Thioredoxin catalyzes the reduction of insulin disulfides by dithiothreitol and dihydrolipoamide.

Thioredoxin from Escherichia coli was shown to catalyze the reduction of insulin disulfides by dithiothreitol. A quantitative assay was developed which measures the rate of insulin reduction spectrophotometrically at 650 nm as turbidity formation from the precipitation of the free insulin B chain. Thioredoxin, at 5 microM concentration, accelerated the reaction between 0.130 mM insulin and 1.0 mM dithiothreitol at pH 7 around 20-fold. The pH optimum of the reaction was 7.5. Thioredoxins from E. coli and calf liver showed similar specific activities. Stopped flow fluorescence measurements of the rate of reduction of thioredoxin-S2 by dithiothreitol showed a second order rate constant of 1647 M-1 s-1 at pH 7.2. This is between 10(2) to 10(3) times larger than the reaction between insulin or linear model disulfides and dithiothreitol. It is consistent with a ping-pong mechanism of thioredoxin catalysis since reduced thioredoxin is known to react very fast with insulin. Thioredoxin also catalyzed lipoamide-dependent reduction of the insulin disulfides in a coupled system with NADH, lipoamide, and lipoamide dehydrogenase. The fast spontaneous reaction between dihydrolipoamide and thioredoxin-S2 provides a mechanism for NADH or pyruvate-dependent disulfide reduction. The implication of the dithiol-disulfide oxidoreductase activity of thioredoxin for the regulation of enzyme activities by thiol oxidation-reduction control is discussed.     

Characterization of affinity-purified insulin receptor/kinase. Effects of dithiothreitol on receptor/kinase function

The insulin receptor/kinase was purified to near homogeneity from human placenta. The purified kinase exhibited a specific activity of 300 nmol/min/mg of protein at 30 degrees C using the synthetic peptide, Arg-Arg-Leu-Ile-Glu-Asp-Ala-Glu-Tyr-Ala-Ala-Arg-Gly, as substrate in the presence of insulin. Treatment of the receptor/kinase with dithiothreitol (DTT) reduced insulin binding by 40-50% and also inhibited tyrosine kinase activity. Phosphorylation and activation of the receptor/kinase did not prevent the DTT-induced loss of binding but completely protected it from the deleterious effects of reducing agent on enzymic activity. Analyses of the structure of the receptor/kinase following phosphorylation and treatment with DTT indicated that the class I disulfide bonds were reduced under the conditions employed, but the tetrameric structure of the receptor/kinase was essentially unaltered. These findings indicate that intact class I disulfides are required for insulin binding but are not necessary for maintenance of the preactivated kinase. DTT was also found to enhance the autoactivation of the insulin receptor/kinase and to promote the reversal of the autophosphorylation reaction. Thus disulfide bonds appear to have multiple roles in the function of the insulin receptor/kinase.     

Transmembrane signaling by the human insulin receptor kinase. Relationship between intramolecular beta subunit trans- and cis-autophosphorylation and substrate kinase activation.

To examine the role of intramolecular beta subunit trans- and cis-autophosphorylation in signal transduction, the vaccinia virus/bacteriophage T7 expression system was used to generate insulin holoreceptors composed of a kinase-defective half-receptor precursor (alpha beta A/K or alpha beta A/K.delta CT) and a kinase-active half-receptor precursor (alpha beta delta CT or alpha beta WT). In the alpha beta A/K-alpha beta delta CT hybrid insulin receptor, insulin stimulated a 20-fold increase in intramolecular beta subunit trans-phosphorylation, whereas cis-phosphorylation increased only 3-fold over the basal state. Similarly, in the alpha beta WT-alpha beta A/K.delta CT hybrid insulin receptor, insulin stimulated trans-phosphorylation approximately 30-fold and cis-phosphorylation only 3-fold over the basal state. Although cis-phosphorylation of the kinase-functional alpha beta half-receptor was observed within these hybrid receptor species, this was not sufficient to stimulate exogenous substrate kinase activity. These data demonstrate that insulin primarily activates an intramolecular beta subunit trans-phosphorylation reaction within the insulin holoreceptor and suggest that this reaction is necessary for activation of the holoreceptor. Furthermore, our results suggest a molecular basis for the dominant-negative phenotype observed in insulin-resistant patients possessing one kinase-defective insulin receptor allele.     

Regulation of interleukin-4 signaling by extracellular reduction of intramolecular disulfides

Interleukin-4 (IL-4) contains three structurally important intramolecular disulfides that are required for the bioactivity of the cytokine. We show that the cell surface of HeLa cells and endotoxin-activated monocytes can reduce IL-4 intramolecular disulfides in the extracellular space and inhibit binding of IL-4 to the IL-4Rα receptor. IL-4 disulfides were in vitro reduced by thioredoxin 1 (Trx1) and protein disulfide isomerase (PDI). Reduction of IL-4 disulfides by the cell surface of HeLa cells was inhibited by auranofin, an inhibitor of thioredoxin reductase that is an electron donor to both Trx1 and PDI. Both Trx1 and PDI have been shown to be located at the cell surface and our data suggests that these enzymes are involved in catalyzing reduction of IL-4 disulfides. The pro-drug N-acetylcysteine (NAC) that promotes T-helper type 1 responses was also shown to mediate the reduction of IL-4 disulfides. Our data provides evidence for a novel redox dependent pathway for regulation of cytokine activity by extracellular reduction of intramolecular disulfides at the cell surface by members of the thioredoxin enzyme family.     

Alteration of insulin receptor kinase in obese, insulin-resistant mice

We have studied the properties of muscle insulin receptors obtained from genetically or experimentally-induced obese mice that are both insulin-resistant. Insulin receptors, partially purified by wheat germ agglutinin--agarose chromatography, were studied in a cell-free system for autophosphorylation, for their ability to phosphorylate a synthetic glutamate--tyrosine copolymer and for their binding characteristics. Insulin receptor number was decreased by 25% in muscles from obese mice without any change in their binding affinity. The insulin stimulatory action on its beta-subunit receptor phosphorylation was diminished in preparations from genetically- or experimentally-induced obese mice to a higher degree than the decrease in insulin receptor number. HPLC analysis of the phosphopeptides generated by trypsin treatment of the labeled receptor beta-subunit was identical in lean and obese mice. Similar alteration of the kinase activity was found in obese mice when the phosphorylation of casein or polyglutamate--tyrosine was measured. Trypsin treatment of the receptor preparations was less effective in stimulating the kinase activity in obese mice than in lean mice. These results suggest that the defect in insulin receptor kinase activity reflects an alteration in the transmission of the message from the alpha- to the beta-subunit or an impairment of the enzyme functioning by environmental conditions.     

Dithiothreitol activation of the insulin receptor/kinase does not involve subunit dissociation of the native alpha 2 beta 2 insulin receptor subunit complex

The subunit composition of the dithiothreitol- (DTT) activated insulin receptor/kinase was examined by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis and gel filtration chromatography under denaturing (0.1% SDS) or nondenaturing (0.1% Triton X-100) conditions. Pretreatment of 32P-labeled insulin receptors with 50 mM DTT followed by gel filtration chromatography in 0.1% SDS demonstrated the dissociation of the alpha 2 beta 2 insulin receptor complex (Mr 400,000) into the monomeric 95,000 beta subunit. In contrast, pretreatment of the insulin receptors with 1-50 mM DTT followed by gel filtration chromatography in 0.1% Triton X-100 resulted in no apparent alteration in mobility compared to the untreated insulin receptors. Resolution of this complex by nonreducing SDS-polyacrylamide gel electrophoresis and autoradiography demonstrated the existence of the alpha 2 beta 2 heterotetrameric complex with essentially no alpha beta heterodimeric or free monomeric beta subunit species present. This suggests that the insulin receptor can reoxidize into the Mr 400,000 complex after the removal of DTT by gel filtration chromatography. Surprisingly, these apparently reoxidized insulin receptors were also observed to be functional with respect to insulin binding, albeit with a 50% decrease in affinity for insulin and insulin stimulation of the beta subunit autophosphorylation. To prevent reoxidation, the insulin receptors were pretreated with 50 mM DTT followed by incubation with excess N-ethylmaleimide prior to gel filtration chromatography in 0.1% Triton X-100. Under these conditions the insulin receptors migrated as the Mr 400,000 alpha 2 beta 2 complex.(ABSTRACT TRUNCATED AT 250 WORDS)     

Relative susceptibilities of the interchain disulfides of an immunoglobulin G molecule to reduction by dithiothreitol.

The reduction by dithiothreitol (DTT) of the four interchain disulfides of a human IgGlkappa immunoglobulin has been studied by two methods: variation of the concentration of DTT relative to the protein concentration (incremental reduction); and variation of the time of reduction at fixed levels of DTT and protein (kinetic reduction). In both cases, the results depend on whether the reduction is carried out aerobically or anaerobically. Under aerobic conditions, the relative levels of intermediates (HL, H2, and H2L) which are generated as native molecules (H2L2) are converted to reduced heavy (H) and light (L) chains depend on the concentrations of protein and DTT as well as on the exposure time to DTT; no stable equilibrium is reached between reduced and oxidized states and conditions gradually revert from those favoring reduction to those favoring reoxidation. By contrast, anaerobic reduction is independent of protein concentration or time of exposure to DTT, beyond about 30 min, indicating that an equilibrium between partially reduced and oxidized states is achieved. The distribution of intermediates observed under anaerobic conditions has been analyzed according to theoretical models (Sears, D.W., and Beychok, S. (1977), Biochemistry 16 (second in a series of three articles in this issue)). Within experimental error, both kinds of anaerobic experiments resemble a random reduction process wherein the four disulfides are equivalent and independent of each other with respect to rate and extent of reduction by D. It is concluded that there are no readily detected pathways in the process, as would occur if the intrinsic reactivities of the bonds were distinct, and no marked cooperatively between the four reaction sites, as would be observed if reduction of one bond materially facilitated or hampered reactivity at another site. Both of these characteristics of the reduction are in direct contrast to those of the reoxidative process, which is marked by the initial preference for formation of a bond between heavy and light chains, and by kinetic cooperativity in bond formation during the course of the reaction (Sears, D.W., et al. (1977), Biochemistry 16 (first in a series of three articles in this issue); Sears, D.W., and Beychok, S. (1977), Biochemistry 16 (second in this series)).     

Urea treatment allows dithiothreitol to release the binding subunit of the insulin receptor from the cell membrane: implications for the structural organization of the insulin receptor

The sequence of the human insulin receptor has only one identifiable transmembrane region which is located in the beta subunit. The structure predicts that the alpha subunit, which binds insulin, is attached to the cell only by disulfide bonds to the beta subunit. However, treatment of membranes with dithiothreitol is ineffective at releasing the alpha subunit. If the receptor structure is unfolded with urea, dithiothreitol is able to release the alpha subunit. These data provided confirmatory evidence that the alpha subunit is not a transmembrane protein.     

The beta subunit of the insulin receptor is an insulin-activated protein kinase

In the presence of adenosine 5'-[gamma-32P]triphosphate ([gamma-32P]ATP) and a partially purified human placental insulin receptor preparation, insulin stimulates the phosphorylation of an Mr 94000 protein in a time- and dose-dependent manner. Half-maximal stimulation of 32P incorporation occurs at (2-3) X 10(-9) M insulin, a concentration identical with the Kd for insulin binding in this preparation. Immunoprecipitations with monoclonal anti-insulin receptor antibody demonstrate that the Mr 94000 protein kinase substrate is a component of the insulin receptor, the beta subunit. If the partially purified, soluble placental receptor preparation is immunoprecipitated and then exposed to [gamma-32P]ATP and insulin, phosphorylation of the Mr 94000 protein is maintained. The photoincorporation of 8-azido[alpha-32P]ATP into placental insulin receptor preparations was carried out to identify the ATP binding site responsible for the protein kinase activity. Photoincorporation into numerous proteins was observed, including both subunits of the insulin receptor. However, when photolabeling was performed in the presence of excess adenosine 5'-(beta, gamma-imidotriphosphate), a nonhydrolyzable ATP derivative, the beta subunit of the insulin receptor was the only species protected from label incorporation. These data indicate that the beta subunit of the insulin receptor has insulin-dependent protein kinase activity. Phosphotyrosine formation is the primary result of this activity in placental insulin receptor preparations.     

Preferential degradation of the beta subunit of purified insulin receptor. Effect on insulin binding and protein kinase activities of the receptor

Collagenase preparations (a mixture of enzymes including collagenase, clostripain, and a casein-degrading protease) degraded the beta subunit (Mr = 95,000) of the purified insulin receptor into fragments of Mr less than 15,000, without degrading the alpha subunit. The resulting beta-digested insulin receptor preparations were found to bind insulin as well as control insulin receptor, as assessed by either cross-linking of 125I-insulin to the digested receptor or by separating insulin bound to receptor from free insulin by high performance liquid chromatography. Moreover, the beta-digested insulin receptor preparations were still precipitated by a monoclonal antibody directed against the insulin-binding site. In contrast, the beta-digested insulin receptor lacked protein kinase activity since it no longer phosphorylated either itself, or an exogenous substrate, calf thymus histone. These results support the identification of the beta subunit of the insulin receptor as a protein kinase.     

Tyrosine phosphorylation of the insulin receptor beta subunit activates the receptor-associated tyrosine kinase activity

The regulation of kinase activity associated with insulin receptor by phosphorylation and dephosphorylation has been examined using partially purified receptor immobilized on insulin-agarose. The immobilized receptor preparation exhibits predominately tyrosine but also serine and threonine kinase activities toward insulin receptor beta subunit and exogenous histone. Phosphorylation of the insulin receptor preparation with increasing concentrations of unlabeled ATP, followed by washing to remove the unreacted ATP, results in a progressive activation of the receptor kinase activity when assayed in the presence of histone and [gamma-32P]ATP. A maximal 4-fold activation is achieved by prior incubation of receptor with concentrations of ATP approaching 1 mM. High pressure liquid chromatographic analysis of tryptic hydrolysates of the 32P-labeled insulin receptor beta subunit reveals three domains of phosphorylation (designated peaks 1, 2, and 3). Phosphotyrosine and phosphoserine residues are present in these three domains while peak 2 contains phosphothreonine as well. Thus, at least seven sites are available for phosphorylation on the beta subunit of the insulin receptor. Incubation of the phosphorylated insulin receptor with alkaline phosphatase at 15 degrees C results in the selective dephosphorylation of the phosphotyrosine residues on the beta subunit of the receptor while the phosphoserine and phosphothreonine contents are not affected. The dephosphorylation of the receptor is accompanied by a marked 65% inhibition of the receptor kinase activity. Almost 90% of the decrease in [32P]phosphate content of the receptor after alkaline phosphatase treatment is accounted for by a decrease in phosphotyrosine content in peak 2, while very small decreases are observed in peaks 1 and 3, respectively. These results demonstrate that the extent of phosphorylation of tyrosine residues in receptor domain 2 closely parallels the receptor kinase activity state, suggesting phosphorylation of this domain may play a key role in regulating the insulin receptor tyrosine kinase.     

Regulation of the insulin receptor kinase by hyperinsulinism

A murine fibroblast cell line transfected with human insulin receptor cDNA, NIH 3T3 HIR3.5, was observed to display insulin-induced down-regulation of insulin-binding activity in a time- and concentration-dependent manner. Maximal inhibition of insulin-binding activity (54%) occurred within 16 h of exposure to 100 nM insulin in vivo, where in vivo refers to intact cells in tissue culture. The decrease in cellular insulin-binding activity was the consequence of a decrease in the number of cell-associated insulin receptors as determined by Scatchard analysis of insulin binding, 125I-insulin affinity cross-linking, and Western blotting of the insulin receptor beta subunit. Acute insulin treatment in vivo (1-60 min) resulted in the activation of the insulin receptor protein tyrosine kinase as determined by in vitro phosphorylation of glutamic acid:tyrosine (4:1), where in vitro refers to broken cell preparations. This acute in vivo insulin activation of the insulin receptor tyrosine kinase resulted in a greater stimulation (1.4-1.9-fold) of tyrosine kinase activity in the glutamic acid:tyrosine (4:1) assay than the maximal stimulation produced by insulin treatment in vitro. In contrast, long term (24 h) insulin treatment in vivo resulted in a 50-70% decrease in intrinsic protein tyrosine kinase activity of the insulin receptors compared with that of acutely activated (1 min) insulin receptors. Under these conditions, the insulin receptor protein kinase activity remained insulin independent in the in vitro substrate kinase assay. Surprisingly, the insulin-independent activated (1 min in vivo insulin-treated) and uncoupled (24 h in vivo insulin-treated) insulin receptors displayed similar stoichiometries of 32P incorporation into the beta subunit by in vitro autophosphorylation when compared with the control insulin receptors, ranging from 1.5 to 1.8 mol of phosphate incorporated/mol of insulin receptor. Phosphoamino acid analysis demonstrated that the phosphoserine/phosphothreonine content of in vivo 32P-labeled insulin receptors increased markedly within a 1-h exposure to insulin in vivo, whereas insulin-induced receptor desensitization was not apparent until 10-24 h after exposure to insulin. These data suggest that insulin treatment in vivo results initially in the activation of the insulin receptor kinase followed by a subsequent uncoupling of protein kinase activity. This insulin-induced desensitization of the insulin receptor kinase does not correlate with the extent of beta subunit serine/threonine phosphorylation.     

Alteration of the apparent Ki of carnitine palmitoyltransferase for malonyl-CoA by the diabetic state and reversal by insulin

The effects of streptozotocin-induced diabetes and the subsequent treatment of diabetic animals with insulin were studied using a dose of streptozotocin that produces highly ketotic animals 48 h after injection. Carnitine palmitoyltransferase of diabetic animals had apparent Ki values for malonyl-CoA that were approximately 10 times greater than control animals, indicating a greatly decreased affinity for malonyl-CoA in the diabetic state. Subsequent treatment of diabetic animals with insulin for 5 days produced non-ketotic animals with normal blood glucose, and the affinity of carnitine palmitoyltransferase for malonyl-CoA was increased to the control level. Treatment of other groups of ketotic diabetic animals with insulin produced substantial changes in the carnitine palmitoyltransferase apparent Ki value for malonyl-CoA within 4 h. These results suggest that insulin modulates the ketotic state, at least in part, by increasing the affinity of carnitine palmitoyltransferase for malonyl-CoA to bring about inhibition of fatty acid oxidation and ketogenesis.     

Tyrosine phosphorylation of insulin receptor beta subunit activates the receptor tyrosine kinase in intact H-35 hepatoma cells

The phosphorylation characteristics of insulin receptor from control and insulin-treated rat H-35 hepatoma cells 32P-labeled to equilibrium have been documented. The 32P-labeled insulin receptor is isolated by immunoprecipitation with patient-derived insulin receptor antibodies in the presence of phosphatase and protease inhibitors to preserve the native phosphorylation and structural characteristics of the receptor. The unstimulated insulin receptor contains predominantly [32P] phosphoserine and trace amounts of [32P]phosphothreonine in its beta subunit. In response to insulin, the insulin receptor beta subunit exhibits marked tyrosine phosphorylation and a 2-fold increase in total [32P]phosphoserine contents. High pressure liquid chromatography of the tryptic hydrolysates of the 32P-labeled receptor beta subunit from quiescent cells results in the resolution of up to 9 fractions containing [32P]phosphoserine. The insulin-stimulated tyrosine phosphorylation is concentrated in two of these receptor phosphopeptide fractions, whereas the increase in [32P]phosphoserine content is scattered in low abundance over all receptor tryptic fractions. Insulin receptors affinity-purified by lectin- and insulin-agarose chromatographies from insulin-treated, 32P-labeled cells exhibit a 22-fold increase in the Vmax of receptor tyrosine kinase activity toward histone when compared to controls. The elevated kinase activity of the insulin receptor derived from insulin-treated cells is not due to the presence of hormone bound to the receptor because the receptor kinase activity is assayed while immobilized on insulin-agarose. Furthermore, the insulin-activated receptor kinase activity is reversed following dephosphorylation of the receptor beta subunit with alkaline phosphatase in vitro. The correlation between the insulin-stimulated site specific tyrosine phosphorylation on receptor beta subunit and the elevation of receptor tyrosine kinase activity strongly suggests that the insulin receptor kinase is activated by hormone-stimulated autophosphorylation on tyrosine residues in intact cells, as previously demonstrated for the purified receptor.     

Phospholipid activation of the insulin receptor kinase: regulation by phosphatidylinositol

A soybean phospholipid mixture produced a concentration-dependent enhancement of beta subunit autophosphorylation of the detergent-soluble, purified human placental insulin receptor. Although phosphatidylcholine, phosphatidylethanolamine, or phosphatidylserine also increased insulin receptor autophosphorylation, only phosphatidylinositol (PtdIns) stimulated to a similar extent as the phospholipid mixture. The effect of PtdIns was biphasic, stimulating at low concentrations (75 microM), but having no stimulatory effect at high concentrations (1.0 mM). Phospholipids also stimulated the exogenous protein kinase activity of the insulin receptor toward histone H2B. Phosphorylation of PtdIns occurred with these purified insulin receptor preparations, but this activity was insulin-independent, and the turnover number for PtdIns phosphorylation in the presence of soybean phospholipid was 1/220th as small as the turnover number for the autophosphorylating activity. These results suggest that although PtdIns can modulate the activity of the insulin receptor kinase, PtdIns phosphorylation itself is not directly involved in this regulation.     

Kinetic properties of the insulin receptor tyrosine protein kinase: activation through an insulin-stimulated tyrosine-specific, intramolecular autophosphorylation

The insulin receptor is an insulin-activated, tyrosine-specific protein kinase. Previous studies have shown that autophosphorylation of tyrosine residues on the Mr 95,000 is associated with an activation of the protein kinase activity toward exogenous protein substrates. We have employed the highly purified insulin receptor, immobilized on insulin-Sepharose or eluted in an active form, to define the metal/ATP requirements for kinase activation, the relationship of receptor autophosphorylation to activation, and the kinetic properties of the autophosphorylated, activated receptor kinase. Prior incubation of the immobilized receptor with 2 mM ATP, 10 mM Mg (or 10 mM Mn), followed by removal of these reactants, served to abolish the upward curvilinearity in the rate of histone 2b (tyrosine) phosphorylation measured subsequently. This treatment also markedly increased the rate of histone 2b phosphorylation as compared to that observed with the unmodified, immobilized receptor, as estimated under conditions that per se minimized further activation. The extents of maximal activation of receptor histone 2b (tyrosine) kinase obtained on preincubation with MgATP or MnATP are identical; however, the affinity of the receptor for MnATP is approximately 10-fold higher than that for MgATP. The higher affinity of the receptor for MnATP is observed for both autophosphorylation/autoactivation and histone 2b tyrosine kinase activity (Km MnATP approximately 0.01 mM; Km MgATP approximately 0.1 mM). Autophosphorylation/autoactivation per se does not significantly alter the apparent affinity for MeATP (or protein substrate, as previously reported) but increases Vmax. Activation of receptor histone 2b (tyrosine) kinase is due to tyrosine-specific autophosphorylation of the Mr 95,000 (beta) subunit; thus the extent of total 32P incorporation into the beta subunit correlates precisely with the extent of kinase activation, both over time and at a wide variety of Me2+ ATP concentrations. Sequential treatment of the autophosphorylated receptor with elastase and trypsin yields a single, basically charged 32P-peptide, Mr less than 2000. The functional properties of the unphosphorylated and fully phosphorylated receptor were compared after elution from insulin-Sepharose. The insulin binding characteristics of the two forms of the receptor were indistinguishable; the kinase properties differed greatly; whereas the histone 2b activity of the unphosphorylated receptor was low in the basal state, and activated 10-fold by insulin, the fully autophosphorylated receptor exhibits maximal histone 2b kinase in the basal state and is unaffected by insulin addition.(ABSTRACT TRUNCATED AT 400 WORDS)     

Regulation of insulin receptor kinase activity by insulin mimickers and an insulin antagonist

Three agents which mimic insulin action in intact cells (concanavalin A, wheat germ agglutinin, and polyclonal insulin receptor antibody), mimicked insulin's ability to stimulate the kinase activity of purified insulin receptors. In contrast, monoclonal insulin receptor antibody, an antagonist of insulin action, did not stimulate the phosphorylation of the insulin receptor either in intact IM-9 cells or in purified receptor preparations. This antibody, however, antagonized the ability of insulin to stimulate the phosphorylation of the receptor both in intact cells and in the purified receptor. These studies with insulin mimickers and an insulin antagonist are consistent with a role for the kinase activity of the receptor mediating the actions of insulin.     

Stabilization of insulin receptor subunit structure by glutathione-insulin transhydrogenase

A partially purified insulin receptor preparation from rat liver was incubated at 37 degrees C with and without the protein-disulfide interchange enzyme, glutathione-insulin transhydrogenase (thiol: protein-disulfide oxidoreductase/isomerase, EC 1.8.4.2/5.3.4.1). Insulin-binding activity was then assessed by crosslinking receptor-125I-insulin complexes and subjecting them to electrophoresis on SDS-polyacrylamide gels in the absence and presence of reductant followed by autoradiography. Prior incubation of the receptor at 37 degrees C in the absence of the enzyme markedly decreased the subsequent binding of 125I-insulin to the holoreceptor (Mr 350 000) and to its subunits (Mr 180 000 and 130 000), while addition of the enzyme to the preincubation medium served to substantially prevent this decrease. The loss in binding at 37 degrees C was not restored by subsequent addition of the enzyme, nor was the loss prevented by any of the several known inhibitors of proteolysis. The apparent stabilization of receptor by transhydrogenase, as evidenced by the increase in binding above control levels, was proportional to both the enzyme concentration and the duration of incubation. These effects seem to be specific for transhydrogenase, since several other disulfide-containing proteins were found to be ineffective. These data suggest that the stabilization of the subunit structure of the insulin receptor at physiological temperatures may take place via a disulfide interchange reaction catalyzed by glutathione-insulin transhydrogenase.     

Insulin stimulation of the insulin receptor kinase can occur in the complete absence of beta subunit autophosphorylation

The glutamic acid:tyrosine (Glu:Tyr) synthetic polymer was observed to inhibit the insulin receptor beta subunit autophosphorylation with an IC50 of 0.20 mg/ml in the absence and 0.15 mg/ml in the presence of insulin. Even though complete blockade of beta subunit autophosphorylation was observed at 4.0 mg/ml Glu:Tyr, insulin was still capable of stimulating the exogenous protein kinase activity of the insulin receptor toward Glu:Tyr. Histone H2B (1.3 mg/ml) was also observed to inhibit the beta subunit autophosphorylation by approximately 80% with an IC50 of 0.31 and 0.35 mg/ml in the absence and presence of insulin, respectively. Similar to the results with Glu:Tyr, insulin was found to stimulate histone H2B phosphorylation under these conditions. Comparisons between the time courses of beta subunit autophosphorylation with those of Glu:Tyr phosphorylation both in the presence and absence of insulin confirmed that insulin can stimulate the exogenous protein kinase activity of the insulin receptor in the complete absence of beta subunit autophosphorylation. Prephosphorylation of the insulin receptor (from 0 to 1.3 mol of phosphate/mol of insulin receptor) in the absence of insulin was found to have no significant effect on the exogenous protein kinase activity when assayed both in the presence and absence of insulin. Insulin was observed to stimulate the phosphorylation of Glu:Tyr approximately 3-fold independent of the extent of beta subunit autophosphorylation. In contrast, prephosphorylation of the insulin receptors in the presence of insulin was observed to enhance the exogenous protein kinase activity dependent on the extent of autophosphorylation, such that by 1.4 mol of phosphate incorporated per mol of insulin receptor, insulin was found to maximally stimulate the initial rate of Glu:Tyr phosphorylation (approximately 9-fold). These results demonstrate that the insulin-dependent autophosphorylation of the insulin receptor results in an amplification of the insulin stimulation of the exogenous protein kinase activity, whereas the insulin-independent autophosphorylation does not.