apramycin and paromamine

A radical S-adenosyl-l-methionine dehydratase AprD4 and an NADPH-dependent reductase AprD3 are responsible for the C3'-deoxygenation of pseudodisaccharide paromamine in the biosynthesis of apramycin. These enzymes are involved in the construction of the characteristic structural motif that is not modified by 3'-phosphotransferase in aminoglycoside-resistant bacterial strains. AprD4 catalyzes the C3'-dehydration of paromamine via a radical-mediated reaction mechanism to give 4'-oxolividamine, which is then reduced by AprD3 with NADPH to afford lividamine. In the present study, the substrate specificity of this unique combination of enzymes has been investigated. AprD4 was found to recognize paromamine, neamine, kanamycin C, and kanamycin B to afford 5'-deoxyadenosine as one of products during the C3'-dehydration of aminoglycosides, but not 2'-N-acetylparomamine and paromomycin. Only paromamine and kanamycin C were converted to the corresponding C3'-deoxygenated compounds by AprD4 and AprD3. AprD3 recognizes the 4'-oxolividamine moiety, including the pseudotrisaccharide kanamycin C, and seems to reject the amino group at C6' of neamine and kanamycin B. Chirally deuterium-labeled NADPH was used to identify that that AprD3 transfers the pro-S hydrogen atom of NADPH when reducing 4'-oxolividamine to give lividamine.

Topics: Actinobacteria; Aminoglycosides; Anti-Bacterial Agents; Hydro-Lyases; Kanamycin; NADP; Nebramycin; Substrate Specificity

Apramycin is a clinically interesting aminoglycoside antibiotic (AGA) containing a highly unique bicyclic octose moiety, and this octose is deoxygenated at the C3 position. Although the biosynthetic pathways for most 2-deoxystreptamine-containing AGAs have been well characterized, the pathway for apramycin biosynthesis, including the C3 deoxygenation process, has long remained unknown. Here we report detailed investigation of apramycin biosynthesis by a series of genetic, biochemical and bioinformatical studies. We show that AprD4 is a novel radical S-adenosyl-l-methionine (SAM) enzyme, which uses a noncanonical CX3CX3C motif for binding of a [4Fe-4S] cluster and catalyzes the dehydration of paromamine, a pseudodisaccharide intermediate in apramycin biosynthesis. We also show that AprD3 is an NADPH-dependent reductase that catalyzes the reduction of the dehydrated product from AprD4-catalyzed reaction to generate lividamine, a C3' deoxygenated product of paromamine. AprD4 and AprD3 do not form a tight catalytic complex, as shown by protein complex immunoprecipitation and other assays. The AprD4/AprD3 enzyme system acts on different pseudodisaccharide substrates but does not catalyze the deoxygenation of oxyapramycin, an apramycin analogue containing a C3 hydroxyl group on the octose moiety, suggesting that oxyapramycin and apramycin are partitioned into two parallel pathways at an early biosynthetic stage. Functional dissection of the C6 dehydrogenase AprQ shows the crosstalk between different AGA biosynthetic gene clusters from the apramycin producer Streptomyces tenebrarius, and reveals the remarkable catalytic versatility of AprQ. Our study highlights the intriguing chemistry in apramycin biosynthesis and nature's ingenuity in combinatorial biosynthesis of natural products.

Topics: Aminoglycosides; Carbohydrate Sequence; Catalysis; Nebramycin; Oxidoreductases; Oxygen; Substrate Specificity