Protein dynamics are often invoked in explanations of enzyme catalysis, but their design has proven elusive. Here we track the role of dynamics in evolution, starting from the evolvable and thermostable ancestral protein Anc(HLD-RLuc) which catalyses both dehalogenase and luciferase reactions. Insertion-deletion (InDel) backbone mutagenesis of Anc(HLD-RLuc) challenged the scaffold dynamics. Screening for both activities reveals InDel mutations localized in three distinct regions that lead to altered protein dynamics (based on crystallographic B-factors, hydrogen exchange, and molecular dynamics simulations). An anisotropic network model highlights the importance of the conformational flexibility of a loop-helix fragment of Renilla luciferases for ligand binding. Transplantation of this dynamic fragment leads to lower product inhibition and highly stable glow-type bioluminescence. The success of our approach suggests that a strategy comprising (i) constructing a stable and evolvable template, (ii) mapping functional regions by backbone mutagenesis, and (iii) transplantation of dynamic features, can lead to functionally innovative proteins.
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 Renilla 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 Renilla 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 Renilla luciferase RLuc8, thereby addressing a limitation of a popular molecular probe. 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.
Title: Functional Trade-Offs in Promiscuous Enzymes Cannot Be Explained by Intrinsic Mutational Robustness of the Native Activity Kaltenbach M, Emond S, Hollfelder F, Tokuriki N Ref: PLoS Genet, 12:e1006305, 2016 : PubMed
The extent to which an emerging new function trades off with the original function is a key characteristic of the dynamics of enzyme evolution. Various cases of laboratory evolution have unveiled a characteristic trend; a large increase in a new, promiscuous activity is often accompanied by only a mild reduction of the native, original activity. A model that associates weak trade-offs with "evolvability" was put forward, which proposed that enzymes possess mutational robustness in the native activity and plasticity in promiscuous activities. This would enable the acquisition of a new function without compromising the original one, reducing the benefit of early gene duplication and therefore the selection pressure thereon. Yet, to date, no experimental study has examined this hypothesis directly. Here, we investigate the causes of weak trade-offs by systematically characterizing adaptive mutations that occurred in two cases of evolutionary transitions in enzyme function: (1) from phosphotriesterase to arylesterase, and (2) from atrazine chlorohydrolase to melamine deaminase. Mutational analyses in various genetic backgrounds revealed that, in contrast to the prevailing model, the native activity is less robust to mutations than the promiscuous activity. For example, in phosphotriesterase, the deleterious effect of individual mutations on the native phosphotriesterase activity is much larger than their positive effect on the promiscuous arylesterase activity. Our observations suggest a revision of the established model: weak trade-offs are not caused by an intrinsic robustness of the native activity and plasticity of the promiscuous activity. We propose that upon strong adaptive pressure for the new activity without selection against the original one, selected mutations will lead to the largest possible increases in the new function, but whether and to what extent they decrease the old function is irrelevant, creating a bias towards initially weak trade-offs and the emergence of generalist enzymes.
Here, we report the use of Yarrowia lipolytica as a versatile expression host for developing protein engineering approaches to modify the properties of Candida antarctica lipase B. A reliable screening protocol was defined and validated using a saturation mutagenesis library, yielding mutants displaying higher catalytic efficiencies than the wild-type enzyme.
