Abstract
De novo designed proteins offer a malleable platform for the development of stereoselective transformations not found in biochemistry. Here, we report the de novo design and directed evolution of helical bundle protein catalysts for enantioselective germylation through Ge-H insertion, a transformation not previously achieved by enzymatic catalysis. Comparative computational analysis revealed that, relative to Si-H insertion, the Ge-H insertion reaction proceeds through an earlier and more flexible transition state, introducing distinct challenges for stereocontrol. Using a fully de novo designed truncated four-helix bundle scaffold as the starting point, directed evolution afforded a quadruple mutant that catalyzes Ge-H insertion with high efficiency, enantioselectivity, and broad substrate scope. Molecular dynamics simulations indicated that beneficial mutations introduced from directed evolution enhanced active-site preorganization and modulated local backbone flexibility, contributing to improved transition-state complementarity with fine-tuned binding pocket size and more stable cofactor positioning regulated by hydrogen bonding interactions. These findings showcase the excellent potential for de novo proteins to achieve stereoselective transformations previously unknown to biocatalysts and underscore the importance of active-site remodeling of de novo protein scaffolds via directed evolution in achieving selective catalysis involving flexible transition states.