In vivo investigation of the roles of FdmM and FdmM1 in fredericamycin biosynthesis unveiling a new family of oxygenases.

Fredericamycin (FDM) A, a highly oxidized aromatic pentadecaketide natural product, exhibits potent cytotoxicity and has been studied as a new anticancer drug lead. The FDM biosynthetic gene cluster has been previously cloned from Streptomyces griseus ATCC 49344 and successfully expressed in the heterologous host Streptomyces albus J1074. The fdmM and fdmM1 genes code for two proteins with high sequence homology to each other but unknown function. In-frame deletion of each of the genes from the fdm cluster was accomplished in the S. albus host. Each mutant failed to produce FDM A and the key biosynthetic intermediate FDM E but produced various new metabolites, the titers of which were dramatically increased via overexpression of an fdm pathway-specific activator fdmR1. The DeltafdmM mutant strain accumulated three new compounds FDM M-1, FDM M-2, and FDM M-3, whereas the DeltafdmM1 mutant strain produced one new compound FDM M1-1. Isolation and structural characterization of these compounds enable us to propose that FdmM and FdmM1 catalyze the C-6 and C-8 hydroxylations for FDM biosynthesis, respectively. Homologs of FdmM and FdmM1 can be found in biosynthetic gene clusters of many other aromatic polyketides, ranging from dodecaketides to pentadecaketides, but to date all of them were annotated as proteins of unknown function. Based on the findings reported here for FdmM and FdmM1, we now propose similar functions for those proteins, and FdmM and FdmM1 therefore represent an emerging family of novel oxygenases responsible for hydroxylation of aromatic polyketide natural products.