Probing electrostatic interactions in cytochromecusing site-directed chemical modification

Abstract

This communication reports the generation of an electrostatic probe using chemical modification of methionine side chains. The alkylation of methionine by iodoacetamide was achieved in a set of Saccharomyces cerevisiae iso-1-cytochrome c mutants, introducing the nontitratable, nondelocalized positive charge of a carboxyamidomethylmethionine sulfonium (CAMMS) ion at five surface and one buried site in the protein. Changes in redox potential and its variation with temperature were used to calculate microscopic effective dielectric constants operating between the probe and the heme iron. Dielectric constants (ε) derived from ΔΔG values were not useful due to entropic effects, but εΔΔHgave results that supported the theory. The effect on biological activity of surface derivatization was interpreted in terms of protein–protein interactions. The introduction of an electrostatic probe in cytochrome c often resulted in marked effects on activity with one of two physiological partners: cytochrome c reductase, especially if introduced at position 65, and cytochrome c oxidase, if at position 28.Key words: protein engineering, chemical modification, cytochrome c, electron transport, protein electrostatics, redox potential control.