Snapshots along the catalytic path of KabA, a PLP-dependent aminotransferase required for kanosamine biosynthesis in Bacillus cereus UW85.

Kanosamine is an antibiotic and antifungal monosaccharide. The kanosamine biosynthetic pathway from glucose 6-phosphate in Bacillus cereus UW85 was recently reported, and the functions of each of the three enzymes in the pathway, KabA, KabB and KabC, were demonstrated. KabA, a member of a subclass of the VIß family of PLP-dependent aminotransferases, catalyzes the second step in the pathway, generating kanosamine 6-phosphate (K6P) using l-glutamate as the amino-donor. KabA catalysis was shown to be extremely efficient, with a second-order rate constant with respect to K6P transamination of over 107 M-1s-1. Here we report the high-resolution structure of KabA in both the PLP- and PMP-bound forms. In addition, co-crystallization with K6P allowed the structure of KabA in complex with the covalent PLP-K6P adduct to be solved. Co-crystallization or soaking with glutamate or 2-oxoglutarate did not result in crystals with either substrate/product. Reduction of the PLP-KabA complex with sodium cyanoborohydride gave an inactivated enzyme, and crystals of the reduced KabA were soaked with the l-glutamate analog glutarate to mimic the KabA-PLP-l-glutamate complex. Together these four structures give a complete picture of how the active site of KabA recognizes substrates for each half-reaction. The KabA structure is discussed in the context of homologous aminotransferases.

The kanosamine biosynthetic pathway in Bacillus cereus UW85: Functional and kinetic characterization of KabA, KabB, and KabC.

Kanosamine is an aminosugar antibiotic, and component of complex antibiotics such as kanamycin. The biosynthesis of kanosamine varies among different bacteria; best known is a pathway starting from UDP-glucose, but Bacillus subtilis can produce kanosamine in a three-step pathway from glucose 6-phosphate. A set of genes proposed to encode a kanosamine pathway has previously been identified within the zwittermicin A gene cluster of Bacillus cereus UW85. These genes, designated kabABC, are similar to the B. subtilis kanosamine pathway genes (ntdABC), but have never been studied experimentally. We have expressed each of the kab genes, and studied the in vitro substrate scope and reaction rates and kinetic mechanisms of all three enzymes. The kab genes encode enzymes that catalyze a route similar to that found in B. subtilis from glucose 6-phosphate to kanosamine, passing through an unusual and unstable 3-keto intermediate. Kinetic studies show the first step in the pathway, the KabC-catalyzed oxidation of glucose 6-phosphate at carbon-3, is very slow relative to the subsequent KabA-catalyzed aminotransferase and KabB-catalyzed phosphatase reactions. KabC differs from its homolog, NtdC, in that it is NADP- rather than NAD-dependent. The KabA kinetic study is the first such report for a kanosamine 6-phosphate aminotransferase, revealing an extremely efficient PLP-dependent reaction. These results show that this kanosamine biosynthesis pathway occurs in more than one organism, and that the reactions are tuned in order to avoid any accumulation of the unstable intermediate.