N-Formimidoylation/-iminoacetylation modification in aminoglycosides requires FAD-dependent and ligand-protein NOS bridge dual chemistry.
Yung-Lin WangChin-Yuan ChangNing-Shian HsuI-Wen LoKuan-Hung LinChun-Liang ChenChi-Fon ChangZhe-Chong WangYasushi OgasawaraTohru DairiChitose MaruyamaYoshimitsu HamanoTsung-Lin LiPublished in: Nature communications (2023)
Oxidized cysteine residues are highly reactive and can form functional covalent conjugates, of which the allosteric redox switch formed by the lysine-cysteine NOS bridge is an example. Here, we report a noncanonical FAD-dependent enzyme Orf1 that adds a glycine-derived N-formimidoyl group to glycinothricin to form the antibiotic BD-12. X-ray crystallography was used to investigate this complex enzymatic process, which showed Orf1 has two substrate-binding sites that sit 13.5 Å apart unlike canonical FAD-dependent oxidoreductases. One site could accommodate glycine and the other glycinothricin or glycylthricin. Moreover, an intermediate-enzyme adduct with a NOS-covalent linkage was observed in the later site, where it acts as a two-scissile-bond linkage facilitating nucleophilic addition and cofactor-free decarboxylation. The chain length of nucleophilic acceptors vies with bond cleavage sites at either N-O or O-S accounting for N-formimidoylation or N-iminoacetylation. The resultant product is no longer sensitive to aminoglycoside-modifying enzymes, a strategy that antibiotic-producing species employ to counter drug resistance in competing species.
Keyphrases
- nitric oxide synthase
- genome wide
- small molecule
- hiv testing
- living cells
- fluorescent probe
- amino acid
- high resolution
- magnetic resonance
- gene expression
- hydrogen peroxide
- computed tomography
- dna methylation
- cancer therapy
- men who have sex with men
- protein protein
- dual energy
- electron microscopy
- drug resistant
- antiretroviral therapy