Identification of the residues responsible for the alkaline inhibition of Cu, Zn superoxide dismutase: A site‐directed mutagenesis approach

Abstract

The catalytic rate of wild type, two single (Lys 120 → Leu, Lys 134 → Thr), and one double (Lys 120 → Leu‐Lys 134 → Thr) mutants of Xenopus laevis B Cu, Zn superoxide dismutase has been studied by pulse radiolysis as a function of pH. The pH dependence curve of the activity of the wild‐type enzyme can be deconvoluted by two deprotonation equilibria, at pH 9.3 (pK₁) and at pH 11.3 (pK₂). Catalytic rate measurements on single and double mutants indicate that pK₁ is mainly due to the deprotonation of Lys 120 and Lys 134, with only a minor contribution from other surface basic residues, whereas pK₂ is due to titration of the invariant Arg 141, likely coupled to deprotonation of the copper‐bound water molecule. Accordingly, Brownian dynamics simulations carried out as a function of pH reproduce well the pH dependence of the catalytic rate, when the experimentally determined pKs are assigned to Lys 120, Lys 134, and Arg 141.