Electrostatic Switch Function in the Mechanism of Protein Kinase A Iα Activation: Results of the Molecular Dynamics Simulation.

We used molecular dynamics to find the average path of the A-domain H → B conformational transition in protein kinase A Iα. We obtained thirteen productive trajectories and processed them sequentially using factor and cross-correlation analyses. The conformational transition is presented as partly deterministic sequence of six events. Event B represents H → B transition of the phosphate binding cassette. Main participants of this event form electrostatic switch cAMP(O6)-A202(N-H)-G199(C=O). Through this switch, cAMP transmits information about its binding to hydrophobic switch L203-Y229 and thus triggers conformational transition of A-domain. Events C and D consist in N3A-motif displacement towards phosphate binding cassette and B/C-helix rotation. Event E involves an increase in interaction energy between Y229 and ß-subdomain. Taken together, events B, E, and D correspond to the hinge movement towards ß-barrel. Transition of B/C-helix turn (a.a. 229-234) from α-form to π-form accounts for event F. Event G implies that π-helical turn is replaced by kink. Emerging in the resulting conformation, electrostatic interaction R241-E200 facilitates kink formation. The obtained data on the mechanism of cAMP-dependent activation of PKA Iα may contribute to new approaches to designing pharmaceuticals based on cAMP analogs.

Role of arginine 209 in the conformational transition of the protein kinase A regulatory subunit RIα A-domain.

Using the combination of molecular dynamics (MD) simulations and geometric clustering we analyzed the role of arginine at 209 position in the transition of protein kinase A Iα (PKA Iα) regulatory subunit A-domain from H- to B-conformation and stabilization of the latter. The mechanism underlying the role of the residue at position 209 in the realization of B-conformation includes: (1) possibility to bind the ligand tightly (if transition happens in the presence of cAMP), (2) capability to hold ß2ß3-loop in the correct conformation, (3) tendency of residue at 209 position to stabilize B-conformation in the absence and in presence of the ligand. In terms of the effect produced on transition of A-domain from H- to B-conformation in the presence of cAMP, mutational substitutions for R209 can be arranged in the following order: Glu(Gly)>Lys>Ile. In the absence of cAMP the order is different Lys>Gly>Glu>Ile. Thus, our results allow us to presume that the role of arginine at 209 position can be important though not crucial.