Proreceptor dimerization is required for insulin receptor post-translational processing

The insulin receptor is a transmembrane protein dimer composed of two alphabeta monomers held together by inter-alpha-chain disulfide bonds. In a previous report we described a monomeric insulin receptor obtained by replacing Cys-524, -682, -683, and -685 with serine. The membrane-bound monomeric insulin receptors could be cross-linked to dimers in the presence of insulin, indicating that although covalent interactions had been abolished, noncovalent dimerization could still occur in the membrane. To eliminate noncovalent dimerization, we replaced all or some of Cys-524, -682, -683, and -685 with arginine or aspartic acid with the expectation that the electrostatic repulsion at these contact sites would prevent noncovalent dimerization. The results indicate that mutant insulin receptors that are able to form covalent dimers are expressed at the wild type level; mutants that can form noncovalent dimers are expressed at half the level of the wild type receptor, whereas insulin receptor mutants that cannot dimerize are expressed at less than 10% of the wild type level. To elucidate the mechanism of the decrease in expression of the mutant insulin receptors, we examined their subcellular localization and biosynthesis. The results suggest that the extent of expression of these mutant receptors is related to their ability to form covalent or noncovalent dimers at the proreceptor stage.     

Evidence supporting a passive role for the insulin receptor transmembrane domain in insulin-dependent signal transduction

We previously have demonstrated that intramolecular interactions between alpha beta-alpha beta subunits are necessary for insulin-dependent activation of the protein kinase domain within a single alpha 2 beta 2 heterotetrameric insulin-receptor complex (Wilden, P. A., Morrison, B. D., and Pessin, J. E. (1989) Biochemistry 28, 785-792). To evaluate the role of the beta subunit transmembrane domain in the insulin-dependent signalling mechanism, mutant human insulin receptors containing a series of nested transmembrane domain deletions (amino acids 941-945) were generated and stable Chinese hamster ovary-transfected cell lines were obtained. In addition, a substitution of Val-938 for Glu (E/V938) similar to the oncogenic mutation found in the neu transmembrane domain was also introduced into the insulin receptor. Scatchard analysis of insulin binding to the stable Chinese hamster ovary cell lines expressing either wild type or mutant insulin receptors indicated equivalent receptor number (2-4 x 10(6)/cell) and similar high affinity binding constants (Kd 0.1-0.3 nM). 125I-Insulin affinity cross-linking demonstrated that all of the expressed insulin receptors were assembled and processed into alpha 2 beta 2 heterotetrameric complexes. Surprisingly, all the mutant insulin receptors retained insulin-stimulated autophosphorylation both in vivo and in vitro. Furthermore, endogenous substrate phosphorylation in vivo as well as insulin-stimulated thymidine incorporation into DNA were unaffected by the transmembrane domain mutations. These data demonstrate that marked structural alterations in the insulin receptor transmembrane domain do not interfere with insulin-dependent signal transduction.     

Structural requirements for the transmembrane activation of the insulin receptor kinase

Tetrameric insulin holoreceptor (alpha 2 beta 2) was reduced with dithiothreitol into alpha beta dimers such that they maintain up to 50% of insulin binding at tracer ligand concentrations. Scatchard analysis of insulin binding to dimers revealed that they had a reduced affinity for ligand by a factor of 3-6 compared to holoreceptor, whereas the maximum number of high affinity binding sites was not affected. The alpha beta dimers can be separated from holoreceptor by sucrose density gradient centrifugation, and hence, they are not associated by noncovalent interactions. Insulin-dependent autophosphorylation of alpha beta dimers isolated from low ionic strength sucrose density gradients was minimal and was always accompanied by reoxidation of dimers to the tetrameric holoreceptor. The reformed tetramer exhibited a strong insulin-dependent autophosphorylation reaction. Reoxidation was prevented by isolating alpha beta dimers in sucrose density gradients containing 0.15 M NaCl. Under these conditions, no insulin-dependent autophosphorylation was observed. When insulin receptor was first autophosphorylated and then reduced, receptor kinase activity, as assayed by histone phosphorylation, was not affected. Also, the insulin-independent, basal autophosphorylation was maintained after reduction into alpha beta dimers. We conclude that alpha beta-alpha beta interaction is not necessary for the maintenance of basal kinase activity or for insulin-activated kinase activity once autophosphorylation occurs. However, dimer-dimer interaction appears critical for the insulin-dependent activation of the receptor's intrinsic kinase activity.     

Postbinding characterization of five naturally occurring mutations in the human insulin receptor gene: impaired insulin-stimulated c-jun expression and thymidine incorporation despite normal receptor autophosphorylation.

Some patients with extreme insulin resistance have mutations in their insulin receptor gene. We previously identified five such mutations located in the extracellular domain of the insulin receptor (Asn-->Lys15, His-->Arg209, Phe-->Val382, Lys-->Glu460, and Asn-->Ser462) and studied the effects of these mutations upon posttranslational processing, insulin binding, and tyrosine autophosphorylation. We now characterize the ability of these mutant receptors to mediate biological actions of insulin in transfected NIH-3T3 fibroblasts. All cell lines expressing mutant receptors showed marked impairment in insulin-stimulated c-jun expression and thymidine incorporation when compared with cells expressing wild-type human insulin receptors. The most severe impairment was seen in cells expressing the Val382 mutant (a mutation which causes an intrinsic defect in receptor autophosphorylation). These cells had insulin responses similar to the untransfected cells (used as a negative control). In contrast, cells expressing the Lys15 mutant have the ability to achieve a normal level of maximal autophosphorylation but require an abnormally high concentration of insulin to do so (as the result of decreased insulin binding affinity). These cells show a higher basal rate and much lower insulin stimulation of both c-jun expression and thymidine incorporation when compared with the cells expressing the wild-type human insulin receptors. This pattern is also seen in the cells expressing the other mutants with normal autophosphorylation (Arg209, Glu460, and Ser462). Although the most severe defects in insulin action are seen with the mutation which has an intrinsic defect in receptor autophosphorylation, the ability to undergo normal autophosphorylation does not seem to preclude mutations from impairing the ability of receptors to mediate some of the actions of insulin.     

Cytoplasmic juxtamembrane region of the insulin receptor: a critical role in ATP binding, endogenous substrate phosphorylation, and insulin-stimulated bioeffects in CHO cells.

We have expressed in CHO cells a mutant receptor (IR delta 960) from which 12 amino acids in the juxtamembrane region (A954-D965), including Tyr960, have been deleted. The mutant receptor bound insulin normally but exhibited an increased Km for ATP during autophosphorylation. Upon prolonged incubation in vitro, or at high ATP concentrations such as those observed in vivo, autophosphorylation of IR delta 960 was similar to wild type, and the in vitro phosphotransferase activity of the autophosphorylated IR delta 960 was normal. These results suggest that the deletion did not cause a nonspecific structural disruption of the catalytic domain of IR delta 960. In vivo autophosphorylation of the IR delta 960 receptor was reduced by 30% after 2 min of insulin stimulation and was similar to the wild-type receptor after 30 min of insulin stimulation. However, the mutant receptor was defective in insulin-stimulated tyrosyl phosphorylation of the endogenous substrate pp185. In addition, IR delta 960 was deficient in mediating insulin stimulation of glycogen and DNA synthesis. Thus, autophosphorylation of the insulin receptor is necessary but not sufficient for signal transmission. These data extend the hypothesis that the cytoplasmic juxtamembrane region of the insulin receptor is important for its interactions with ATP, intracellular substrates, and other proteins and is broadly necessary for biological signal transmission.     

Transmembrane signalling by insulin via an insulin receptor mutated at tyrosines 1158, 1162, and 1163

In order to study the role of tyrosine autophosphorylation in insulin receptor signalling, we investigated a mutant human insulin receptor whereby the three major tyrosine autophosphorylation sites at positions 1158, 1162, and 1163 in the receptor beta-subunit were mutated to phenylalanines. When these mutant receptors were expressed in HTC rat hepatoma cells, there was no enhanced beta-subunit autophosphorylation and tyrosine kinase activity. In these cells there was enhanced insulin stimulation of [3H]AIB uptake and [3H]thymidine incorporation when compared to wild type HTC cells. The present study suggests therefore that the presence of the major insulin autophosphorylation sites is not a requirement for insulin stimulation of amino acid transport and mitogenesis.     

Rin1 regulates insulin receptor signal transduction pathways

Rin1 is a multifunctional protein containing several domains, including Ras binding and Rab5 GEF domains. The role of Rin1 in insulin receptor internalization and signaling was examined by expressing Rin1 and deletion mutants in cells utilizing a retrovirus system. Here, we show that insulin-receptor-mediated endocystosis and fluid phase insulin-stimulated endocytosis are enhanced in cells expressing the Rin1:wild type and the Rin1:C deletion mutant, which contain both the Rab5-GEF and GTP-bound Ras binding domains. However, the Rin1:N deletion mutant, which contains both the SH2 and proline-rich domains, blocked insulin-stimulated receptor-mediated and insulin-stimulated fluid phase endocytosis. In addition, the expression of Rin1:delta (429-490), a natural occurring splice variant, also blocked both receptor-mediated and fluid phase endocystosis. Furthermore, association of the Rin1 SH2 domain with the insulin receptor was dependent on tyrosine phosphorylation of the insulin receptor. Morphological analysis indicates that Rin1 co-localizes with insulin receptor both at the cell surface and in endosomes upon insulin stimulation. Interestingly, the expression of Rin1:wild type and both deletion mutants blocks the activation of Erk1/2 and Akt1 kinase activities without affecting either JN or p38 kinase activities. DNA synthesis and Elk-1 activation are also altered by the expression of Rin1:wild type and the Rin1:C deletion mutant. In contrast, the expression of Rin1:delta stimulates both Erk1/2 and Akt1 activation, DNA synthesis and Elk-1 activation. These results demonstrate that Rin1 plays an important role in both insulin receptor membrane trafficking and signaling.     

Tyrosine kinase-defective insulin receptors undergo insulin-induced microaggregation but do not concentrate in coated pits

Biologically active colloid-gold complexes were used to compare ligand-induced microaggregation, redistribution, and internalization of insulin receptors on Rat 1 fibroblasts expressing wild type (HIRc) or tyrosine kinase-defective (HIR A/K1018) human insulin receptors. Insulin-like growth factor I (IGF I) and alpha 2-macroglobulin receptors also were compared. On both cell types, all four unoccupied receptor types occurred predominantly as single receptors. Ligand binding caused receptor microaggregation. Microaggregation of wild type or kinase-defective insulin receptors or IGF I receptors was not different. alpha 2-Macroglobulin receptors formed larger microaggregates. Compared to wild type insulin or IGF I receptors, accumulation of kinase-defective insulin receptor microaggregates in endocytic structures was decreased, and the size of microaggregates in coated pits was significantly smaller. As a result, receptor-mediated internalization of gold-insulin by HIR A/K1018 cells was less than 6% of the cell-associated particles compared to approximately 60% of the particles in HIRc cells. On HIR A/K1018 cells, alpha 2-macroglobulin and IGF I were internalized via coated pits demonstrating that those structures were functional. These results suggest that: 1) ATP binding, receptor autophosphorylation, and activation of receptor kinase activity are not required for receptor microaggregation; 2) receptor microaggregation per se is not sufficient to cause ligand-induced receptor-mediated internalization or the biological effects of insulin; and 3) autophosphorylation of the beta-subunit or activation of the receptor kinase activity is required for the insulin-induced concentration of occupied receptors in coated pits.     

Complementation analysis demonstrates that insulin cross-links both alpha subunits in a truncated insulin receptor dimer

The insulin receptor is a homodimer composed of two alphabeta half receptors. Scanning mutagenesis studies have identified key residues important for insulin binding in the L1 domain (amino acids 1-150) and C-terminal region (amino acids 704-719) of the alpha subunit. However, it has not been shown whether insulin interacts with these two sites within the same alpha chain or whether it cross-links a site from each alpha subunit in the dimer to achieve high affinity binding. Here we have tested the contralateral binding mechanism by analyzing truncated insulin receptor dimers (midi-hIRs) that contain complementary mutations in each alpha subunit. Midi-hIRs containing Ala(14), Ala(64), or Gly(714) mutations were fused with Myc or FLAG epitopes at the C terminus and were expressed separately by transient transfection. Immunoblots showed that R14A+FLAG, F64A+FLAG, and F714G+Myc mutant midi-hIRs were expressed in the medium but insulin binding activity was not detected. However, after co-transfection with R14A+FLAG/F714G+Myc or F64A+FLAG/F714G+Myc, hybrid dimers were obtained with a marked increase in insulin binding activity. Competitive displacement assays revealed that the hybrid mutant receptors bound insulin with the same affinity as wild type and also displayed curvilinear Scatchard plots. In addition, when hybrid mutant midi-hIR was covalently cross-linked with (125)I(A14)-insulin and reduced, radiolabeled monomer was immunoprecipitated only with anti-FLAG, demonstrating that insulin was bound asymmetrically. These results demonstrate that a single insulin molecule can contact both alpha subunits in the insulin receptor dimer during high affinity binding and this property may be an important feature for receptor signaling.     

Cysteine 647 in the insulin receptor is required for normal covalent interaction between alpha- and beta-subunits and signal transduction.

We have investigated the structural and functional properties of two mutant insulin receptors in which Cys647 and Cys682,683,685 have been replaced with Ser (IRS647 and IRS682,683,685, respectively). Compared with the wild-type receptor (IRWT), both mutant receptors displayed altered sensitivities to dithiothreitol with respect to insulin binding and reduction of oligomeric forms. Subunit composition of the oligomeric forms of the receptors as determined by two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis of 125I-labeled receptors indicated that Cys682,683,685 are required for normal heterotetrameric structure and that Cys647 plays a major role in the normal covalent association of the alpha- and beta-subunits. Under nonreducing conditions, the affinity-labeled IRS647 migrated, almost exclusively, as a 230-kDa species which appeared to represent an alpha 2 form of the receptor. Furthermore, Chinese hamster ovary cells expressing IRS647 did not exhibit basal or insulin-stimulated autophosphorylation, suggesting that Cys647 is also required for signal transduction.     

Mutation of the insulin receptor at tyrosine 960 inhibits signal transmission but does not affect its tyrosine kinase activity

Tyrosyl phosphorylation is implicated in the mechanism of insulin action. Mutation of the beta-subunit of the insulin receptor by substitution of tyrosyl residue 960 with phenylalanine had no effect on insulin-stimulated autophosphorylation or phosphotransferase activity of the purified receptor. However, unlike the normal receptor, this mutant was not biologically active in Chinese hamster ovary cells. Furthermore, insulin-stimulated tyrosyl phosphorylation of at least one endogenous substrate (pp185) was increased significantly in cells expressing the normal receptor but was barely detected in cells expressing the mutant. Therefore, beta-subunit autophosphorylation was not sufficient for the insulin response, and a region of the insulin receptor around Tyr-960 may facilitate phosphorylation of cellular substrates required for transmission of the insulin signal.     

Dissociation of insulin receptor expression and signaling from caveolin-1 expression

The presence of cell surface caveolin/caveolae has been postulated to influence the localization, expression levels, and kinase activity of numerous receptors, including the insulin receptor. However, there are conflicting data concerning the effects of caveolin on insulin receptor expression and function. To help clarify this issue, we created a gain of function situation by expressing caveolin-1 at various levels in HEK-293 cells where the endogenous level of caveolin-1 is very low. We generated four permanent lines of this cell expressing amounts of caveolin-1 ranging from 10 to 40 times that of parental cells. The amount of caveolin-1 in the human embryonic kidney cells expressing the highest caveolin levels is comparable with that of adipocytes, cells that naturally express one of the highest levels of caveolin-1. We measured insulin receptor amount and insulin-dependent receptor autophosphorylation as well as insulin receptor substrate 1 (IRS1) tyrosine phosphorylation as an index of insulin signaling. We found that the insulin receptor level was essentially the same in the parental and all four derived cell lines. Likewise, we determined that insulin-dependent insulin receptor and IRS1 tyrosine phosphorylation was not significantly different in the four cell lines representing parental, low, medium, and high levels of caveolin-1 expression. We conclude that insulin receptor expression and ligand-dependent signaling is independent of caveolin-1 expression.     

The rat liver insulin receptor

Using insulin affinity chromatography, we have isolated highly purified insulin receptor from rat liver. When evaluated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing conditions, the rat liver receptor contained the Mr 125,000 alpha-subunit, the Mr 90,000 beta-subunit, and varying proportions of the Mr 45,000 beta'-subunit. The specific insulin binding of the purified receptor was 25-30 micrograms of 125I-insulin/mg of protein, and the receptor underwent insulin-dependent autophosphorylation. Rat liver and human placental receptors differ from each other in several functional aspects: (1) the adsorption-desorption behavior from four insulin affinity columns indicated that the rat liver receptor binds less firmly to immobilized ligands; (2) the 125I-insulin binding affinity of the rat liver receptor is lower than that of the placental receptor; (3) partial reduction of the rat liver receptor with dithiothreitol increases its insulin binding affinity whereas the binding affinity of the placental receptor is unchanged; (4) at optimal insulin concentration, rat liver receptor autophosphorylation is stimulated 25-50-fold whereas the placental receptor is stimulated only 4-6-fold. Conversion of the beta-subunit to beta' by proteolysis is a major problem that occurs during exposure of the receptor to the pH 5.0 buffer used to elute the insulin affinity column. The rat receptor is particularly subject to destruction. Frequently, we have obtained receptor preparations that did not contain intact beta-subunit. These preparations failed to undergo autophosphorylation, but their insulin binding capacity and binding isotherms were identical with those of receptor containing beta-subunit. Proteolytic destruction and the accompanying loss of insulin-dependent autophosphorylation can be substantially reduced by proteolysis inhibitors.(ABSTRACT TRUNCATED AT 250 WORDS)     

Reevaluation of the evidence that an antibody to the insulin receptor is insulinmimetic without activating the protein tyrosine kinase activity of the receptor

The immunoglobulin fraction of a polyclonal anti-insulin receptor antibody (B-10) derived from a patient with severe insulin resistance and acanthosis nigricans was tested for its ability to activate the protein kinase activity of the insulin receptor and to mimic insulin action in Chinese hamster ovary cells expressing either wild type or kinase-deficient human insulin receptors. This antiserum had previously been reported to be insulinmimetic without activating the insulin receptor protein tyrosine kinase. Antibody B-10 bound to both wild type and mutant human insulin receptors, but it induced receptor down-regulation and stimulated hexose transport and thymidine incorporation into DNA only in cells expressing the wild type receptor. Furthermore, this antibody activated the kinase activity of the wild type insulin receptor in intact cells and in vitro. It is likely, therefore, that the biological activities of antibody B-10, like those of insulin, depend upon the protein tyrosine kinase activity of the insulin receptor.     

Substitution of isoleucine for methionine at position 1153 in the beta-subunit of the human insulin receptor. A mutation that impairs receptor tyrosine kinase activity, receptor endocytosis, and insulin action.

The intracellular domain of the insulin receptor possesses activity as a tyrosine-specific protein kinase. The receptor tyrosine kinase is stimulated by insulin binding to the extracellular domain of the receptor. Previously, we have identified a patient with a genetic form of insulin resistance who is heterozygous for a mutation substituting Ile for Met1153 in the tyrosine kinase domain of the receptor near the cluster of the three major autophosphorylation sites (Tyr1158, Tyr1162, and Tyr1163). In this investigation, the Ile1153 mutant receptor was expressed by transfection of mutant cDNA into NIH-3T3 cells. The mutation impairs receptor tyrosine kinase activity and also inhibits the ability of insulin to stimulate 2-deoxyglucose uptake and thymidine incorporation. These data support the hypothesis that the receptor tyrosine activity plays a necessary role in the ability of the receptor to mediate insulin action in vivo. Furthermore, expression of the Ile1153 mutant receptor exerted a dominant negative effect to inhibit the ability of endogenous murine receptors for insulin and insulin-like growth factor I to mediate their actions upon the cell. This observation is consistent with previous suggestions that mutant receptors dimerize with wild type receptors, thereby creating hybrid molecules which lack biological activity. The dominant negative effect of the mutant receptor may explain the dominant mode of inheritance of insulin resistance caused by the Ile1153 mutation. Finally, the mutation inhibits the ability of insulin to stimulate receptor endocytosis. This may explain the normal number of insulin receptors on the surface of the patient's cells in vivo. Despite the presence of markedly elevated levels of insulin in the patient's plasma, the receptors were resistant to down-regulation.     

Receptor-mediated internalization of insulin requires a 12-amino acid sequence in the juxtamembrane region of the insulin receptor beta-subunit

The juxtamembrane region of the insulin receptor (IR) beta-subunit contains an unphosphorylated tyrosyl residue (Tyr960) that is essential for insulin-stimulated tyrosyl phosphorylation of some endogenous substrates and certain biological responses (White, M.F., Livingston, J.N., Backer, J.M., Lauris, V., Dull, T.J., Ullrich, A., and Kahn, C.R. (1988) Cell 54, 641-649). Tyrosyl residues in the juxtamembrane region of some plasma membrane receptors have been shown to be required for their internalization. In addition, a juxtamembrane tyrosine in the context of the sequence NPXY [corrected] is required for the coated pit-mediated internalization of the low density lipoprotein receptor. To examine the role of the juxtamembrane region of the insulin receptor during receptor-mediated endocytosis, we have studied the internalization of insulin by Chinese hamster ovary (CHO) cells expressing two mutant receptors: IRF960, in which Tyr960 has been substituted with phenylalanine, and IR delta 960, in which 12 amino acids (Ala954-Asp965), including the putative consensus sequence NPXY [corrected], were deleted. Although the in vivo autophosphorylation of IRF960 and IR delta 960 was similar to wild type, neither mutant could phosphorylate the endogenous substrate pp185. CHO/IRF960 cells internalized insulin normally whereas the intracellular accumulation of insulin by CHO/IR delta 960 cells was 20-30% of wild-type. However, insulin internalization in the CHO/IR delta 960 cells was consistently more rapid than that occurring in CHO cells expressing kinase-deficient receptors (CHO/IRA1018). The degradation of insulin was equally impaired in CHO/IR delta 960 and CHO/IRA1018 cells. These data show that the juxtamembrane region of the insulin receptor contains residues essential for insulin-stimulated internalization and suggest that the sequence NPXY [corrected] may play a general role in directing the internalization of cell surface receptors.     

Insulin receptor transmembrane signaling: Evidence for an intermolecular oligomerization mechanism of activation

Abstract

To evaluate the mechanism of ligand activation of the insulin receptor we have generated mutant receptor cDNAs which encode proteins with oligopeptide linkers between the carboxy terminus of the extracellular domain and the transmembrane domain of the molecule. Mutant cDNAs encoding a rigid α helical insert (HIR NQDVD) or a flexible polyglycine insert (HIR G12) were expressed in CHO KI cells. Both basal and insulin stimulated autophosphorylation in vitro and in vivo of the expressed receptors were indistinguishable from those of wild type receptor expressed in the same cells. These findings suggest that ligand binding can activate the insulin receptor by an intermolecular dimerization mechanism.     

N-linked oligosaccharide chains of the insulin receptor beta subunit are essential for transmembrane signaling.

Insulin receptor (IR) is a glycoprotein possessing N-linked oligosaccharide side chains on both alpha and beta subunits. The present study focuses for the first time on the potential contribution of N-linked oligosaccharides of the beta subunit in the processing, structure, and function of the insulin receptor. To investigate this point, a receptor mutant (IR beta N1234) was obtained by stable transfection into Chinese hamster ovary cells of an IR cDNA modified by site-directed mutagenesis on the four potential N-glycosylation sites (Asn-X-Ser/Thr) of the beta subunit. The mutated receptor presents an alpha subunit of 135 kDa, indistinguishable from the wild type alpha subunit, but the beta subunit has a reduced molecular mass (80 kDa instead of 95 kDa) most likely due to the absence of N-glycosylation. Metabolic labeling experiments indicate a normal processing and maturation of this mutated receptor which is normally expressed at the surface of the cells as demonstrated by indirect immunofluorescence. The affinity of the mutant for insulin (Kd = 0.12 nM) is similar to that of the wild type receptor (Kd = 0.12 nM). However, a major defect of the mutated IR tyrosine kinase was assessed both in vitro and in vivo by (i) the absence of insulin-stimulated phosphorylation of the poly(Glu-Tyr) substrate in vitro; (ii) the reduction of the insulin maximal stimulation of the mutated IR autophosphorylation in vitro (2-fold stimulation for the mutant receptor as compared to a 7-fold stimulation for the wild type); and (iii) a more complex alteration of the mutated receptor tyrosine autophosphorylation in vivo (3-fold increase of the basal phosphorylation and a 4-fold simulation of this phosphorylation as compared to the wild type receptor, the phosphorylation of which is stimulated 14-fold by insulin). The physiological consequences of this defect were tested on three classical insulin cellular actions; in Chinese hamster ovary IR beta N1234, glucose transport, glycogen synthesis, and DNA synthesis were all unable to be stimulated by insulin indicating the absence of insulin transduction through this mutated receptor. These data provide the first direct evidence for a critical role of oligosaccharide side chains of the beta subunit in the molecular events responsible for the IR enzymatic activation and signal transduction.     

Cys-140 is critical for metabotropic glutamate receptor-1 dimerization

Metabotropic glutamate receptor 1 (mGluR1) expresses at the cell surface as disulfide-linked dimers and can be reduced to monomers with sulfhydryl reagents. To identify the dimerization domain, we transiently expressed in HEK-293 cells a truncated version of mGluR1 (RhodC-R1) devoid of the extracellular domain (ECD). RhodC-R1 was a monomer in the absence or presence of the reducing agents, suggesting that dimerization occurs via the ECD. To identify cysteine residues involved in dimerization within the ECD, cysteine to serine point mutations were made at three cysteines within the amino-terminal half of the ECD. A mutation at positions Cys-67, Cys-109, and Cys-140 all resulted in significant amounts of monomers in the absence of reducing agents. The monomeric C67S and C109S mutants were not properly glycosylated, failed to reach the cell surface, and showed no glutamate response, indicating that these mutant receptors were improperly folded and/or processed and thus retained intracellularly. In contrast, the monomeric C140S mutant was properly glycosylated, processed, and expressed at the cell surface. Phosphoinositide hydrolysis assay showed that the glutamate response of the C140S mutant receptor was similar to the wild type receptor. Substitution of a cysteine for Ser-129, Lys-134, Asp-143, and Thr-146 on the C140S mutant background restored receptor dimerization. Taken together, the results suggest that Cys-140 contributes to intermolecular disulfide-linked dimerization of mGluR1.     

Internalization and down-regulation of the human epidermal growth factor receptor are regulated by the carboxyl-terminal tyrosines

The C terminus of the epidermal growth factor receptor (EGF-R) contains three tyrosines (Y1068, Y1148, and Y1173) which correspond to the major autophosphorylation sites. To investigate the role of the tyrosines in internalization and down-regulation of the EGF-R, mutational analysis was performed with receptors in which 1, 2, or all 3 tyrosines were changed to phenylalanines. The triple point mutant EGF-R, expressed in NIH-3T3, exhibited low autophosphorylation in vivo, low biological and reduced kinase activities. Single and double point mutants were down-regulated, as well as wild type EGF-R in response to EGF showing a half-life of about 1 h. Degradation of the triple point mutant, however, was impaired and resulted in a half-life of 4 h in the presence of EGF. EGF-dependent down-regulation of surface receptors was decreased in the triple point mutant EGF-R as was internalization and degradation of EGF. The specific rate of internalization of the triple point mutant was reduced. By contrast, intracellular processing of ligand previously internalized at 20 degrees C was similar between wild type and mutant receptors. Taken together the data indicate that the delay in degradation observed in cells expressing the triple point mutant EGF-R can be attributed mainly to a slower removal from the cell surface. Our results show that in the full-length EGF-R all three C-terminal tyrosines are necessary for rapid internalization, suggesting that autophosphorylation is required for efficient EGF-dependent receptor endocytosis.