Computational modeling of the rate limiting step in low molecular weight protein tyrosine phosphatase.

Hydrolysis of the phosphoenzyme intermediate is the second and rate limiting step of the reaction catalyzed by the protein tyrosine phosphatases (PTPs). The cysteinyl phosphate thioester bond is cleaved by nucleophilic displacement where an active site water molecule attacks the phosphorus atom. Starting from the crystal structure of the low molecular weight PTP, we study the energetics of this reaction utilizing the empirical valence bond method in combination with molecular dynamics and free energy perturbation simulations. The reactions of the wild-type as well as the D129A and C17S mutants are modeled. For the D129A mutant, which lacks the general acid/base residue Asp-129, an alternative reaction mechanism is proposed. The calculated activation barriers are in all cases in good agreement with experimental reaction rates. The present results together with earlier computational and experimental work now provide a detailed picture of the complete reaction mechanism in many PTPs. The key role played by the structurally invariant signature motif in stabilizing a double negative charge is reflected by its control of the energetics of both transition states and the reaction intermediate.