Abstract
Modification of natural products with prenyl groups and the ensuing oxidative transformations are important for introducing structural complexity and biological activities. Penigequinolones (1) are potent insecticidal alkaloids that contain a highly modified 10-carbon prenyl group. Here we reveal an iterative prenylation mechanism for installing the 10-carbon unit using two aromatic prenyltransferases (PenI and PenG) present in the gene cluster of 1 from Penicillium thymicola. The initial Friedel-Crafts alkylation is catalyzed by PenI to yield dimethylallyl quinolone 6. The five-carbon side chain is then dehydrogenated by a flavin-dependent monooxygenase to give aryl diene 9, which serves as the electron-rich substrate for a second alkylation with dimethylallyl diphosphate to yield stryrenyl product 10. The completed, oxidized 10-carbon prenyl group then undergoes further structural morphing to yield yaequinolone C (12), the immediate precursor of 1. Our studies have therefore uncovered an unprecedented prenyl chain extension mechanism in natural product biosynthesis.