作者
Samuel A. Bradley,Frederik G. Hansson,Beata Joanna Lehka,Daniela Rago,Pedro Pinho,Huadong Peng,Khem B. Adhikari,Ahmad K. Haidar,Lea G. Hansen,Daria A. Volkova,M Holtz,Sergi Abad,Xin Ma,Κωνσταντίνος Κουδούνας,Sébastien Besseau,Nicolas Gautron,C. Mélin,Jillian Marc,Caroline Birer-Williams,Vincent Courdavault,Emil D. Jensen,Jay D. Keasling,Jie Zhang,Michael K. Jensen
摘要
Monoterpene indole alkaloids (MIAs) make up a highly bioactive class of metabolites produced by a range of tropical and subtropical plants. The corynanthe-type MIAs are a stereochemically complex subclass with therapeutic potential against a large number of indications including cancer, psychotic disorders, and erectile dysfunction. Here, we report yeast-based cell factories capable of de novo production of corynanthe-type MIAs rauwolscine, yohimbine, tetrahydroalstonine, and corynanthine. From this, we demonstrate regioselective biosynthesis of 4 fluorinated derivatives of these compounds and de novo biosynthesis of 7-chlororauwolscine by coexpression of a halogenase with the biosynthetic pathway. Finally, we capitalize on the ability of these cell factories to produce derivatives of these bioactive scaffolds to establish a proof-of-principle drug discovery pipeline in which the corynanthe-type MIAs are screened for bioactivity on human drug targets, expressed in yeast. In doing so, we identify antagonistic and agonistic behavior against the human adrenergic G protein-coupled receptors ADRA2A and ADRA2B, and the serotonergic receptor 5HT4b, respectively. This study thus demonstrates a proto-drug discovery pipeline for bioactive plant-inspired small molecules based on one-pot biocatalysis of natural and new-to-nature corynanthe-type MIAs in yeast.