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.