Abstract

<p>Insertion-deletion mutations are sources of major functional innovations in naturally evolved proteins, but directed evolution methods rely primarily on substitutions. Here, we report a powerful strategy for engineering backbone dynamics based on InDel mutagenesis of a stable and evolvable template, and its validation in application to a thermostable ancestor of haloalkane dehalogenase and <i>Renilla</i> luciferase. First, extensive multidisciplinary analysis linked the conformational flexibility of a loop-helix fragment to binding of the bulky substrate coelenterazine. The fragment’s key role in extant <i>Renilla</i> luciferase was confirmed by transplanting it into the ancestor. This increased its catalytic efficiency 7,000-fold, and fragment-containing mutants showed highly stable glow-type bioluminescence with 100-fold longer half-lives than the flash-type <i>Renilla</i> luciferase <i>RLuc8</i>,<i> </i>thereby addressing a limitation of a popular molecular probe<i>.</i> Thus, our three-step approach: (i) constructing a robust template, (ii) mapping functional regions by backbone mutagenesis, and (iii) transplantation of a dynamic feature, provides a potent strategy for discovering protein modifications with globally disruptive but functionally innovative effects.</p>