Partial Activation of the Insulin Receptor Kinase Domain by Juxtamembrane Autophosphorylation

Abstract

Increased enzymatic activity of receptor tyrosine kinases occurs after trans-phosphorylation of one or two tyrosines in the activation loop, located near the catalytic cleft. Partial activation of the insulin receptor's kinase domain was observed at dilute concentrations of kinase, suggesting that cis-autophosphorylation was occurring. Autophosphorylation during partial activation mapped to the juxtamembrane (JM) tyrosines and not to activation loop tyrosines. Furthermore, a double JM Tyr-to-Phe mutant kinase (JMY2F) did not undergo partial activation but catalyzed substrate phosphorylation at a very low rate. Steady-state kinetics of peptide phosphorylation were determined with and without JM autophosphorylation. The JMY2F mutant was used to prevent concurrent cis-autophosphorylation and therefore to approximate the basal state apoenzyme in the kinetic analysis. Partial activation was dominated by a decreased Michaelis constant for peptide substrate, from K_M,PEP ≥ 2.5 mM in the basal state to 0.2 mM in the partially activated state; the K_M,ATP remained virtually unchanged at ∼1 mM, and k_cat increased from 180 to 600 min^-1. The high K_M,PEP suggests weak binding of peptide substrates to the apoenzyme. This was confirmed by K_i > 1 mM for peptide substrates used as inhibitors of JM autophosphorylation. The absence of comparably large changes in k_cat and K_M,ATP suggests that the JM region is primarily a strong barrier to the peptide entry step of trans-phosphorylation reactions. The JM region therefore functions as an intrasteric inhibitor in the basal state of the insulin receptor's kinase domain.