Abstract
AbstractMicroorganisms are remarkable chemists capable of assembling complex molecular architectures that penetrate cells and bind biomolecular targets with exquisite selectivity. Consequently, microbial natural products have wide-ranging applications in medicine and agriculture. How the “blind watchmaker” of evolution creates skeletal diversity is a key question in contemporary natural products research. Comparative analysis of biosynthetic pathways to structurally related metabolites is an insightful approach to addressing this.Here we report comparative biosynthetic investigations of gladiolin, a polyketide antibiotic fromBurkholderia gladioliwith promising activity against multidrug resistantMycobacterium tuberculosis, and entangien, a structurally related antibiotic produced bySorangium cellulosum. Although these metabolites have very similar macrolide cores, their C21 side chains differ significantly in both length and degree of saturation. Surprisingly, thetrans-acyltransferase polyketide synthases (PKSs) that assemble these antibiotics are almost identical, raising intriguing questions about mechanisms underlying structural diversification in this important class of biosynthetic assembly line.In vitro reconstitution of key biosynthetic transformations using simplified substrate analogues, combined with gene deletion and complementation experiments, enabled us to elucidate the origin of all structural differences in the C21 side chains of gladiolin and etnangien. The more saturated gladiolin side chain arises from a cis-acting enoylreductase (ER) domain in module 1 and in trans recruitment of a standalone ER to module 5 of the PKS. Remarkably, module 5 of the gladiolin PKS is intrinsically iterative in the absence of the standalone ER, accounting for the longer side chain in etnangien. These findings have important implications for biosynthetic engineering approaches to the creation of novel polyketide skeletons.
Publisher
Cold Spring Harbor Laboratory