Kamileen, M. O.; Nakamura, Y.; Luck, K.; Heinicke, S.; Hong, B.; Colinas, M.; Lichman, B. R.; O'Connor, S. E.

Plant-specialized metabolism is largely driven by the oxidative tailoring of key chemical scaffolds catalyzed by cytochrome P450 (CYP450s) enzymes. The monoterpene indole alkaloids tabersonine and pseudo-tabersonine, found in the medicinal plant Tabernanthe iboga, are extensively modified by oxidative reactions. Here we developed a streamlined screening strategy to screen the activity of T. iboga CYP450s in Nicotiana benthamiana. Using multigene constructs encoding the biosynthesis of tabersonine and pseudo-tabersonine scaffolds, we set out to uncover the CYP450s responsible for oxidative transformations of these scaffolds. Our approach identified two T. iboga cytochrome P450 enzymes: pachysiphine synthase (PS) and 16-hydroxy-tabersonine synthase (T16H). These enzymes catalyze an epoxidation and site-specific hydroxylation of tabersonine to produce pachysiphine and 16-OH-tabersonine, respectively. We further demonstrated that these genes produced the expected products when expressed in Catharanthus roseus flowers. This work provides new insights into the biosynthetic pathways of MIAs and underscores the utility of N. benthamiana and C. roseus as platforms for the functional characterization of plant enzymes.