Insulin receptor: tyrosine kinase activity and insulin action

The first step in insulin action consists in binding of the hormone to specific cell surface receptors. This receptor displays two functional domains: an extracellular alpha-subunit containing the majority or the totality of the hormone binding site and an intracellular beta-subunit possessing insulin-stimulated tyrosine kinase activity. A general consensus has been reached in favour of the idea that this receptor enzymic function is essential for generation of the metabolic and growth-promoting effects of insulin. Concerning the mechanism of transmembrane signalling, we like to think that interaction of insulin with the receptor alpha-subunit triggers a conformational change, which is propagated to the beta-subunit and activates it. The active receptor kinase leads then to the phosphorylation of cellular protein substrates, which are likely to belong to two broad categories, those generating metabolic effects of insulin and those resulting in growth-promoting effects. The phosphorylated and active substrates then generate the final effects of insulin.     

Effects of theophylline on insulin receptors and insulin action in the adipocyte

Summary The effects of theophylline on insulin receptors and insulin action in isolated rat adipocytes were studied. Theophylline reduced insulin binding by a decrease of receptor affinity. As concentration-response curves revealed, the effect was paralleled by a reduction of the cellular ATP content. Basal as well as insulin-stimulated glucose transport (2-deoxyglucose and 3-O-methylglucose uptake) were inhibited by much smaller theophylline concentrations (0.15–0.6 mM ) than those necessary to reduce insulin binding and to lower ATP levels (1–4.8 mM), or to stimulate lipolysis (0.3-2.4 mM). Insulin fully antagonized the effect of theophylline on lipolysis but failed to reverse the inhibition of glucose transport completely. The results suggest that (a) theophylline impairs insulin action at a post-receptor level and, at higher concentrations, by a decrease of receptor binding, (b) the reduction of insulin receptor affinity probably reflects ATP depletion of the adipocyte, and (c) the xanthine inhibits glucose transport independently from its effects on lipolysis.     

Effect of internalization and degradation of insulin on rat adipocyte insulin receptor binding kinetics

We have assessed the influence of nondisplaceable (internalized) insulin and insulin degradation during binding reactions at 37 degrees C on the numbers and affinities of insulin binding sites on isolated rat adipocytes. Corrections for nondisplaceable insulin caused a 33% reduction in the number of the high affinity sites (p less than 0.01) and a 24% reduction (p less than 0.01) in the number of the low affinity sites which was associated with a 20% increase (p less than 0.01) in affinity when a two-site model was applied. With a one-site model, the number of insulin receptors decreased by approximately 33% (p less than 0.01), but the affinity did not change. These results indicate that the internalization and degradation of insulin that occurs during the binding reaction can significantly affect the estimation of insulin binding kinetics. Potential variations in internalization and degradation of insulin by cells obtained under various physiological or pathologic conditions should, therefore, be taken into consideration in the interpretation of insulin binding data.     

Insulin-like effect of trypsin on the phosphorylation of rat adipocyte insulin receptor

Trypsin treatment of a partially purified insulin receptor preparation from rat adipocytes stimulated the phosphorylation of 90,000- and 72,000-Da polypeptides immunoprecipitated by anti-insulin receptor antibody. The phosphorylation of tyrosine residues alone was observed in both polypeptides. Trypsin concentrations which stimulated insulin receptor phosphorylation were the same as those previously shown to activate rat adipocyte glycogen synthase. Trypsin treatment of the insulin receptor fraction also stimulated the phosphorylation of an exogenous substrate of tyrosine kinase similarly to insulin treatment. Trypsin treatment of a highly purified insulin receptor from human placenta also activated the phosphorylation of the receptor-derived peptides. These results suggest that the insulin-stimulated protein kinase, a component of the insulin receptor, was activated by tryptic digestion to phosphorylate polypeptides derived from the insulin receptor itself. Thus, it is suggested that stimulation by trypsin of phosphorylation of the insulin receptor may be related to the insulin-like metabolic actions of trypsin observed in rat adipocytes.     

Insulin provokes apparent increases in rat adipocyte M-kinase

Insulin has been shown to stimulate the translocation of protein kinase C (PKC) in rat adipocytes. Presently, we found that decreases in cytosolic 80 kDa PKC were associated with increases in Ca++/phospholipid-independent protein kinase activity, and increases in a 50 kDa cytosolic protein recognized by anti-PKC antiserum. These findings suggest that insulin provokes increases in M-kinase in rat adipocytes.     

Regulation of adipocyte differentiation and insulin action with rapamycin

Here, we demonstrated that inhibition of mTOR with rapamycin has negative effects on adipocyte differentiation and insulin signaling. Rapamycin significantly reduced expression of most adipocyte marker genes including PPARgamma, adipsin, aP2, ADD1/SREBP1c, and FAS, and decreased intracellular lipid accumulation in 3T3-L1 and 3T3-F442A cells, suggesting that rapamycin would affect both lipogenesis and adipogenesis. Contrary to the previous report that suppressive effect of rapamycin on adipogenesis is limited to the clonal expansion, we revealed that its inhibitory effect persisted throughout the process of adipocyte differentiation. Thus, it is likely that constitutive activation of mTOR might be required for the execution of adipogenic programming. In differentiated 3T3-L1 adipocytes, chronic treatment of rapamycin blunted the phosphorylation of AKT and GSK, which is stimulated by insulin, and reduced insulin-dependent glucose uptake activity. Taken together, these results suggest that rapamycin not only prevents adipocyte differentiation by decrease of adipogenesis and lipogenesis but also downregulates insulin action in adipocytes, implying that mTOR would play important roles in adipogenesis and insulin action.     

Insulin receptor monoclonal antibodies that mimic insulin action without activating tyrosine kinase

HTC rat hepatoma cells were transfected with human insulin receptor cDNA to a level of 40,000 receptors/cell. In these cells, as well as in nontransfected cells, insulin stimulated the uptake of alpha-aminoisobutyric acid. Two monoclonal antibodies directed against the human insulin receptor alpha subunit, like insulin, stimulated amino acid uptake in transfected HTC cells, but not in nontransfected HTC cells. The antibodies, in contrast to insulin, failed to stimulate insulin receptor tyrosine kinase activity, both in intact transfected cells and in cell free extracts prepared from them. These data suggest, therefore, that activation of insulin receptor tyrosine kinase may not be an obligatory step in all of the transmembrane signaling mechanisms of the insulin receptor.     

Insulin secretion and action in the hyperthyroid rat

To gain insight into the mechanism of the altered carbohydrate metabolism in thyrotoxicosis, intravenous glucose tolerance tests (IVGTT) and pancreatic suppression tests (PST) were performed in hyperthyroid rats (0.1 mg/kg T4 X 5 days) to assess insulin secretion and action in vivo. Thyroid hormone injections significantly increased T4 levels (182.8 nM +/- 11.6 (SEM) versus 50.2 +/- 6.4; P less than 0.001) and baseline glucose concentrations (9.3 mM +/- 0.2 versus 7.1 +/- 0.2; P less than 0.001). Body weights, basal insulin concentrations, glucose concentrations during IVGTT, glucose disappearance rates and steady state plasma glucose levels (SSPG) were normal. Insulin concentrations during the glucose tolerance test and during the PST were significantly decreased. The metabolic clearance rate of insulin (ml/min/kg +/- SEM) was significantly (P less than 0.01) increased (54.4 +/- 3.5 versus 41.6 +/- 2.3) in the hyperthyroid rats. If the different baseline glucose values were subtracted from the glucose concentrations achieved during the 2 tests, both the glucose disappearance rate and the fall in SSPG levels were significantly enhanced in the T4-injected animals. Thus, in the hyperthyroid rat, insulin secretion is decreased, the clearance of insulin is increased and insulin sensitivity is either normal or possibly enhanced.     

Insulin down-regulates insulin receptor number and up-regulates insulin receptor affinity in cells expressing a tyrosine kinase-defective insulin receptor

We examined the effect of insulin treatment on HTC cells transfected with large numbers of either normal insulin receptors (HTC-IR) or insulin receptors defective in tyrosine kinase (HTC-IR/M-1030). In both HTC-IR and HTC-IR/M-1030 cells, 20 h of insulin treatment (1 microM) at 37 degrees C resulted in a 65% decrease in the number of binding sites with a reciprocal 6-fold increase in affinity. In contrast, treatment with 10 nM insulin (20 h, 37 degrees C) also increased receptor affinity but had a smaller effect on the number of binding sites. 125I-Insulin binding to soluble receptors from HTC-IR and HTC-IR/M-1030 cells pretreated with insulin showed results similar to those obtained in intact cells. In both HTC-IR and HTC-IR/M-1030 cells, insulin enhanced insulin receptor degradation. In HTC-IR/M-1030 cells a 1-h incubation with insulin did not change receptor number and had only a small effect on receptor affinity; also there was no effect of insulin after a 20-h incubation at 15 degrees C. Inhibiting protein synthesis by pretreatment with cycloheximide (100 microM) did not block either the decrease in receptor number or the increase in receptor affinity. Both HTC-IR and HTC-IR/M-1030 cells exhibited a very slow rate of insulin and insulin receptor internalization and no differences were seen in this parameter when HTC-IR cells were compared to HTC-IR/M-1030 cells. These studies indicate, therefore, that in cells expressing kinase-defective insulin receptors, insulin down-regulates insulin receptor number via enhanced receptor degradation, and up-regulates receptor affinity. These effects were time- and temperature-dependent, but not dependent on new protein synthesis, and suggest that activation of tyrosine kinase may not be a prerequisite for certain mechanisms whereby insulin regulates its receptor.     

Insulin receptors in rat brain: insulin stimulates phosphorylation of its receptor beta-subunit

In rat brain cortex synaptosomes insulin stimulated the phosphorylation of its own receptor beta-subunit (94 kDa) as identified by immunoprecipitation with anti-insulin or anti-receptor antiserum. The receptor alpha-subunit (115 kDa) was characterized by specific labeling with 125I-labeled photoreactive insulin. These observations indicate that: (i) insulin receptors in brain are composed of alpha-subunits which bind insulin, and beta-subunits, the phosphorylation of which can be stimulated by insulin; (ii) the size of alpha-subunits in brain is significantly smaller than in other tissues (115 vs 130 kDa), whereas beta-subunits (94 kDa) are identical. We suggest that brain insulin receptors represent a subtype regarding their binding function, whereas their enzyme function is more conserved.     

Insulin action is mimicked by polyclonal antireceptor antibodies that activate the insulin receptor tyrosine kinase

The insulin-like properties of anti-insulin receptor antibodies (P95 Ab) that have been characterized as being directed against the receptor beta-subunit, were studied as probes to assess the interrelationship between insulin action and receptor phosphorylation. When tested on intact cells, P95 Ab mimicked insulin effects. On isolated fat cells, they stimulated 2-deoxyglucose (2-DG) transport and lipogenesis and the P95 antibody maximal effects (173 and 232% of the control values, respectively) represented about 50% of the maximal effects elicited by insulin (317 and 475% of the control values). On cultured Zajdela hepatoma cells (ZHC cells), P95 Ab also mimicked insulin action on the incorporation of [U-14C]glucose into glycogen (158 and 207% of the control value for antibody- and insulin-treated cells, respectively). In all cases the antibody effects were dose-dependent, specific and, when maximal, were not additive with those elicited by insulin. When tested in a cell-free system, P95 Ab faithfully reproduced insulin action on the phosphorylation of the receptor beta-subunit. The maximal antibody and insulin effects (317 and 328% of the control value, respectively) were not additive. P95 Ab were also equally potent as insulin to stimulate the receptor-mediated phosphorylation of an exogenous substrate (365 and 379% of the control value in P95 antibody- and insulin-treated receptors, respectively). As well, P95 Ab proved as able as insulin in stimulating the tyrosine kinase activity of the receptor (89% of the hormone effect) when the activation was carried out in vivo. Taken together, these results are consistent with a role for the kinase activity of the insulin receptor in mediating the action of insulin.     

Localization of the insulin receptor in caveolae of adipocyte plasma membrane.

The insulin receptor is a transmembrane protein of the plasma membrane, where it recognizes extracellular insulin and transmits signals into the cellular signaling network. We report that insulin receptors are localized and signal in caveolae microdomains of adipocyte plasma membrane. Immunogold electron microscopy and immunofluorescence microscopy show that insulin receptors are restricted to caveolae and are colocalized with caveolin over the plasma membrane. Insulin receptor was enriched in a caveolae-enriched fraction of plasma membrane. By extraction with beta-cyclodextrin or destruction with cholesterol oxidase, cholesterol reduction attenuated insulin receptor signaling to protein phosphorylation or glucose transport. Insulin signaling was regained by spontaneous recovery or by exogenous replenishment of cholesterol. beta-Cyclodextrin treatment caused a nearly complete annihilation of caveolae invaginations as examined by electron microscopy. This suggests that the receptor is dependent on the caveolae environment for signaling. Insulin stimulation of cells prior to isolation of caveolae or insulin stimulation of the isolated caveolae fraction increased tyrosine phosphorylation of the insulin receptor in caveolae, demonstrating that insulin receptors in caveolae are functional. Our results indicate that insulin receptors are localized to caveolae in the plasma membrane of adipocytes, are signaling in caveolae, and are dependent on caveolae for signaling.     

Reoxidation of the class I disulfides of the rat adipocyte insulin receptor is dependent upon the presence of insulin: the class I disulfide of the insulin receptor is extracellular

Elements of the quaternary structure of the native and dithiothreitol- (DTT) reduced rat adipocyte insulin receptor have been elucidated by vectorial probing and subunit cross-linking. The charged reducing agents glutathione and beta-mercaptoethylamine were used to reduce the class I disulfides of the receptor in intact adipocytes, demonstrating the extracellular location of the disulfide directly. This interpretation was confirmed by use of DTT as a reducing agent and the nonpermeant sulfhydryl blocking reagent Thiolyte MQ to prevent the reoxidation of the class I sulfhydryl groups which occurred when they were not blocked. It was found that the above reoxidation of the receptor is dependent on the concentration of insulin in the nanomolar range, not occurring measurably at 4 degrees C in its absence. Cross-linking studies with ethylene glycol bis(succinimidyl succinate) demonstrated that the alpha subunits could not be cross-linked to each other after reduction of the class I disulfides, suggesting that the interaction between the receptor heterodimers may be due primarily to the disulfide bonds.     

Inhibition of rat and human adipocyte adenylate cyclase in the antilipolytic action of insulin, clofibrate, and nicotinic acid.

Clofibrate (Atromid-S), nicotinic acid, and insulin are known to be potent hypolipidemic and antilipolytic agents. The present study was undertaken to define the mechanism of action of this latter effect on isolated rat and human fat cells. Sodium clofibrate (0.42 mM), nicotinic acid (0.42 mM), and insulin (100 microU/mL) were shown to inhibit norepinephrine-stimulated lipolysis in rat and human adipose cells and this inhibition was associated with a reduction in intracellular 3',5'-cyclic AMP levels. A similar cyclic AMP lowering effect was demonstrated with insulin in the presence of procaine-HCL, which uncouples the adenylate cyclase system from lipolysis. This insulin effect was attributed to inhibition of adenylate cyclase. A direct and significant inhibition of adenylate cyclase in membrane fractions obtained from isolated human adipocytes was demonstrated for all three antilipolytic agents. The common membrane site of action of these agents whereby adenylate cyclase activity is depressed, thus decreasing cyclic AMP production and free fatty acid (FFA) mobilization from adipose stores, implies a central role for the adenylate cyclase system. These findings are consistent with the view that the hypotriglyceridemic effects of clofibrate, nicotinic acid, and insulin may be partly explained by deprivation of FFA substrate for hepatic very low density lipoprotein synthesis.     

Insulin and IGF-I signaling through the insulin receptor substrate 1

The insulin and insulin-like growth factor-I (IGF-I) receptors are tyrosine kinases. Consequently, an approach to investigating signaling pathways from these receptors is to characterize proteins rapidly phosphorylated on tyrosine in response to insulin and IGF-I. In many cell types the most prominent phosphotyrosine (Ptyr) protein, in addition to the receptors themselves, is a protein of ?160 kD, now known as the insulin receptor substrate 1 (IRS-1). We have purified IRS-1 from mouse 3T3-L1 adipocytes, obtained the sequences of tryptic peptides, and cloned its cDNA based on this information. Mouse IRS-1 is a protein of 1,231 amino acids. It contains 12 tyrosine residues in sequence contexts typical for tyrosine phosphorylation sites. Six of these begin the sequence motif YMXM and two begin the motif YXXM. Recent studies have shown that the enzyme phosphatidylinositol 3-kinase (PI 3-kinase) binds tightly to the activated platelet-derived growth factor (PDGF) and colony-stimulating factor-1 (CSF-1) receptors, through interaction of the src homology 2 (SH2) domains on the 85 kD subunit of PI 3-kinase with Ptyr in one of these motifs on the receptors. We have found that, upon insulin treatment of 3T3-L1 adipocytes, a portion of the Ptyr form of IRS-1 becomes tightly complexed with PI 3-kinase. Since IRS-1 binds to fusion proteins containing the SH2 domains of PI 3-kinase, association most likely occurs through this domain. The association of IRS-1 with PI 3-kinase activates the enzyme about fivefold. Thus, one signaling pathway from the insulin and IGF-I receptors probably proceeds as follows: tyrosine phosphorylation of IRS-1, tight association of IRS-1 with PI 3-kinase with accompanying activation of the kinase, elevation of the PI 3-phosphates. © 1993 Wiley-Liss, Inc.