Production and NMR analysis of the human ibuprofen metabolite 3-hydroxyibuprofen.

The anti-inflammatory drug ibuprofen (Ibu) is metabolized in the human liver to a number of metabolites including 1-hydroxyibuprofen (1-OH-Ibu), 2-OH-Ibu, and 3-OH-Ibu, respectively. The only human CYP known to produce relevant amounts of 3-OH-Ibu is CYP2C9 and as genetic polymorphisms of CYP2C9 influence the metabolization of numerous drugs, the availability of reference standards for CYP2C9-specific metabolites is of considerable interest. The aim of this study was to develop a biological production process for 3-OH-Ibu and to affirm its NMR characteristics. The recombinant fission yeast strain CAD68 coexpressing human CYP2C9 and CPR was used for the whole-cell biotransformation of Ibu to 3-OH-Ibu in 1L batch-scale for 75h. The average space-time yield for the bioproduction of 3-OH-Ibu (125±34µmol/Ld) considerably exceeded that of 2-OH-Ibu (44±10µmol/Ld). Accordingly, average biotransformation activities normalized to dry biomass weight were 5.0±0.8µmol/gd (3-OH-Ibu) and 1.9±0.7µmol/gd (2-OH-Ibu). The metabolite was prepurified on preparative TLC-plates, isolated by HPLC fractionation, and characterized by LC-MS and NMR. As expected, differential fragmentation patterns of 2-OH-Ibu and 3-OH-Ibu were detected in ESI-LC-MS analysis. 44mg of 3-OH-Ibu was efficiently purified from four 1L batch cultures and its structure was clearly confirmed by one- and two-dimensional NMR.

Mutasynthesis-derived myxalamids and origin of the isobutyryl-CoA starter unit of myxalamid B.

Myxalamids are potent inhibitors of the eukaryotic electron transport chain produced by different myxobacteria. Here, we describe the identification of the myxalamid biosynthesis gene cluster from Myxococcus xanthus. Additionally, new myxalamids (5-13) have been obtained by mutasynthesis from bkd mutants of M. xanthus and Stigmatella aurantiaca. Moreover, as these bkd mutants are still able to produce myxalamid B (2), the origin of the isobutyryl-CoA (IB-CoA) starter unit required for its biosynthesis has been determined. In a M. xanthus bkd mutant, IB-CoA originates from valine, but in S. aurantiaca this starter unit is derived from alpha-oxidation of iso-odd fatty acids, thereby connecting primary and secondary metabolism.