Insulin binding to its receptor induces a conformational change in the receptor C-terminus.

International audienceAntibodies against peptides corresponding to sequences in the C-terminus of the insulin receptor beta-subunit were used to approach the putative role of this receptor domain in signal generation. Two sequences were chosen and correspond to peptide C1, comprising amino acids 1309-1326, and peptide C2, comprising amino acids 1294-1317. The two antibodies produced distinct immunoprecipitation patterns as a function of the insulin receptor form and recognized changes in the insulin receptor molecule induced by ligand binding and autophosphorylation. Both antipeptides, anti-C1 and anti-C2, showed an important decrease in their recognition capacity for the receptor occupied by insulin when compared to the empty receptor. Further, anti-C1 had a lower affinity for the phosphorylated receptor compared to the unphosphorylated receptor and failed to recognize a fraction of the phosphoreceptor population. In contrast, anti-C2 had similar affinities for the phosphorylated and unphosphorylated receptors but was unable to interact with part of the unphosphorylated receptors. Finally, using immunoblotting of the receptor to analyze the denatured molecules, we showed that the phosphorylation-induced changes detected by anti-C1 are retained, suggesting that they are likely not of a conformational nature. In contrast, the insulin-induced changes in the receptor molecule disappear with receptor denaturation which points to their reversible nature. We conclude from these data that (i) antipeptides against the receptor C-terminal sequence are able to distinguish between phosphorylated and unphosphorylated receptor forms and (ii) binding of insulin to its receptor leads to a reversible, phosphorylation-independent, and possibly conformational change at the level of the receptor C-terminal domain

Activation and regulation of the insulin receptor kinase.

International audienceFor the insulin receptor and the EGF receptor it is believed that ligand occupancy results in interactions within the heterotetrameric alpha 2 beta 2 insulin receptor or between monomeric EGF receptors. These interactions then activate the intracellular receptor tyrosine kinase which induces receptor autophosphorylation and phosphorylation of cellular substrates. In the present study we have approached the nature of this receptor activation and autophosphorylation. We have investigated whether these phenomena occur via an intra--or an intermolecular process. To this end the following receptor model system consisting of two receptors was co-expressed in NIH 3T3 cells: a kinase inactive human insulin receptor (HIR K1018A) and a chimeric (EIR) receptor corresponding to the extracellular and transmembrane domains of the human EGF receptor and the cytosolic domain of the human insulin receptor beta subunit. Using this system we found that stimulation of the cells with EGF induced tyrosine autophosphorylation of the EGF-insulin receptor chimera (150 kd) and tyrosine phosphorylation of the beta-subunit of the kinase-deficient insulin receptor (95 kd). The phosphopeptides of the autophosphorylated cytoplasmic domain of the EGF-insulin receptor chimera were comparable to those of the transphosphorylated beta subunit of the kinase-deficient insulin receptor and the wild type human insulin receptor. When immunoaffinity purified EGF-insulin receptor hybrids and kinase-deficient insulin receptors were used in a cell lysate phosphorylation assay, it was found that addition of EGF produced [32P]-labeling of both receptor species. In conclusion, we have shown that tyrosine transphosphorylation can occur between homologous receptor domains. This transphosphorylation and transactivation could be a possible mechanism for signal amplification.2+ domain could influence interactions between the receptor and cellular structures and, as such, play a key role in signal transduction