannin also disrupts insulin-stimulated GLUT4 traffic in the recycling endosomal pathway, at a step distal to the sorting of recycling proteins from late endosomal and TGN markers; wortmannin does not appear to affect internalization from the plasma membrane, and delivery from early to late endosomes or from late endosomes to the TGN. In combination with previous kinetic biochemical studies, these results suggest that: (i) insulin stimulates the exocytosis of GLUT4 through a direct pathway from a specialized basal compartment to the plasma membrane, (ii) during endocytosis in the presence of insulin, GLUT4 is sorted out of the TfR compartment into a separate recycling pathway back to the plasma membrane, and (iii) both of these pathways involve wortmannin sensitive enzymes.

Insulin Receptor Substrate-2 (IRS-2) Can Mediate the Action of Insulin to Stimulate Translocation of GLUT4 to the Cell Surface in Rat Adipose Cells

Insulin receptor substrates-1 and -2 (IRS-1 and -2) are important substrates of the insulin receptor tyrosine kinase. Previous studies have focused upon the role of IRS-1 in mediating the actions of insulin. In the present study, we demonstrate that IRS-2 can mediate translocation of the insulin responsive glucose transporter GLUT4 in a physiologically relevant target cell for insulin action. Co-immunoprecipitation experiments performed on cell lysates derived from freshly isolated rat adipose cells incubated in the presence or absence of insulin indicated that twice as much phosphatidylinositol 3-kinase was associated with endogenous IRS-1 as with IRS-2 after insulin stimulation. When rat adipose cells in primary culture were transfected with expression vectors for IRS-1 or IRS-2, we observed 40-fold overexpression of human IRS-1 or murine IRS-2. In addition, anti-phosphotyrosine immunoblotting experiments confirmed that the recombinant substrates were phosphorylated in response to insulin stimulation. To examine the role of IRS-2 in insulin-stimulated translocation of GLUT4, we studied the effects of overexpression of IRS-1 and -2 on translocation of a co-transfected epitope-tagged GLUT4 (GLUT4-HA). Overexpression of IRS-1 or IRS-2 in adipose cells resulted in a significant increase in the basal level of cell surface GLUT4 (in the absence of insulin). Interestingly, at maximally effective concentrations of insulin (60 nM), the level of cell surface GLUT4 in cells overexpressing IRS-1 or -2 significantly exceeded the maximal recruitment observed in the control cells (160 and 135% of control, respectively; p < 0.003). Our data directly demonstrate that IRS-2, like IRS-1, is capable of participating in insulin signal transduction pathways leading to the recruitment of GLUT4. Thus, IRS-2 may provide an alternative pathway for critical metabolic actions of insulin.

Low density lipoprotein receptors in rat adipose cells: subcellular localization and regulation by insulin

The distribution of LDL receptors within subcellular compartments of isolated rat adipose cells and the effects of insulin on their expression have been assessed. By immunoblotting with specific anti-rat LDL receptor antibodies, LDL receptors were 2.3- and 4.5-fold enriched in endoplasmic reticulum-rich high-density microsomes (HDM) and Golgi complex-rich low-density microsomes (LDM), respectively, compared to plasma membranes (PM). This distribution was similar in cultured cells in which total receptors were increased 2.5-fold compared to freshly isolated cells. After correction for enzyme recoveries, LDL receptors were distributed approximately 4% in HDM, approximately 73% in LDM, and approximately 23% in PM. Insulin decreased total LDL receptors in adipose cells approximately 44%, with a 48% and 49% decrease in HDM and LDM, respectively, without any changes in PM. In contrast, insulin caused an increase of glucose transporters in PM while also decreasing glucose transporters in LDM. When adipose cells were depleted of potassium to inhibit receptor-mediated endocytosis, insulin again caused a decrease of LDL receptors in LDM but now increased LDL receptors in PM. Insulin increased the rate of LDL receptor synthesis approximately 24%, but decreased their half life approximately 40%. Thus, in isolated adipose cells the majority of LDL receptors appear to be located in an intracellular compartment that co-sediments with the Golgi complex rather than located in the PM. The LDL receptors localized in intracellular compartments seem to be functionally regulated as insulin acutely diminishes the number of receptors by apparently accelerating their rate of degradation through, as yet, incompletely determined mechanisms.

Insulin-stimulated GLUT4 glucose transporter recycling. A problem in membrane protein subcellular trafficking through multiple pools

The subcellular trafficking of GLUT4 in isolated rat adipose cells and 3T3-L1 adipocytes exhibits many of the properties observed in regulated secretory processes and neurosecretion. GLUT4 is sorted and sequestered from endosomes into a specialized secretory compartment in the basal state and the initial stimulation of its exocytosis by insulin is more rapid than its recycling through the endosomes and secretory compartment during the steady-state response to insulin. We present a mathematical analysis which shows that this behavior is inconsistent with a simple 2-pool model with one plasma membrane and one intracellular compartment, but that a 3-pool model, with two intracellular compartments, can simulate these properties. We extend this model to include the presence of occluded pools in the plasma membrane. Our analysis compares the behavior expected when these occluded pools are precursors in stimulation and/or clathrin-associated-like intermediates in endocytosis. The presence of a precursor occluded pool can account for a lag between the appearance of GLUT4 in the membrane and before the full stimulation of glucose transport activity. The analysis also shows that since the pool size of the occluded GLUT4 is relatively small, the formation of endocytic occluded intermediates such as GLUT4 in clathrin-coated pits is likely to be slow compared with the rate of endocytosis of the coated vesicles.

Transfection of DNA into Isolated Rat Adipose Cells by Electroporation:: Evaluation of Promoter Activity in Transfected Adipose Cells Which Are Highly Responsive to Insulin after 1 Day in Culture

Isolated adipose cells are among the most insulin responsive cells with respect to glucose transport and metabolism. However, molecular biological techniques such as transfection of DNA have heretofore not been applied successfully in these cells in primary culture. We report a method for transfection of DNA into rat adipose cells by electroporation. Six shocks at 800 V and 25 μF in a 0.4 cm gap cuvette results in efficient transfection. We compared the ability of five promoters to drive expression of a luciferase reporter gene in transfected adipose cells. After one day in culture, promoter activity ranged from no expression to a very high level of expression. These transfected, cultured cells also displayed a 10-fold increase in 3-O-methylglucose transport with maximal insulin stimulation. The ability to transfect DNA into adipose cells which remain insulin responsive after one day in primary culture may be helpful for understanding adipose cell-specific gene regulation and elucidating the molecular mechanisms of insulin action.

Cell surface labeling of glucose transporter isoform GLUT4 by bis-mannose photolabel. Correlation with stimulation of glucose transport in rat adipose cells by insulin and phorbol ester.

A new impermeant photoaffinity label has been used for identifying cell surface glucose transporters in isolated rat adipose cells. This compound is 2-N-4(1-azi-2,2,2-trifluoroethyl)benzoyl-1,3-bis(D-mannos-4- yloxy)-2- propylamine. We have used this reagent in combination with immunoprecipitation by specific antibodies against the GLUT4 and GLUT1 glucose transporter isoforms to estimate the relative abundance of these two transporters on the surface of the intact adipose cell following stimulation by insulin and phorbol 12-myristate 13-acetate (PMA). In the basal state, GLUT4 and GLUT1 are both present at the cell surface but GLUT4 is more abundant than GLUT1. In response to insulin, GLUT4 increases 15-20-fold and GLUT1 increases approximately 5-fold while 3-O-methyl-D-glucose transport is stimulated 20-30-fold. By contrast, PMA only induces a approximately 4-fold increase in GLUT4 while GLUT1 increases approximately 5-fold to the same level as seen with insulin. In addition, PMA stimulates 3-O-methyl-D-glucose transport approximately 3-fold to only 13% of the insulin-stimulated state. Thus GLUT4 is the major glucose transporter isoform under all conditions, and it is selectively and markedly enriched in response to insulin but not PMA which increases GLUT1 and GLUT4 equally. Furthermore, stimulation of glucose transport activity correlates closely with the appearance of GLUT4 on the cell surface in response to both insulin and PMA but does not correlate with the sum of GLUT1 and GLUT4 appearance. These results suggest that GLUT4 may be inherently more active than GLUT1 due to a higher TK (turnover/Km).

Interleukin-1 stimulates glucose transport in rat adipose cells: Evidence for receptor discrimination between IL-1β and IL-1α

The effect of interleukin 1 (IL-1) on glucose transport activity in isolated rat adipose cells was examined. IL-1β stimulated 3- O-methylglucose (3 OMG) transport in a time and dose dependent manner. This effect appears to be due to increased maximal transport velocity ( V max of the carrier. Addition of insulin and IL-1β resulted in an additive stimulation of transport, suggesting different mechanisms. IL-1α had no effect on glucose transport. Glu-4, a relatively inactive IL-1β analogue in most cells, stimulated glucose uptake in a time and dose dependent manner with kinetics indistinguishable from those of IL- 1β.

Characterization of the stimulatory action of insulin on insulin-like growth factor II binding to rat adipose cells. Differences in the mechanism of insulin action on insulin-like growth factor II receptors and glucose transporters.

Insulin is known to increase the number of cell surface insulin-like growth factor II (IGF-II) receptors in isolated rat adipose cells through a subcellular redistribution mechanism similar to that for the glucose transporter. The effects of insulin on these two processes, therefore, have now been directly compared in the same cell preparations. 1) Insulin increases the steady state number of cell surface IGF-II receptors by 7-13-fold without affecting receptor affinity; however, insulin stimulates glucose transport activity by 25-40-fold. 2) The insulin concentration required for half-maximal stimulation of cell surface IGF-II receptor number is approximately 30% lower than that for the stimulation of glucose transport activity. 3) The half-time for the achievement of insulin's maximal effect at 37 degrees C is much shorter for IGF-II receptor number (approximately 0.8 min) than for glucose transport activity (approximately 2.6 min). 4) Reversal of insulin's action at 37 degrees C occurs more rapidly for cell surface IGF-II receptors (t1/2 congruent to 2.9 min) than for glucose transport activity (t1/2 congruent to 4.9 min). 5) When the relative subcellular distribution of IGF-II receptors is examined in basal cells, less than 10% of the receptors are localized to the plasma membrane fraction indicating that most of the receptors, like glucose transporters, are localized to an intracellular compartment. However, in response to insulin, the number of plasma membrane IGF-II receptors increases only approximately 1.4-fold while the number of glucose transporters increases approximately 4.5-fold. Thus, while the stimulatory actions of insulin on cell surface IGF-II receptors and glucose transport activity are qualitatively similar, marked quantitative differences suggest that the subcellular cycling of these two integral membrane proteins occurs by distinct processes.

Divergent mechanisms for the insulin resistant and hyperresponsive glucose transport in adipose cells from fasted and refed rats. Alterations in both glucose transporter number and intrinsic activity.

The effects of fasting and refeeding on the glucose transport response to insulin in isolated rat adipose cells have been examined using 3-O-methylglucose transport in intact cells and cytochalasin B binding and Western blotting in subcellular membrane fractions. After a 72-h fast, basal glucose transport activity decreases slightly and insulin-stimulated activity decreases greater than 85%. Following 48 h of fasting, insulin-stimulated glucose transport activity is diminished from 3.9 +/- 0.5 to 1.3 +/- 0.3 fmol/cell per min (mean +/- SEM). Similarly, the concentrations of glucose transporters are reduced with fasting in both the plasma membranes from insulin-stimulated cells from 38 +/- 5 to 18 +/- 3 pmol/mg of membrane protein and the low density microsomes from basal cells from 68 +/- 8 to 34 +/- 9 pmol/mg of membrane protein. Ad lib. refeeding for 6 d after a 48-h fast results in up to twofold greater maximally insulin-stimulated glucose transport activity compared with the control level (7.1 +/- 0.4 vs. 4.5 +/- 0.2 fmol/cell per min), before returning to baseline at 10 d. However, the corresponding concentration of glucose transporters in the plasma membranes is restored only to the control level (45 +/- 5 vs. 50 +/- 5 pmol/mg of membrane protein). Although the concentration of glucose transporters in the low density microsomes of basal cells remains decreased, the total number is restored to the control level due to an increase in low density microsomal protein. Thus, the insulin-resistant glucose transport in adipose cells from fasted rats can be explained by a decreased translocation of glucose transporters to the plasma membrane due to a depleted intracellular pool. In contrast, the insulin hyperresponsive glucose transport observed with refeeding appears to result from (a) a restored translocation of glucose transporters to the plasma membrane from a repleted intracellular pool and (b) enhanced plasma membrane glucose transporter intrinsic activity.

Activity and phosphorylation state of glucose transporters in plasma membranes from insulin-, isoproterenol-, and phorbol ester-treated rat adipose cells.

The counterregulatory action of catecholamines on insulin-stimulated glucose transport and its relation to glucose transporter phosphorylation were studied in isolated rat adipose cells. Plasma membranes exhibiting reduced glucose transport activity were prepared as described previously (Joost, H. G., Weber, T. M., Cushman, S. W., and Simpson, I. A. (1986) J. Biol. Chem. 261, 10033-10036) from cells treated with insulin, and subsequently with isoproterenol and adenosine deaminase. In these membranes, transporter affinity for cytochalasin B binding was significantly reduced (KD = 133.5 +/- 14 versus 89.8 +/- 11 nM, means +/- S.E.) with no change in number of sites or immunoreactivity of the transporter on Western blots. Reconstituted plasma membrane transport was significantly lower with isoproterenol treatment (0.50 +/- 0.12 versus 0.97 +/- 0.27 nmol/mg protein/10 s). In contrast, transport activity reconstituted from corresponding intracellular transporters (from low density microsomes) was unchanged (5.4 +/- 2.2 versus 6.9 +/- 1.2 nmol/mg protein/10 s). Thus, the intrinsic activity change of the transporter produced by catecholamines appears to reflect a structural modification that is confined to the plasma membrane and not recycled into the intracellular compartment. In cells equilibrated with [32P]phosphate, neither insulin nor isoproterenol induced [32P]phosphate incorporation into the glucose transporter immunoprecipitated from plasma membranes. Conversely, phorbol 12-myristate 13-acetate stimulated significant incorporation of [32P]phosphate into the glucose transporter in insulin-stimulated cells without any change in plasma membrane transport activity or transporter concentration. Thus, the phosphorylation state of the glucose transporter does not seem to be involved in either signaling transporter translocation or triggering changes in transporter intrinsic activity.

Prostaglandin E2 differentiates between two forms of glucose transport inhibition by lipolytic agents

The inhibition of insulin-stimulated glucose transport by lipolytic agents was studied in isolated rat adipose cells. Two different mechanisms for the inhibition of glucose transport by lipolytic hormones and agents were distinguished by use of the antilipolytic agent prostaglandin E2 (PGE2). The inhibition of glucose transport induced by lipolytic hormones such as glucagon, catecholamines or ACTH in the presence of adenosine deaminase was antagonized by PGE2. In contrast, inhibition of hexose transport by alkylxanthines was only partially (20-30%) attenuated by PGE2, although the eicosanoid had antagonized cyclic AMP accumulation and stimulation of lipolysis in response to all tested lipolytic agents. The inhibition of glucose transport by IBMX was immediate, whereas the lipolytic hormones (isoprenaline and ACTH) exhibited a latency of 2-3 min. In addition, the inhibition induced by the lypolytic hormones disappeared after cooling of the cells to 22 degrees C, at which temperature IBMX was still inhibitory. Thus, the PGE2-sensitive component of the effect of lipolytic agents on glucose transport appears to be mediated by adenylate cyclase or its subunits Ns/Ni. The PGE2-insensitive effect of alkylxanthines probably reflects a direct interaction of the agents with a regulatory site at the transporter or a related protein.

Insulin-stimulated glucose transport in rat adipose cells. Modulation of transporter intrinsic activity by isoproterenol and adenosine.

The mechanism of modulation of insulin-stimulated glucose transport activity in isolated rat adipose cells by lipolytic and antilipolytic agents has been examined. We have measured glucose transport activity in intact cells with 3-O-methylglucose and in plasma membranes with D-glucose, and the concentration of glucose transporters in plasma membranes using a cytochalasin B binding assay. In intact cells, isoproterenol reduced insulin-stimulated transport activity by 60%. This effect was lost after cooling and washing the cells with homogenization buffer, and neither the concentration of glucose transporters nor transport activity in the plasma membranes differed from control. However, treatment of cells with KCN prior to homogenization preserved the isoproterenol effect through the fractionation procedure. Plasma membranes from these cells contained an unchanged number of transporters (31 +/- 7, mean +/- S.E., versus 31 +/- 4 pmol/mg of protein in controls) but transported glucose at a reduced rate (19 +/- 6 versus 48 +/- 9 pmol/mg of protein/s). Conversely, incubation of intact cells in the presence of adenosine stimulated plasma membrane glucose transport activity compared to that in the absence of adenosine (44 +/- 6 versus 36 +/- 6 pmol/mg of protein/s). Kinetic studies of isoproterenol-inhibited glucose transport in plasma membranes revealed a 60% decrease in Vmax (2900 +/- 350 versus 7200 +/- 1000 pmol/mg of protein/s) and a small increase in Km (15.1 +/- 1 versus 13.0 +/- 0.6 mM). These data indicate that modifications of glucose transport activity produced by lipolytic and antilipolytic agents in intact adipose cells can be fully retained in plasma membranes isolated under appropriate conditions. Furthermore, the effects of these agents occur through a modification of the glucose transporter intrinsic activity.

Biosynthesis of the insulin receptor in rat adipose cells. Intracellular processing of the Mr-190 000 pro-receptor

We investigated the biosynthesis of the insulin receptor in primary cultures of isolated rat adipose cells. Cells were pulse-chase-labelled with [3H]mannose, and at intervals samples were homogenized. Three subcellular membrane fractions were prepared by differential centrifugation: high-density microsomal (endoplasmic-reticulum-enriched), low-density microsomal (Golgi-enriched), and plasma membranes. After detergent solubilization, the insulin receptors were immunoprecipitated with anti-receptor antibodies and analysed by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis and autoradiography. After a 30 min pulse-label [3H]mannose first appeared in a band of Mr 190 000. More than 80% of the Mr-190 000 component was recovered in the microsomal fractions. Its intensity reached a maximum at 1 h in the high-density microsomal fraction and at 2 h in the low-density microsomal fraction, and thereafter declined rapidly (t 1/2 approx. 3 h) in both fractions. In the plasma-membrane fraction, the radioactivity in the major receptor subunits, of Mr 135 000 (alpha) and 95 000 (beta), rose steadily during the chase and reached a maximum at 6 h. The Mr-190 000 precursor could also be detected in the high-density microsomal fraction by affinity cross-linking to 125I-insulin. In the presence of monensin, a cationic ionophore that interferes with intracellular transport within the Golgi complex, the processing of the Mr-190 000 precursor into the alpha and beta subunits was completely inhibited. Our results suggest that the Mr-190 000 pro-receptor originates in the endoplasmic reticulum and is subsequently transferred to the Golgi complex. Maturation of the pro-receptor does not seem to be necessary for the expression of the insulin-binding site. Processing of the precursor into the mature receptor subunits appears to occur during the transfer of the pro-receptor from the Golgi complex to the plasma membrane.