The hydroxamate moiety of the natural product actinonin mediates inhibition of metalloproteinases because of its chelating properties towards divalent cations in the active site of those enzymes. Owing to its antimicrobial activity, actinonin has serv...
The hydroxamate moiety of the natural product actinonin mediates inhibition of metalloproteinases because of its chelating properties towards divalent cations in the active site of those enzymes. Owing to its antimicrobial activity, actinonin has served as a lead compound for the development of new antibiotic drug candidates. Recently, we identified a putative gene cluster for the biosynthesis of actinonin. Here, we confirm and characterize this cluster by heterologous pathway expression and gene‐deletion experiments. We assigned the biosynthetic gene cluster to actinonin production and determine the cluster boundaries. Furthermore, we establish that ActI, an AurF‐like oxygenase, is responsible for the N‐hydroxylation reaction that forms the hydroxamate warhead. Our findings provide the basis for more detailed investigations of actinonin biosynthesis.
The recently identified putative actinonin biosynthesis gene cluster is herein confirmed and characterized by heterologous pathway expression and gene‐deletion experiments. Furthermore, the actinonin cluster boundaries are determined, and gene‐deletion studies give evidence that ActI, an AurF‐like oxygenase, is required for the N‐hydroxylation reaction that forms the hydroxamate warhead of actinonin.