Genetic characterization of enzymes involved in the priming steps of oxytetracycline biosynthesis in Streptomyces rimosus

Abstract

Tetracyclines are clinically important aromatic polyketides whose biosynthesis is catalysed by bacterial type II polyketide synthases (PKSs). Tetracyclines are biosynthesized starting with an amide-containing malonamate starter unit and the resulting C-2 carboxyamide is critical for the antibiotic activities. In this work, we genetically verified that an amidotransferase, OxyD, and a thiolase, OxyP, are involved in the biosynthesis and incorporation of the starter unit. First, two mutations, R248T and D268N, were found to be present in OxyD* encoded in Streptomyces rimosus ATCC 13224, a strain that produces the acetate-primed 2-acetyl-2-decarboxyamido-oxytetracycline (ADOTC) instead of the malonamate-primed oxytetracycline (OTC). Homology modelling suggested that in particular D268N may inactivate OxyD. Complementation of S. rimosus ATCC 13224 with wild-type OxyD restored OTC biosynthesis, thereby confirming the essential role of OxyD in the synthesis of the amide starter unit. Second, using a series of knockout and complementation approaches, we demonstrated that OxyP is most likely involved in maintaining fidelity of the amide-priming process via hydrolysis of the competing acetate priming starter units. While the inactivation of OxyP does not eliminate OTC biosynthesis, the ratio of acetate-primed ADOTC to malonamate-primed OTC is significantly increased. This suggests that OxyP plays an ancillary role in OTC biosynthesis and is important for minimizing the levels of ADOTC, a shunt product that has much weaker antibiotic activities than OTC.