Abstract
The enzyme QueF catalyzes a four-electron reduction of a nitrile group into an amine, the only reaction of this kind known in biology. In nature, QueF converts 7-cyano-7-deazaguanine (preQ0) into 7-aminomethyl-7-deazaguanine (preQ1) for the biosynthesis of the tRNA-inserted nucleoside queuosine. The proposed QueF mechanism involves a covalent thioimide adduct between preQ0 and a cysteine nucleophile in the enzyme, and this adduct is subsequently converted into preQ1 in two NADPH-dependent reduction steps. Here, we show that the Escherichia coli QueF binds preQ0 in a strongly exothermic process (ΔH = −80.3 kJ/mol; −TΔS = 37.9 kJ/mol, Kd = 39 nm) whereby the thioimide adduct is formed with half-of-the-sites reactivity in the homodimeric enzyme. Both steps of preQ0 reduction involve transfer of the 4-pro-R-hydrogen from NADPH. They proceed about 4–7-fold more slowly than trapping of the enzyme-bound preQ0 as covalent thioimide (1.63 s−1) and are thus mainly rate-limiting for the enzyme's kcat (=0.12 s−1). Kinetic studies combined with simulation reveal a large primary deuterium kinetic isotope effect of 3.3 on the covalent thioimide reduction and a smaller kinetic isotope effect of 1.8 on the imine reduction to preQ1. 7-Formyl-7-deazaguanine, a carbonyl analogue of the imine intermediate, was synthesized chemically and is shown to be recognized by QueF as weak ligand for binding (ΔH = −2.3 kJ/mol; −TΔS = −19.5 kJ/mol) but not as substrate for reduction or oxidation. A model of QueF substrate recognition and a catalytic pathway for the enzyme are proposed based on these data.
Highlights
The enzyme QueF catalyzes a four-electron reduction of a nitrile group into an amine, the only reaction of this kind known in biology
The proposed QueF mechanism involves a covalent thioimide adduct between preQ0 and a cysteine nucleophile in the enzyme, and this adduct is subsequently converted into preQ1 in two NADPH-dependent reduction steps
We show that the Escherichia coli QueF binds preQ0 in a strongly exothermic process (⌬H ؍؊80.3 kJ/mol; ؊T⌬S ؍37.9 kJ/mol, Kd ؍39 nM) whereby the thioimide adduct is formed with halfof-the-sites reactivity in the homodimeric enzyme
Summary
Q, queuosine; preQ0, 7-cyano-7-deazaguanine; preQ1, 7-aminomethyl-7-deazaguanine; QM/MM, quantum mechanics/ molecular mechanics; 7-formyl-preQ0, 7-formyl-7-deazaguanine; ecQueF, E. coli QueF; 2-deamino-preQ0, 7-cyano-2-deamino-7-deazaguanine; 6-deoxo-preQ0, 7-cyano-6-deoxo-7-deazaguanine; LTQ, linear ion trap; FT, Fourier transform; KIE, kinetic isotope effect; ITC, isothermal titration calorimetry. Hydride reduction of the thioimide by NADPH, under protonic assistance by Asp, subsequently gives a covalent hemithioaminal. In B. subtilis QueF, the kcat (0.011 sϪ1) [5, 13] is much smaller than the rate constant of thioimide formation (2.78 sϪ1) [11] This locates the ratedetermining step in the sequence of steps involved in the NADPH-dependent reductions. How does NADPH bind and which of its diastereotopic hydrogens at the nicotinamide C4 is used for hydride transfer in each reduction step? Together with the native preQ0, we used these analogues to characterize the kinetics and thermodynamics of substrate binding by the QueF enzyme from E. coli (ecQueF). We characterized the binding of this analogue to ecQueF and examined its reactivity as substrate for enzymatic reduction or oxidation. We show that the hydride transfer steps are rate-determining in the overall reaction
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