CreE is a flavin-dependent monooxygenase (FMO) that catalyzes three sequential nitrogen oxidation reactions of L-aspartate to produce nitrosuccinate, contributing to the biosynthesis of the antimicrobial and antiproliferative nautral product, cremeomycin. This compound contains a highly reactive diazo functional group for which the reaction of CreE is essential to its formation. Nitro and diazo functional groups can serve as potent electrophiles, important in some challenging nucleophilic addition reactions. Formation of these reactive groups positions CreE as a promising candidate for biomedical and synthetic applications. Here, we present the catalytic mechanism of CreE and the identification of active site r... More
CreE is a flavin-dependent monooxygenase (FMO) that catalyzes three sequential nitrogen oxidation reactions of L-aspartate to produce nitrosuccinate, contributing to the biosynthesis of the antimicrobial and antiproliferative nautral product, cremeomycin. This compound contains a highly reactive diazo functional group for which the reaction of CreE is essential to its formation. Nitro and diazo functional groups can serve as potent electrophiles, important in some challenging nucleophilic addition reactions. Formation of these reactive groups positions CreE as a promising candidate for biomedical and synthetic applications. Here, we present the catalytic mechanism of CreE and the identification of active site residues critical to binding L-aspartate, aiding in future enzyme engineering efforts. Steady-state analysis demonstrated that CreE is very specific for NADPH over NADH and performs a highly coupled reaction with L-aspartate. Analysis of the rapid-reaction kinetics showed that flavin reduction is very fast, along with the formation of the oxygenating species, the C4a-hydroperoxyflavin. The slowest step observed was the dehydration of the flavin. Structural analysis and site-directed mutagenesis implicated T65, R291, and R440 in the binding L-aspartate. The data presented describes the catalytic mechanism and the active site architecture of this unique FMO.