Quantitative structure-activity relationships in two-electron reduction of nitroaromatic compounds by Enterobacter cloacae NAD(P)H:nitroreductase.

Enterobacter cloacae NAD(P)H:nitroreductase (NR; EC 1.6.99.7) catalyzes the reduction of a series of nitroaromatic compounds with steady-state bimolecular rate constants (kcat/Km) ranging from 10(4) to 10(7) M(-1) s(-1). In agreement with a previously proposed scheme of two-step four-electron reduction of nitroaromatics by NR (Koder, R. L., and Miller, A.-F. (1998) Biochim. Biophys. Acta 1387, 395-405), 2 mol NADH per mole mononitrocompound were oxidized. An oxidation of excess NADH by polinitrobenzenes, including explosives 2,4,6-trinitrotoluene (TNT) and 2,4,6-trinitrophenyl-N-methylnitramine (tetryl), has been observed as a slower secondary process, accompanied by O2 consumption. This type of "redox cycling" was not related to reactions of nitroaromatic anion-radicals, but was caused by the autoxidation of relatively stable reaction products. The initial reduction of tetryl and other polinitrophenyl-N-nitramines by E. cloacae NR was analogous to a two-step four-electron reduction mechanism of TNT and other nitroaromatics. The logs kcat/Km of all the compounds examined exhibited parabolic dependence on their enthalpies of single-electron or two-electron (hydride) reduction, obtained by quantum mechanical calculations. This type of quantitative structure-activity relationship shows that the reactivity of nitroaromatics towards E. cloacae nitroreductase depends mainly on their hydride accepting properties, but not on their particular structure, and does not exclude the possibility of multistep hydride transfer.

Retro-nitroreductase, a putative evolutionary precursor to Enterobacter cloacae strain 96-3 nitroreductase.

Enterobacter cloacae strain 96-3 nitroreductase (NR) is a homodimeric flavoenzyme that catalyzes the pyridine nucleotide-dependent four-electron reduction of a variety of nitroaromatic compounds, including the explosives TNT (2,4,6-trinitrotoluene), RDX (1,3,5-trinitro-1,3,5-triazine), tetryl (2,4,6-trinitrophenyl-N-methylnitramine), and pentryl (2,4,6-trinitrophenyl-N-nitroaminoethylnitrate). The enzyme was initially characterized by Bryant et al. from a strain of Enterobacter that had been isolated from a weapons dump in La Jolla, CA. The enzyme displays a catalytic efficiency for nitroreduction at least 10-fold higher than that of several highly homologous bacterial nitroreductases and has long been thought to have evolved to be a more efficient nitroreductase due to the high nitroaromatic compound concentrations in its environment. We report the cloning and biochemical characterization of a nitroreductase gene from a clinical isolate of Enterobacter cloacae, a strain that presumably had not encountered high concentrations of nitroaromatics. The new enzyme, which we term retro-nitroreductase, had an amino acid sequence 96.7% identical to NR, and most differences are relatively conservative. The catalytic efficiency of the new enzyme is twofold less than that of NR for the oxidation of NADH and is not significantly different from the value observed for NR for the reduction of dinitrobenzyl alcohol. We conclude that NR has not significantly evolved to be a more efficient nitroreductase as a result of its environment, and the relatively high catalytic activity of the enzyme is a general property of Enterobacter cloacae nitroreductases.

Mutational and spectroscopic studies of the significance of the active site glutamine to metal ion specificity in superoxide dismutase.

We are addressing the puzzling metal ion specificity of Fe- and Mn-containing superoxide dismutases (SODs) [see C.K.Vance, A.-F. Miller. J. Am. Chem. Soc. 120(3) (1998) 461-467]. Here, we test the significance to activity and active site integrity of the Gln side chain at the center of the active site hydrogen bond network. We have generated a mutant of MnSOD with the active site Gln in the location characteristic of Fe-specific SODs. The active site is similar to that of MnSOD when Mn2+, Fe3+ or Fe2+ are bound, based on EPR and NMR spectroscopy. However, the mutant's Fe-supported activity is at least 7% that of FeSOD, in contrast to Fe(Mn)SOD, which has 0% of FeSOD's activity. Thus, moving the active site Gln converts Mn-specific SOD into a cambialistic SOD and the Gln proves to be important but not the sole determinant of metal-ion specificity. Indeed, subtle differences in the spectra of Mn2+, Fe3+ and 1H in the presence of Fe2+ distinguish the G77Q, Q146A mut-(Mn)SOD from WT (Mn)SOD, and may prove to be correlated with metal ion activity. We have directly observed the side chain of the active site Gln in Fe2+ SOD and Fe2+ (Mn)SOD by 15N NMR. The very different chemical shifts indicate that the active site Gln interacts differently with Fe2+ in the two proteins. Since a shorter distance from Gln to Fe and stronger interaction with Fe correlate with a lower Em in Fe(Mn)SOD, Gln has the effect of destabilizing additional electron density on the metal ion. It may do this by stabilizing OH- coordinated to the metal ion.

Two-electron reduction of nitroaromatic compounds by Enterobacter cloacae NAD(P)H nitroreductase: description of quantitative structure-activity relationships.

Enterobacter cloacae NAD(P)H:nitroreductase catalyzes the reduction of a series of nitroaromatic compounds with steady-state bimolecular rate constants (kcat/Km) ranging from 10(4) M(-1) s(-1) to 10(7) M(-1) s(-1), and oxidizing 2 moles NADH per mole mononitrocompound. Oxidation of excess NADH by polynitrobenzenes including explosives 2,4,6-trinitrotoluene (TNT) and 2,4,6-trinitrophenyl-N-methylnitramine (tetryl), has been observed as a slower secondary process, accompanied by O2 consumption. This type of 'redox cycling' was not related to reactions of nitroaromatic anion-radicals, but was caused by the autoxidation of relatively stable reaction products. The logs kcat/Km of all the compounds examined exhibited parabolic dependence on their enthalpies of single-electron- or two-electron (hydride) reduction, obtained by quantum mechanical calculations. This type of quantitative structure-activity relationships shows that the reactivity of nitroaromatics towards E. cloacae nitroreductase depends mainly on their hydride accepting properties, but not on their particular structure, and does not exclude the possibility of multistep hydride transfer.

Steady-state kinetic mechanism, stereospecificity, substrate and inhibitor specificity of Enterobacter cloacae nitroreductase.

Enterobacter cloacae nitroreductase (NR) is a flavoprotein which catalyzes the pyridine nucleotide-dependent reduction of nitroaromatics. Initial velocity and inhibition studies have been performed which establish unambiguously a ping-pong kinetic mechanism. NADH oxidation proceeds stereospecifically with the transfer of the pro-R hydrogen to the enzyme and the amide moiety of the nicotinamide appears to be the principal mediator of the interaction between NR and NADH. 2,4-Dinitrotoluene is the most efficient oxidizing substrate examined, with a kcat/KM an order of magnitude higher than those of p-nitrobenzoate, FMN, FAD or riboflavin. Dicoumarol is a potent inhibitor competitive vs. NADH with a Ki of 62 nM. Several compounds containing a carboxyl group are also competitive inhibitors vs. NADH. Yonetani-Theorell analysis of dicoumarol and acetate inhibition indicates that their binding is mutually exclusive, which suggests that the two inhibitors bind to the same site on the enzyme. NAD+ does not exhibit product inhibition and in the absence of an electron acceptor, no isotope exchange between NADH and 32P-NAD+ could be detected. NR catalyzes the 4-electron reduction of nitrobenzene to hydroxylaminobenzene with no optically detectable net formation of the putative two-electron intermediate nitrosobenzene.

Overexpression, isotopic labeling, and spectral characterization of Enterobacter cloacae nitroreductase.

Bacterial nitroreductases have generated much interest recently due to their central roles in both nitroaromatic bioremediation and nitroaromatic toxicity, mutagenicity, and carcinogenicity. Enterobacter cloacae nitroreductase (NR) has been subcloned into the pET overexpression system and purified to homogeneity via a four-step procedure resulting in a final yield of 65.7 mg per liter. Overexpression in minimal media containing 15NH4Cl as the sole source of nitrogen yielded 37.6 mg per liter of homogenous NR containing > 99 atom % 15N. A series of melting curves generated under a variety of solvent conditions established the optimal conditions for NR stability as pH 7.5, low ionic strength phosphate buffer. A two-dimensional 1H-15N heteronuclear single quantum coherence nuclear magnetic resonance spectrum demonstrates this enzyme to be amenable to study by high-resolution multidimensional NMR in combination with amino-acid-specific isotopic labeling. Optical spectra of the purified enzyme suggest that the noncovalently bound flavin mononucleotide cofactor binds in a hydrophobic environment and is in the neutral and anionic protonation states in the oxidized and two-electron reduced oxidation states, respectively. NR exhibits a novel visible region circular dichroism spectrum which has a small distinct negative band at 366 nm and a large positive ellipticity at 454 nm with a shoulder centered at 480 nm.

Tartrate dehydrogenase-oxalate complexes: formation of a stable analog of a reaction intermediate complex.

Oxalate has been shown to form a stable complex with Mn-tartrate dehydrogenase-NADH complexes which are proposed to mimic an intermediate formed during catalytic turnover. The formation of this complex can be detected under turnover conditions, where oxalate acts as a time-dependent inhibitor, and under equilibrium conditions, where oxalate binding triggers a slow protein conformation change detectable by fluorescence spectroscopy. Both the rate constant for the change in fluorescence intensity upon oxalate binding and the magnitude of the fluoresence change show a hyperbolic dependence on oxalate concentration. The time-dependent inhibition by oxalate is not consistent with a model in which oxalate binds to enzyme-NAD; rather, it is proposed that inhibition arises from binding to enzyme-NADH. The apparent dissociation constants of oxalate from enzyme-NAD+ and the enzyme-NADH complexes are 80 and 1 microM, respectively. The fluorescence changes which accompany oxalate binding are suggested to arise from a protein conformational change which serves to sequester reactants in the active site. Consistent with this hypothesis, it was observed that although some alternative pyridine nucleotide cofactors supported the multistep tartrate dehydrogenase-catalyzed net nonoxidative decarboxylation of meso-tartrate only at drastically reduced rates, none of the intermediate hydroxypyruvate was released into solution. In addition, fluorescence anisotropy measurements were conducted to investigate the mode of NADH binding.