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Abstract
Natural products with rare functional groups are likely to be constructed by unique biosynthetic enzymes. One such rare functional group is the O-methyl nitronate, which can undergo [3 + 2] cycloaddition reactions with olefins in mild conditions. O-methyl nitronates are found in some natural products; however, how such O-methyl nitronates are assembled biosynthetically is unknown. Here we show that the assembly of the O-methyl nitronate in the natural product enteromycin carboxamide occurs via activation of glycine on a peptidyl carrier protein, followed by reaction with a diiron oxygenase to give a nitronate intermediate and then with a methyltransferase to give an O-methyl nitronate. Guided by the discovery of this pathway, we then identify related cryptic biosynthetic gene cassettes in other bacteria and show that these alternative gene cassettes can, instead, facilitate oxidative denitrification of glycine-derived nitronates. Altogether, our work reveals bifurcating pathways from a central glycine-derived nitronate intermediate in bacteria. O-methyl nitronate is a rare functional group in natural products. Now, the biosynthetic pathway to O-methyl nitronate, which involves O-methylation of a peptidyl carrier protein (PCP)-tethered nitronate, has been revealed. In some bacteria, the same PCP-tethered nitronate is shown to be oxidized by nitronate monooxygenases to provide nitrite and a PCP-tethered glyoxylate.Cite this article
He, HY., Ryan, K.S. Glycine-derived nitronates bifurcate to O-methylation or denitrification in bacteria. Nat. Chem. (2021). https://doi.org/10.1038/s41557-021-00656-8 