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Characterization of a Radical SAM Oxygenase for the Ether Crosslinking in Darobactin Biosynthesis.

Hai NguyenI Dewa Made KresnaNils BöhringerJeremie RuelEugenio de la MoraJil-Christine KramerKim LewisYvain NicoletTill F SchäberleKenichi Yokoyama
Published in: Journal of the American Chemical Society (2022)
Darobactin A is a ribosomally synthesized, post-translationally modified peptide (RiPP) with potent and broad-spectrum anti-Gram-negative antibiotic activity. The structure of darobactin A is characterized by an ether and C-C crosslinking. However, the specific mechanism of the crosslink formation, especially the ether crosslink, remains elusive. Here, using in vitro enzyme assays, we demonstrate that both crosslinks are formed by the DarE radical S -adenosylmethionine (SAM) enzyme in an O 2 -dependent manner. The relevance of the observed activity to darobactin A biosynthesis was demonstrated by proteolytic transformation of the DarE product into darobactin A. Furthermore, DarE assays in the presence of 18 O 2 or [ 18 O]water demonstrated that the oxygen of the ether crosslink originates from O 2 and not from water. These results demonstrate that DarE is a radical SAM enzyme that uses oxygen as a co-substrate in its physiologically relevant function. Since radical SAM enzymes are generally considered to function under anaerobic environments, the discovery of a radical SAM oxygenase represents a significant change in the paradigm and suggests that these radical SAM enzymes function in aerobic cells. Also, the study revealed that DarE catalyzes the formation of three distinct modifications on DarA; ether and C-C crosslinks and α,β-desaturation. Based on these observations, possible mechanisms of the DarE-catalyzed reactions are discussed.
Keyphrases
  • gram negative
  • ionic liquid
  • multidrug resistant
  • small molecule
  • microbial community
  • wastewater treatment
  • cell death
  • cell proliferation
  • signaling pathway
  • room temperature
  • risk assessment
  • high intensity