FoTO1 orchestrates Taxol biosynthesis through catalytic and non-catalytic mechanisms

Taxol is a blockbuster chemotherapeutic derived from the Pacific Yew tree. Recent work in our group has identified a complete pathway to baccatin III, a key intermediate, that hinges on a novel accessory protein, Facilitator of Taxane Oxidation (FoTO1). This protein dramatically improves yield and alters enzyme product profiles when reconstituting the Taxol pathway in N. benthamiana . FoTO1 has been shown to act early in the biosynthetic pathway improving the yields of product generated by the combination of a plastidial diterpene synthase (taxadiene synthase) and an endoplasmic reticulum (ER) localized cytochrome P450 (T5-alpha-hydroxylase). Here, we show that FoTO1 is an enzyme capable of converting taxadiene-(4),5-epoxide, the likely product of T5αH oxidation, into taxadien-5α-ol. FoTO1 is also functional in yeast, resolving a key bottleneck for development of a bioproduction route to Taxol in this host. Targeted mutagenesis of key catalytic residues in FoTO1 abrogates function in vitro but not in planta , suggesting non-catalytic contributions of FoTO1 to the taxane pathway. A combination of proximity labelling, bimolecular fluorescence complementation assays, and co-immunoprecipitation studies revealed that FoTO1 interacts with and organizes various P450s in the Taxol pathway. These approaches highlight the importance of both FoTO1’s catalytic and non-catalytic functions in improving yields in the early Taxol pathway. Beyond Taxol biosynthesis, FoTO1 boosts yields for diverse diterpene pathways from across phylogeny, suggesting a general role of this protein class in mediating metabolism across the plastid and ER in plants.