Effect of phenylarsine oxide on fluid phase endocytosis: further evidence for activation of the glucose transporter

We have shown previously that insulin stimulates fluid phase endocytosis in 3T3-L1 adipocytes (Gibbs et al., 1986). Using [14C]sucrose as an endocytotic marker, we show here that phenylarsine oxide, a trivalent arsenical which binds neighboring dithiols, blocked not only insulin-stimulated fluid phase endocytosis, but basal endocytosis as well. The Ki for this process was 6 microM in the presence or absence of insulin and the time required for inhibition was less than 2.5 min, the limit of detection in our assay system. These results can be compared with the inhibitory effect of phenylarsine oxide on insulin-stimulated glucose transport. Although the Ki for insulin-stimulated transport (7 microM) was similar to that for inhibition of endocytosis, basal glucose transport was not affected by the inhibitor. Further, when cells were prestimulated with insulin causing maximal stimulation of the glucose transport rate, phenylarsine oxide induced a time-dependent reduction to the basal rate (t 1/2 of 10 min), despite the fact that endocytosis was blocked immediately. This observation suggests that if the transporter is recycled by an exocytotic/endocytotic mechanism, it is distinct from fluid-phase endocytosis/exocytosis, which is a vesicle-mediated process, and provides further evidence that the transporter may undergo intrinsic activation/inactivation which does not require vesicle movement.     

Evidence for the involvement of vicinal sulfhydryl groups in insulin-activated hexose transport by 3T3-L1 adipocytes

Following the differentiation of 3T3-L1 preadipocytes insulin acutely activates the rate of 2-deoxy-[1-14C]glucose uptake in the mature 3T3-L1 adipocyte by 15- to 20-fold. Phenylarsine oxide, a trivalent arsenical that forms stable ring complexes with vicinal dithiols, prevents insulin-activated hexose uptake in a concentration-dependent manner (Ki = 7 microM) but has no inhibitory effect on basal hexose uptake. 2,3-Dimercaptopropanol at a level nearly stoichiometric to that of phenylarsine oxide prevents or rapidly reverses the inhibition of hexose uptake; 2-mercaptoethanol, even in high stoichiometric excess over the arsenical, does not reverse inhibition of hexose uptake. When phenylarsine oxide is added after adipocytes have been fully activated by insulin, 2-deoxy-[1-14C]glucose uptake rate decays slowly at a rate corresponding to that caused by the withdrawal of insulin (t1/2 = 10 min). Using the same conditions under which phenylarsine oxide blocked activation, the Km for deoxyglucose uptake, the rate at which 125I-insulin became cell-associated, and the 125I-insulin binding isotherm for solubilized insulin receptor were not affected by phenylarsine oxide. These results support the transporter translocation model for insulin-activated hexose transport and implicate vicinal sulfhydryl groups in a post-insulin binding event essential for the translocation of glucose transporters to the plasma membrane.     

Effect of amines on insulin-stimulated processes: the transport of sugars and synthesis of glycogen in frog sartorius muscles

Amines and amides were found to inhibit the process of stimulation of sugar transport in muscle tissue (N. A. Vinogradova et al., 1978). The present paper reports results of experiments on frog sartorius muscles acted upon by amines and other substances that inhibit induction of cultured cell proliferation. The stimulation of sugar transport induced by insulin, 2,4-dinitrophenol, or KCl was found to be inhibited by dansylcadaverine (1 mM), 5-methoxytryptamine (2 mM), or methylamine (100 mM). Such substances as chloroquine, bacitracin, or monensin exerted no effect. Besides, dansylcadaverine (1 mM), and 5-methoxytryptamine inhibited the stimulation of insulin induced glycogen synthesis. Dansylcadaverine was ineffective at concentrations lower than 0.5 mM. It is suggested that the inhibitory action of amines depends on their influence on the processes of membrane protein phosphorylation.     

The effect of inhibitors of insulin processing on generation of insulin intermediate products from human fibroblast as detected by high performance liquid chromatography (HPLC)

To assess the role of various modulators of insulin processing on cell-associated A14-125I-insulin intermediates in human fibroblasts, we have studied the effect of N-ethylmaleimide (NEM), chloroquine, bacitracin, dansylcadavarine, and phenylarsine oxide on generation of these intermediate products with the use of HPLC. NEM completely inhibited generation of intermediate peaks or iodotyrosine. Chloroquine inhibited conversion of A14-125I-insulin to iodotyrosine by about 75 percent and the remaining A14-125I-insulin was not susceptible to acid wash. Bacitracin, dansylcadavarine, and phenylarsine oxide, on the other hand, stimulated formation of intermediate products with concomitant inhibition of iodotyrosine formation. We conclude that there are at least three components of insulin degradation in human fibroblasts. These include the sulfhydryl group inhibitor-sensitive, the intracellular chloroquine-sensitive, and membrane site inhibitor-sensitive components.     

Iodophenylarsine oxide and arsenical affinity chromatography: new probes for dithiol proteins. Application to tubulins and to components of the insulin receptor-glucose transporter signal transduction pathway.

In our studies of the effects of the trivalent arsenical phenylarsine oxide on insulin-dependent hexose uptake in 3T3-L1 adipocytes, we needed direct methods to study arsenical-protein interactions. In this report, we describe two such new tools. The first is the radiolabeled covalent affinity reagent 4-[125I]iodophenylarsine oxide. This compound has effects on 3T3-L1 adipocytes similar to those of phenylarsine oxide both with respect to effects of hexose uptake and the accumulation of pp15, a phosphotyrosine-containing putative mediator of insulin action. Iodophenylarsine oxide labels numerous proteins in intact cells in a concentration-dependent, but apparently insulin-independent fashion. The second tool is trivalent arsenical affinity chromatography, which we use to show novel direct interactions between trivalent arsenicals and several proteins from 3T3-L1 adipocytes including the insulin-responsive glucose transporter GLUT4, the insulin proreceptor, and both the alpha and beta subunits of tubulin. The non-insulin-dependent glucose transporter GLUT1, the mature insulin receptor, and the fatty acid-binding protein 422(aP2) do not show strong interactions with arsenical resin. These results provide a new chemical approach to the study of both insulin-dependent hexose transport and tubulin function.     

Newly synthesized proinsulin/insulin and stored insulin are released from pancreatic B cells predominantly via a regulated, rather than a constitutive, pathway

The pancreatic B cell has been used as a model to compare the release of newly synthesized prohormone/hormone with that of stored hormone. Secretion of newly synthesized proinsulin/insulin (labeled with [3H]leucine during a 5-min pulse) and stored total immunoreactive insulin was monitored from isolated rat pancreatic islets at basal and stimulatory glucose concentrations over 180 min. By 180 min, 15% of the islet content of stored insulin was released at 16.7 mM glucose compared with 2% at 2.8 mM glucose. After a 30-min lag period, release of newly synthesized (labeled) proinsulin and insulin was detected; from 60 min onwards this release was stimulated up to 11-fold by 16.7 mM glucose. At 180 min, 60% of the initial islet content of labeled proinsulin was released at 16.7 mM glucose and 6% at 2.8 mM glucose. Specific radioactivity of the released newly synthesized hormone relative to that of material in islets indicated its preferential release. A similar degree of isotopic enrichment of released, labeled products was observed at both glucose concentrations. Quantitative HPLC analysis of labeled products indicated that glucose had no effect on intracellular proinsulin to insulin conversion; release of both newly synthesized proinsulin and insulin was sensitive to glucose stimulation; 90% of the newly synthesized hormone was released as insulin; and only 0.5% of proinsulin was rapidly released (between 30 and 60 min) in a glucose-independent fashion. It is thus concluded that the major portion of released hormone, whether old or new, processed or unprocessed, is directed through the regulated pathway, and therefore the small (less than 1%) amount released via a constitutive pathway cannot explain the preferential release of newly formed products from the B cell.     

Phenylarsine oxide and the mechanism of insulin-stimulated sugar transport

The actions of phenylarsine oxide (PAO) on hormone receptors and transport processes are reviewed with particular reference to the mechanism of insulin-stimulated sugar transport. It is suggested that as well as reaction with vicinal -SH groups, vicinal -SH/-OH and -SH/-CO2H groups should also be considered as potential reaction sites for PAO. The relatively high levels of these vicinal combinations of groups in many hormone receptors makes them particularly susceptible to reaction with PAO. In the case of insulin-stimulated sugar transport PAO does not inhibit insulin binding to its receptor at low concentrations but may react directly with the glucose transporters in some cells. A hypothesis is proposed suggesting that PAO may react specifically with one transporter isoform (GLUT-4) which is found almost exclusively in rat adipocytes, skeletal muscle and heart tissue (i.e. insulin responsive tissue) whereas in insulin unresponsive cells such as erythrocytes the GLUT-1 isoform is the predominant transporter which is not inhibited by PAO.     

Receptor-mediated insulin degradation and insulin-stimulated glycogenesis in cultured foetal hepatocytes.

Insulin-stimulated glycogenesis and insulin degradation were studied simultaneously at 37 degrees C in cultured foetal hepatocytes grown for 2-3 days in the presence of cortisol. Degradation of cell-associated insulin, as measured by trichloroacetic acid precipitation, was significant after 4 min in the presence of 1-3 nM-125I-labelled insulin. This process became maximal (30% of insulin degraded) after 20 min, a time when binding-state conditions were achieved. No insulin-degradative activity was detected in a medium that had been exposed to cells. At steady-state, the appearance of insulin degradation products in the medium was linearly dependent on time (1.5 fmol/min per 10(6) cells at 1nM-125I-labelled insulin). Chloroquine (3-50 microM), bacitracin (0.1-10 mM) and NH4Cl (1-10 mM) inhibited insulin degradation as soon as this became detectable and caused an increase in the association of insulin to hepatocytes after 20 min. Lidocaine and dansylcadaverine had similar effects, whereas N-ethylmaleimide, aprotinin, phenylmethanesulphonyl fluoride and leupeptin were found to be ineffective. Chloroquine, and also bacitracin, at concentrations that inhibited insulin degradation, decreased the insulin-stimulated incorporation of [14C]glucose into glycogen over 2 h. This effect of chloroquine was specific, since it did not modify the basal glycogenesis, or the glycogenic effect of a glucose load in the absence of insulin. It therefore appears that the receptor-mediated insulin degradation (or some associated pathway) is functionally related to the glycogenic effect of insulin in foetal hepatocytes.     

A novel 68-kDa adipocyte protein phosphorylated on tyrosine in response to insulin and osmotic shock

Osmotic shock can cause insulin resistance in 3T3-L1 adipocytes by inhibiting insulin activation of glucose transport, p70S6 kinase, glycogen synthesis, and lipogenesis. By further investigating the relationship between insulin and hypertonic stress, we have discovered that osmotic shock enhanced by 10-fold the insulin-stimulated tyrosine phosphorylation of a 68-kDa protein. Phosphorylation by insulin was maximal after 1 min and was saturated with 50-100 nm insulin. The effect of sorbitol was completely reversible by 2.5 min. pp68 was a peripheral protein that was localized to the detergent insoluble fraction of the low density microsomes but was not associated with the cytoskeleton. Stimulation of the p42/44 and the p38 MAP kinase pathways by osmotic shock had no effect on pp68 phosphorylation. Treatment of adipocytes with the phosphotyrosine phosphatase inhibitor phenylarsine oxide also enhanced insulin-activated tyrosine phosphorylation of pp68 suggesting that osmotic shock may increase pp68 phosphorylation by inhibiting a phosphotyrosine phosphatase. Dissociation of pp68 from the low density microsomes with RNase A indicated that pp68 binds to RNA. Failure to immunoprecipitate pp68 using antibodies directed against known 60-70-kDa tyrosine-phosphorylated proteins suggest that pp68 may be a novel cellular target that lies downstream of the insulin receptor.     

Insulin induces chloroquine-sensitive recycling of insulin-like growth factor II receptors but not of glucose transporters in rat adipocytes

Incubation of insulin-treated rat adipocytes with chloroquine, in a time- and concentration-dependent manner, was observed to inhibit the insulin-stimulated increase in insulin-like growth factor II (IGF-II) binding activity, whereas no significant change in IGF-II binding was observed in the absence of insulin. The incremental increase of insulin-stimulated IGF-II binding was inhibited 50% by 0.2 mM chloroquine within 15 min and was nearly completely abolished by 60 min. Interestingly, IGF-II binding was never observed to decrease below the binding value in cells without insulin treatment even when incubation was extended to 180 min. Scatchard analysis of IGF-II binding as well as the specific binding of an anti-IGF-II receptor antibody demonstrated that the loss of IGF-II binding in the insulin-stimulated chloroquine-treated adipocytes was due to a decrease in the number of cell-surface IGF-II receptors, whereas the total number of cellular IGF-II receptors was unaltered. The effect of chloroquine was observed to be reversible, temperature-dependent, and sensitive to the metabolic poison KCN. Furthermore, NH4Cl was also observed to inhibit insulin-stimulated increase in IGF-II binding. In contrast, chloroquine or NH4Cl did not inhibit the basal or insulin-stimulated glucose transport activity. Photoaffinity labeling of the glucose transporter with [3H]cytochalasin B also demonstrated that the basal and insulin-stimulated subcellular distribution of the glucose transporters was unaltered by chloroquine treatment. These results suggest that 1) insulin induces a constitutive, acidotropic agent-sensitive recycling of IGF-II receptor and 2) the glucose transporter and IGF-II receptor do not share the same insulin-regulated intracellular trafficking pathways.     

Effects of three proposed inhibitors of adipocyte glucose transport on the reconstituted transporter

Three compounds which inhibit glucose transport in rat adipocytes have been proposed to act directly on the glucose transporter protein. We tested these proposals by examining the effects of the compounds on the stereospecific glucose uptake catalyzed by adipocyte membrane proteins after reconstitution into liposomes. Effects on the transport activity reconstituted from human erythrocyte membranes were also examined. Glucose 6-phosphate, which was suggested to inhibit the transporter noncompetitively (Foley, J.E. and Huecksteadt, T.P. (1984) Biochim. Biophys. Acta 805, 313-316), had no effect on either type of reconstituted transporter, even when present at 5 mM on both sides of the liposomal membranes. Thus, it is unlikely to act directly on the transporter. The metalloendoproteinase substrate dipeptide Cbz-Gly-Phe-NH2, which inhibited insulin-stimulated but not basal glucose uptake in adipocytes (Aiello, L.P., Wessling-Resnick, M. and Pilch, P.F. (1986) Biochemistry 25, 3944-3950), inhibited the reconstituted erythrocyte transporter noncompetitively with a Ki of 1.5-2 mM. The inhibition of the erythrocyte transporter was identical in liposomes of soybean and egg lipid. Transport reconstituted using adipocyte membrane fractions was also inhibited by the dipeptide, with the activity from basal microsomes more sensitive than that from insulin-stimulated plasma membranes. These results indicate that the dipeptide interacts directly with the transporter, and may be a potentially useful probe for changes in transporter structure accompanying insulin action. Phenylarsine oxide, which was suggested to act directly on the adipocyte transporter (Douen, A.G., and Jones, M.N. (1988) Biochim. Biophys. Acta 968, 109-118), produced only slight (about 10%) inhibition of the reconstituted adipocyte and erythrocyte transporters, even when present at 100-200 microM and after 30 min of pretreatment. These results suggest that the major actions of phenylarsine oxide observed in adipocytes are not direct effects on the transporter, but rather effects on the pathways by which insulin regulates glucose transport activity (Frost, S.C. and Lane, M.D. (1985) J. Biol. Chem. 260, 2646-2652).     

Reutilization of insulin receptor and hormonal response in cultured foetal hepatocytes: the effects of chloroquine and vinblastine

The effects of chloroquine and vinblastine (10-100 microM) on insulin degradation and biological action were studied in cultured foetal rat hepatocytes. Insulin degradation, as measured by the release of trichloroacetic acid-soluble radioactivity from 125I-insulin into the medium, was strictly cell-associated, saturable with respect to insulin concentrations and linearly related to the amount of cell-associated hormone. The maximal rate of insulin degradation was 4,700 molecules/min per cell, and its KM about 5 nM. Thus, insulin receptors (30,000 sites/cell; half-life close to 13 hr) must be reutilized 450-fold before being degraded with an average time of reutilization inferior to 10 min. In the presence of 70 microM chloroquine or 100 microM vinblastine, insulin degradation was inhibited by 80% and the amount of cell-associated hormone enhanced 2-3-fold. Nearly total inhibition of insulin-stimulated glycogenesis was obtained with 70 microM chloroquine and 45 microM vinblastine. When hepatocytes were preincubated with chloroquine or vinblastine, insulin binding remained high for up to 4 hr, then progressively decreased thereafter. The addition of 10 nM native insulin during preincubation with the drugs resulted in an earlier and more pronounced decrease in insulin binding, whereas native insulin alone did not induce any change. Both the inhibition of insulin degradation and onset of receptor down-regulation suggest a drug-induced impairment in the receptor reutilization. This defect is correlated to a loss of the glycogenic effect of insulin in cultured foetal rat hepatocytes.     

Inhibition of intracellular proteolysis by insulin in isolated rat hepatocytes. Possible role of internalized hormone

The mechanism of insulin's action upon intracellular proteolysis in isolated hepatocytes was studied. At 37 degrees C insulin inhibited intracellular degradation of intracellular proteins in a dose-dependent manner. A maximal 40% inhibition of intracellular proteolysis was achieved at an insulin concentration of 500 ng/ml with a half-maximal inhibition observed at 2.5 ng/ml of insulin. Insulin inhibited intracellular proteolysis both in the presence and in the absence of amino acids in the incubation mixture. Low concentrations of trypsin (10 micrograms/ml) mimicked insulin's effect upon glucose incorporation into glycogen, but not on intracellular proteolysis. Four protease inhibitors (phenylmethylsulfonyl fluoride (0.5 mM), p-nitrophenyl-p-guanidinobenzoate (0.25 mM), p-tosyl-L-arginine methyl ester (1 mM), and N alpha-p-tosyl-L-lysine chloromethyl ketone (1 mM) blocked the stimulatory effect of insulin upon [14C]glucose incorporation into glycogen, but did not affect the inhibitory action of insulin upon intracellular proteolysis. These results suggest that the mechanism of insulin's action upon intracellular proteolysis differs from that involved in stimulation of glycogenesis. Low temperature (15 degrees C) and short time exposure (10 min) of the hepatocytes to insulin eliminated the inhibitory effect of insulin on intracellular proteolysis. Similarly, insulin's effect on intracellular proteolysis was eliminated by dansylcadaverine, a transglutaminase inhibitor that blocked insulin internalization. In contrast, dansylcadaverine had no effect on insulin's ability to stimulate [14C]glucose incorporation into glycogen. These experiments strongly suggest the necessity of insulin internalization for its inhibitory effect on endogenous protein degradation.     

Diversity in the effects of extracellular ATP and adenosine on the cellular processing and physiologic actions of insulin in rat adipocytes

ATP or adenosine (1 mM) added to extracellular buffer abolished both chloroquine- and monensin-dependent accumulation of [125I]iodoinsulin in isolated rat adipocytes. The effects of ATP were not secondary to its conversion to adenosine and were mimicked by beta, gamma-methyleneadenosine 5'-triphosphate. ATP, but not adenosine, partially inhibited the binding of insulin to the cellular receptor. Neither ATP nor adenosine had any significant effect on both internalization of cell-bound insulin and externalization of the internalized hormone. The degradation of cell-bound insulin was reduced to a considerable extent by both 0.1 mM chloroquine and 5 mM ATP, to a lesser degree by 1 mM ATP, and not significantly by 1 or 5 mM adenosine. Physiologically, (a) 1 mM ATP had a strong, while 1 mM adenosine had a mild inhibitory effect on the insulin-stimulated glucose transport without affecting its basal activity, (b) both ATP and adenosine moderately stimulated basal as well as insulin-stimulated glycogen synthase, and (c) ATP, but not adenosine, transiently stimulated basal cAMP phosphodiesterase without affecting the insulin-stimulated enzyme. Phosphodiesterase in cells that had been exposed to ATP for 30 min was refractory to ATP added afresh, but not to insulin. These data suggest that (a) extracellular ATP may block the degradative pathway of insulin processing, (b) adenosine might render the ordinarily irreversible intracellular traffic of insulin reversible or modulate a pathway which is yet to be identified, (c) the previously reported effect of ATP on glycogen synthase may not involve phosphorylation, (d) ATP stimulates cAMP phosphodiesterase by a mechanism which is distinct from that of insulin, and (e) the degradative pathway of insulin processing may not be involved in the physiologic actions of the hormone on glycogen synthase and phosphodiesterase.     

Invited review: Effects of acute exercise and exercise training on insulin resistance.

Insulin resistance of skeletal muscle glucose transport is a key defect in the development of impaired glucose tolerance and Type 2 diabetes. It is well established that both an acute bout of exercise and chronic endurance exercise training can have beneficial effects on insulin action in insulin-resistant states. This review summarizes the present state of knowledge regarding these effects in the obese Zucker rat, a widely used rodent model of obesity-associated insulin resistance, and in insulin-resistant humans with impaired glucose tolerance or Type 2 diabetes. A single bout of prolonged aerobic exercise (30-60 min at approximately 60-70% of maximal oxygen consumption) can significantly lower plasma glucose levels, owing to normal contraction-induced stimulation of GLUT-4 glucose transporter translocation and glucose transport activity in insulin-resistant skeletal muscle. However, little is currently known about the effects of acute exercise on muscle insulin signaling in the postexercise state in insulin-resistant individuals. A well-established adaptive response to exercise training in conditions of insulin resistance is improved glucose tolerance and enhanced skeletal muscle insulin sensitivity of glucose transport. This training-induced enhancement of insulin action is associated with upregulation of specific components of the glucose transport system in insulin-resistant muscle and includes increased protein expression of GLUT-4 and insulin receptor substrate-1. It is clear that further investigations are needed to further elucidate the specific molecular mechanisms underlying the beneficial effects of acute exercise and exercise training on the glucose transport system in insulin-resistant mammalian skeletal muscle.     

Phenylarsine oxide stimulates a cytosolic tyrosine kinase activity and glucose transport in mouse fibroblasts

In the present report we further approach the mechanism by which insulin and phenylarsine oxide (PAO), a trivalent arsenical compound, regulate glucose transport in mouse fibroblasts (NIH3T3). First, we show that PAO is a powerful stimulatory agent on glucose transport. Second, at least three series of observations indicate that this action of PAO is not mediated through the insulin receptor: (i) the same effect of PAO is observed in NIH3T3 and in transfected cells expressing 6 x 10(6) insulin receptors, while the effect of insulin is markedly increased in the transfected cells; (ii) PAO does not affect the tyrosine phosphorylation of the insulin receptor; (iii) the tyrosine kinase activity of the insulin receptor toward exogenous substrates is not increased by PAO. Since PAO appears to act on glucose transport by a different mechanism than insulin, we have compared the effect of PAO and insulin on tyrosine phosphorylation of cellular proteins. Using Western blot analysis we did not detect common substrates in PAO- and insulin-treated cells. However, we found in cell extracts from both PAO- and insulin-treated cells a 50-kDa protein that is immunoprecipitated by antiphosphotyrosine antibody. In addition, PAO activates a cytosolic tyrosine kinase capable of poly(Glu/Tyr) phosphorylation. As a whole, our data suggest that the 50-kDa protein found in cells incubated with PAO and insulin could be the convergence point of the insulin and PAO signaling pathways.     

How muscle insulin sensitivity is regulated: testing of a hypothesis

Muscle contractions induce an increase in glucose transport. The acute effect of muscle contractions on glucose transport is independent of insulin and reverses rapidly after cessation of exercise. As the acute increase in glucose transport reverses, a marked increase in the sensitivity of muscle to insulin occurs. The mechanism for this phenomenon is unknown. We hypothesize that an increase in insulin sensitivity is a general phenomenon that occurs during reversal of an increase in cell surface GLUT4 induced by any stimulus, not just exercise. To test this hypothesis, epitrochlearis, rat soleus, and flexor digitorum brevis muscles were incubated for 30 min with a maximally effective insulin concentration (1.0 mU/ml). Muscles were allowed to recover for 3 h in the absence of insulin. Muscles were then exposed to 60 microU/ml insulin for 30 min followed by measurement of glucose transport. Preincubation with 1.0 mU/ml insulin resulted in an approximately 2-fold greater increase in glucose transport 3.5 h later in response to 60 microU/ml insulin than that which occurred in control muscles treated with 60 microU/ml insulin. Pretreatment of muscles with combined maximal insulin and exercise stimuli greatly amplified the increase in insulin sensitivity. The increases in glucose transport were paralleled by increases in cell surface GLUT4. We conclude that stimulation of glucose transport by any agent is followed by an increase in sensitivity of glucose transport to activation that is mediated by translocation of more GLUT4 to the cell surface.     

Mechanism of autodegradation of cell-surface macromolecules shed by human melanoma cells

The mechanism of autodegradation of cell-surface macromolecules shed by human melanoma cells was studied by incubating radio-iodinated shed macromolecules with unlabeled sister cells and measuring the appearance of acid-soluble radioactivity. After a preliminary latent period of 1-3 h, degradation continually increased up to 24 h and was concentration-dependent. By contrast, binding to cells was very rapid reaching half-maximal value within 15 min. Autodegradation was markedly reduced (44-82%) by pharmacological agents which interfere with endocytosis or lysosomal enzyme activity, including drugs which inhibit receptor migration into coated pits (dansylcadaverine), endocytosis and intracellular transport (colchicine, cytochalasin B, and monensin), and the activity of lysosomal enzymes (chloroquine, ammonium chloride, leupeptin). Degradation was almost totally suppressed (95%) at 4 degrees C. These data suggest that surface macromolecules shed by melanoma cells are autodegraded in part by re-uptake into melanoma cells followed by degradation in lysosomes.     

Glucose transport into rat skeletal muscle: interaction between exercise and insulin

This study was done to evaluate the effect of insulin on sugar transport into skeletal muscle after exercise. The permeability of rat epitrochlearis muscle to 3-O-methylglucose (3-MG) was measured after exposure to a range of insulin concentrations 30, 60, and 180 min after a bout of exercise. Thirty and 60 min after exercise, the effects of exercise and insulin on 3-MG transport were additive over a wide range of insulin concentrations, with no increase in sensitivity or responsiveness to insulin. After 180 min, when approximately 66% of the exercise-induced increase in sugar transport had worn off, both the responsiveness and sensitivity of the glucose transport process to insulin were increased. These findings appear compatible with the hypothesis that the actions of exercise and insulin result in activation and/or translocation into the plasma membrane of two separate pools of glucose transporters in mammalian skeletal muscle.     

Kinetics of insulin action on protein synthesis in isolated adipocytes. Ability of glucose to selectively desensitize the glucose transport system without altering insulin stimulation of protein synthesis

When adipocytes were exposed to [3H]leucine for times ranging from 5 to 180 s, leucine was found to enter cells rapidly and equilibrate with the cell interior within 5 s. After an additional 15-30 s [3H]leucine was incorporated into nascent protein, and the rate of incorporation was linear for up to 6 h in both control and insulin-treated cells. Since treatment of adipocytes with 10 ng/ml insulin enhanced the rate of leucine incorporation 2-3-fold with minimal or no effect on the rate of protein degradation or leucine uptake, we conclude that the predominant effect of insulin is on enhancement of protein synthesis. To assess the time required for insulin to stimulate protein synthesis, we preincubated cells with 10 ng/ml of insulin for various times from 2 to 30 min and then measured [3H]leucine incorporation into protein during a 4-min assay. These results revealed that the insulin stimulation of protein synthesis is rapid (t 1/2 of 4.4 min), but 9-fold slower than insulin activation of glucose transport (t 1/2 less than 0.5 min under identical conditions). In contrast to the rapidity of insulin activation, we found that deactivation proceeded at much slower rates (t 1/2 of 32 and 21 min for protein synthesis and glucose transport, respectively). Desensitization of the glucose transport system has previously been shown to occur after adipocytes are exposed to high glucose and insulin. To examine the specificity of desensitization, we treated cells for 6 h with 20 mM glucose and 25 ng/ml insulin and then examined insulin sensitivity and maximal insulin responsiveness of both the glucose transport and protein synthesis systems. After treatment, the glucose transport was markedly insulin-resistant (60% loss in maximal insulin responsiveness and a marked loss in insulin sensitivity), whereas the protein synthesis system exhibited neither diminished insulin responsiveness nor loss of insulin sensitivity. In fact, insulin sensitivity actually increased, as indicated by the finding that less insulin was required to stimulate protein synthesis (insulin ED50 values of 0.25 and 18 ng/ml at 0 and 6 h of treatment). From these studies we conclude that desensitization of the glucose transport system by glucose and insulin treatment appears to be specific for this particular effector system and does not reflect a state of generalized cellular insulin resistance.