Handicap-Recover Evolution Leads to a Chemically Versatile, Nucleophile-Permissive Protease

Mutation of the tobacco etch virus (TEV) protease nucleophile from cysteine to serine causes an approximately ∼10(4)-fold loss in activity. Ten rounds of directed evolution of the mutant, TEV(Ser), overcame the detrimental effects of nucleophile exchange to recover near-wild-type activity in the mutant TEV(Ser)X. Rather than respecialising TEV to the new nucleophile, all the enzymes along the evolutionary trajectory also retained the ability to use the original cysteine nucleophile. Therefore the adaptive evolution of TEV(Ser) is paralleled by a neutral trajectory for TEV(Cys), in which mutations that increase serine nucleophile reactivity hardly affect the reactivity of cysteine. This apparent nucleophile permissiveness explains how nucleophile switches can occur in the phylogeny of the chymotrypsin-like protease PA superfamily. Despite the changed key component of their chemical mechanisms, the evolved variants TEV(Ser)X and TEV(Cys)X have similar activities; this could potentially facilitate escape from adaptive conflict to enable active-site evolution.