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Simulation-Guided Engineering Enables a Functional Switch in Selinadiene Synthase toward Hydroxylation

Prabhakar Lal Srivastava, Sam Johns, Angus Voice, Katharine Morley, Andrés M. Escorcia, David J. Miller, Rudolf K. Allemann, Marc W. van der Kamp

2024ACS Catalysis13 citationsDOIOpen Access PDF

Abstract

Engineering sesquiterpene synthases to form predefined alternative products is a major challenge due to their diversity in cyclization mechanisms and our limited understanding of how amino acid changes affect the steering of these mechanisms. Here, we use a combination of atomistic simulation and site-directed mutagenesis to engineer a selina-4(15),7(11)-diene synthase (SdS) such that its final reactive carbocation is quenched by trapped active site water, resulting in the formation of a complex hydroxylated sesquiterpene (selin-7(11)-en-4-ol). Initially, the SdS G305E variant produced 20% selin-7(11)-en-4-ol. As suggested by modeling of the enzyme-carbocation complex, selin-7(11)-en-4-ol production could be further improved by varying the pH, resulting in selin-7(11)-en-4-ol becoming the major product (48%) at pH 6.0. We incorporated the SdS G305E variant along with genes from the mevalonate pathway into bacterial BL21(DE3) cells and demonstrated the production of selin-7(11)-en-4-ol at a scale of 10 mg/L in batch fermentation. These results highlight opportunities for the simulation-guided engineering of terpene synthases to produce predefined complex hydroxylated sesquiterpenes.

Topics & Concepts

HydroxylationATP synthaseChemistryCatalysisCombinatorial chemistryEnzymeBiochemistryComputer scienceBiochemical engineeringComputational biologyEngineeringBiologyPlant biochemistry and biosynthesisMicrobial Metabolic Engineering and BioproductionComputational Drug Discovery Methods
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