Superoxide dismutase (SOD) leads the front line of defense against injuries mediated by the reactive oxygen species (ROS). The SOD from a high-altitude plant Potentilla atrosanguinea is a unique thermostable enzyme. In this study, we applied a structure-guided consensus approach on Cu,Zn SOD from Potentilla atrosanguinea plant, to improve its enzymatic properties. The polar uncharged amino acid (threonine) at position 97 of wild-type (WT) SOD was selected as a target residue for substitution by aspartate (T97D) through site-directed mutagenesis. The WT and T97D were examined by a combinative approach consisting of robust computational and experimental tools. The in-silico analysis indicated improved dimeric stability in T97D as compared to the WT. The strong interactions between the monomers were related to improved dimerization and enhanced catalytic efficiency of T97D. These results were validated by in-vitro assays showing improved dimer stability and catalytic efficiency in T97D than WT. Moreover, the mutation also improved the thermostability of the enzyme. The combined structural and functional data described the basis for improved specific activity and thermostability. This study could expand the scope of interface residue to be explored as targets for designing of SODs with improved kinetics.
Keywords: Catalytic efficiency; Dimeric content; Molecular dynamics simulations; Site-directed mutagenesis; Superoxide dismutase; Thermostability.
Copyright © 2021 Elsevier B.V. All rights reserved.