Nucleotidyl transfer is an archetypal enzyme reaction central to DNA replication and repair. Here we describe a variation of the nucleotidylation reaction termed "catch and release" that is used by an antibiotic modifying enzyme. The aminoglycoside nucleotidyl transferase 4' (ANT4') inactivates antibiotics such as kanamycin and neomycin through nucleotidylation within an active site that shares significant structural, and inferred underlying catalytic similarity, with human DNA polymerase beta. Here we follow the entire nucleotidyl transfer reaction coordinate of ANT4' covalently inactivating neomycin using X-ray crystallography. These studies show that although the underlying reaction mechanism is conserved with polymerases, a short 2.35 A hydrogen bond is initially formed to facilitate tight binding of the aminoglycoside substrate and is subsequently disrupted by the assembly of the catalytically active ternary complex. This enables the release of products post catalysis due to a lower free energy of the product state compared to the starting substrate complex. We propose that this "catch and release" mechanism of antibiotic turnover observed in ANT4' is a variation of nucleotidyl transfer that has been adapted for the inactivation of antibiotics.
Keywords: DNA polymerase; aminoglycoside; antibiotic resistance; nucleotidyl transfer; short hydrogen bond.