Binding of 2,6- and 2,7-Dihydroxynaphthalene to Wild-Type and E-B13Q Insulins: Dynamic, Equilibrium, and Molecular Modeling Investigations

Abstract

The binding of phenolic ligands to the insulin hexamer occurs as a cooperative allosteric process. Investigations of the allosteric mechanism from this laboratory resulted in the postulation of a model consisting of a three-state conformational equilibrium and the derivation of a mathematical expression to describe the insulin system. The proposed mechanism involves allosteric transitions among two states of high symmetry, designated T₃T₃‘ (a low affinity state) and R₃R₃‘ (a high affinity state), and a third state of lower symmetry, designated T₃^oR₃^o (a state of mixed low and high affinities). To further characterize this mechanism, we present rapid kinetic fluorescence studies, equilibrium binding isotherms, and molecular modeling investigations for the Co(II)-substituted wild-type and E-B13Q mutant hexamers. These studies show that the measured on and off rates (k_on and k_off) for the binding of the allosteric ligands 2,6- and 2,7-dihydroxynaphthalene provide an independent measure of the dissociation constant for binding to the T₃^oR₃^o conformation (K_R^o). These constants are in agreement with the value obtained by computer fitting of the equilibrium binding isotherms to the quantitative allosteric mechanism. We analyze the structural differences between the T₃^oR₃^o and R₆ phenolic binding sites and predict the structures of the T₃^oR₃^o−2,6-DHN and R₆−2,6-DHN complexes by 3-D molecular modeling. Assignment of H-bonding of the first hydroxyl group to CysA6 and CysA11 has been supported by stacking interactions analogous to phenol using ¹H-NMR. H-bonding of the second hydroxyl group of 2,6-DHN to the GluB13 carboxylate side chains is predicted by molecular modeling and is supported by a reduction of affinity for Ca²⁺, which is postulated to bind to the GluB13 side chains.