Quenching of the intrinsic fluorescence of liver alcohol dehydrogenase by the alkaline transition and by coenzyme binding

The fluorescence of alcohol dehydrogenase is quenched by the acid dissociation of some group on the protein having an apparent pKa of 9.6 at 25 degrees C. The pKa of this alkaline quenching transition is unchanged by the binding of trifluoroethanol or pyrazole to the enzyme or by the selective removal of the active site of Zn2+ ion. This indicates that the ionization of a zinc-bound water molecule is not responsible for the quenching. The binding of NAD+ to the enzyme causes a drop in protein fluorescence and an apparent shift in the alkaline quenching transition to lower pH. In the ternary complex formed with NAD+ and trifluoroethanol the alkaline transition is difficult to discern between pH 6 and pH 11. In the NAD+-pyrazole ternary complex, however, a small but noticeable fluorescence transition is observed with a pKa(app) approximately 9.5. We propose that the alkaline transition centered at pH 9.6 is not shifted to lower pH upon binding NAD+. Instead, the amplitude of the alkaline quenching effect is decreased to the point that it is difficult to detect when NAD+ is bound. We present a model that describes the dependence of the fluorescence of the protein on pH and NAD+ concentration in terms of two independently operating, dynamic quenching mechanisms. Our data and model cast serious doubt on the identification, made previously in the literature, between the alkaline quenching pKa and the pKa of the group whose ionization is coupled to NAD+ binding.(ABSTRACT TRUNCATED AT 250 WORDS)     

Covalent binding of an NAD+ analogue to horse liver alcohol dehydrogenase in a ternary complex with pyrazole

Examination of the model of the fixation site of the adenosine phosphate part of NAD+ on horse liver alcohol dehydrogenase led us to synthesize a NAD+ analogue N6-[N-(8-amino-3,6-dioxaoctyl)carbamoylmethyl]-NAD+ in order to alkylate the carboxylic acid group of Asp-273 and to convert the normally dissociable coenzyme into a permanently bound prosthetic group. This NAD+ analogue is coupled to the horse liver alcohol dehydrogenase in the ternary complex formed with pyrazole. In these conditions the degree of fixation varies between 0.4 and 0.58 coenzyme molecule/enzyme subunit molecule. The N6-[N-(8-amino-3,6-dioxaoctyl)carbamoylmethyl]NAD+ acts as a true prosthetic group which can be reduced and reoxidized by a coupled substrate reaction and the internal activity of this holoenzyme corresponds to the amount of analogue incorporated.     

pH-dependent changes of intrinsic fluorescence of chemically modified liver alcohol dehydrogenases.

Horse liver alcohol dehydrogenase specifically carboxymethylated on cysteine-46 (a ligand to the zinc in the active site) or acetimidylated on 25 of the 30 lysine residues per subunit (including residue 228) was studied. The tryptophan fluorescence of these enzymes decreased by 35% as pH was increased, with an apparent pKa of 9.8 +/- 0.2, identical with that of native enzyme. Native enzyme in the presence of 30mM-imidazole, which displaces a water molecule ligated to the zinc, also had a pKa of 9.8. The ionoizable group is thus neither the water molecule nor one of the modified groups. Binding of NAD+ shifted the pKa for the fluorescence transition to 7.6 with native enzyme and to 9.0 with acetimidylated enzyme, but did not shift the pKa of carboxymethylated enzyme. Binding of NAD+ and trifluoroethanol, an unreactive alcohol, gave maximal fluorescence quenching at pH7 with all three enzymes. The acetimidylated enzyme--NAD+--trifluoroethanol complex had an apparent pKa of 5.0, but the pK of the native enzyme complex was experimentally inaccessible. The results are interpreted in terms of coupled equilibria between two different conformational states. On binding of NAD+, the modified enzymes apparently change conformation less readily than does native enzyme, but binding of alcohol can drive the change to completion.     

Effect of pH on coenzyme binding to liver alcohol dehydrogenase.

1. The transient-state kinetics of ligand-displacement reactions have been analyzed. Methods based on this analysis have been used to obtain reliable estimates of on-velocity and off-velocity constants for coenzyme binding to liver alcohol dehydrogenase at different pH values between 6 and 10. 2. The rate of NADH dissociation from the enzyme shows no pronounced dependence on pH. The rate of NAD+ dissociation is controlled by a group with a pKa of 7.6, agreeing with the pKa reported to regulate the binding of certain inhibitory substrate analogues to the enzyme . NAD+ complex. 3. Critical experiments have been performed to test a recent proposal that on-velocity constants for the binding of NADH and NAD+ are controlled by proton equilibria exhibiting different pKa values. The results show that association rates for NADH and NAD+ exhibit the same pH dependence corresponding to a pKa of 9.2. Titrimetric evidence is presented indicating that the latter effect of pH derives from ionization of a group which affects the anion-binding capacity of the coenzyme-binding site.     

The enthalpy of protolysis of liver alcohol dehydrogenase upon binding nicotinamide adenine dinucleotide.

The binding of NAD+, NADH, and ADP-ribose to horse liver alcohol dehydrogenase has been studied calorimetrically as a function of pH at 25 degrees C. The enthalpy of NADH binding is 0 +/- 0.5 kcal mol-1 in the pH range 6 to 8.6. The enthalpy of NAD+ binding, however, varies with pH in a sigmoidal fashion and is -4.0 kcal mol(NAD)-1 at pH 6.0 and +4.5 kcal mol(NAD)-1 at pH 8.6 with an apparent pKa of 7.6 +/- 0.2. The enthalpy of proton ionization of the group on the enzyme is calculated to be in the range 8.8 to 9.8 kcal mol(H+)-1. In conjunction with the available thermodynamic data on the ionization of zinc-bound water in model compounds, it is concluded that the group with a pKa of 9.8 in the free enzyme and 7.6 in the enzyme . NAD+ binary complex is, most likely, the zinc-bound water molecule. Our studies with zinc-free enzyme provide further evidence for this conclusion. Therefore, the processes involving a conformational change of the enzyme upon NAD+ binding and the suggested mechanism of subsequent quenching of the fluorescence of Trp-314 implicating the participation of an ionized tyrosine group must be re-evaluated in the light of this thermodynamic study.     

Synergism between coenzyme and alcohol binding to liver alcohol dehydrogenase

Heterotropic cooperativity effects in the binding of alcohols and NAD+ or NADH to liver alcohol dehydrogenase have been examined by equilibrium measurements and stopped-flow kinetic studies. Equilibrium data are reported for benzyl alcohol, 2-chloroethanol, 2,2-dichloroethanol, and trifluoroethanol binding to free enzyme over the pH range 6-10. Binary-complex formation between enzyme and alcohols leads to inner-sphere coordination of the alcohol to catalytic zinc and shows a pH dependence reflecting the ionization states of zinc-bound water and the zinc-bound alcohol. The affinity of the binding protonation state of the enzyme for unionized alcohols increases approximately by a factor of 10 on complex formation between enzyme and NAD+ or NADH. The rate and kinetic cooperativity with coenzyme binding of the alcohol association step indicates that enzyme-bound alcohols participate in hydrogen bonding interactions which affect the rates of alcohol and coenzyme equilibration with the enzyme without providing any pronounced contribution to the net energetics of alcohol binding. The pKa values determined for alcohol deprotonation at the binary-complex level are linearly dependent on those of the free alcohols, and can be readily reconciled with the pKa values attributed to ionization of zinc-bound water. Alcohol coordination to catalytic zinc provides a major contribution to the pKa shift which ensures that the substrate is bound predominantly as an alcoholate ion in the catalytically productive ternary complex at physiological pH. The additional pKa shift contributed by NAD+ binding is less pronounced, but may be of particular mechanistic interest since it increases the acidity of zinc-bound alcohols relatively to that of zinc-bound water.     

Coenzyme binding in alcohol dehydrogenase

Crystallographic investigations of horse liver alcohol dehydrogenase have demonstrated that NAD is not a passive participant in the redox reactions catalysed by the enzyme. On the molecular level NAD acts as an activator which induces an active form of the enzyme. This is mediated by a large conformational change, making the active site dehydrated and by providing one part of the substrate-binding cleft. The catalytic events, substrate binding, inhibitor binding and the role of the catalytic zinc ion are discussed in relation to the role of NAD. Human alcohol dehydrogenase isoenzymes which have very different substrate specificities are discussed in relation to sequence differences.     

pH-dependent conformational states of horse liver alcohol dehydrogenase.

The quenching of liver alcohol dehydrogenase protein fluorescence at alkaline pH indicates two conformational states of the enzyme with a pKa of 9.8+/-0.2, shifted to 10.6+/-0.2 in D2O. NAD+ and 2-p-toluidinonaphthalene-6-sulfonate, a fluorescent probe competitive with coenzyme, bind to the acid conformation of the enzyme. The pKa of the protein-fluorescence quenching curve is shifted toward 7.6 in the presence of NAD+, and the ternary complex formation with NAD+ and trifluoroethanol results in a pH-independent maximal quench. At pH (pD) 10.5, the rate constant for NAD+ binding was 2.6 times faster in D2O2 than in H2O due to the shift of the pKa. Based on these results, a scheme has been proposed in which the state of protonation of an enzyme functional group with a pKa of 9.8 controls the conformational state of the enzyme. NAD+ binds to the acid conformation and subsequently causes another conformational change resulting in the perturbation of the pKa to 7.6. Alcohol then binds to the unprotonated form of the functional group with a pKa of 7.6 in the binary enzyme-NAD+ complex and converts the enzyme to the alkaline conformation. Thus, at neutral pH liver alcohol dehydrogenase undergoes two conformational changes en route to the ternary complex in which hydride transfer occurs.     

Molecular mechanics calculation of geometries of NAD+ derivatives, modified in the nicotinamide group, in a ternary complex with horse liver alcohol dehydrogenase

The geometry of seven NAD+ analogues bound to horse liver alcohol dehydrogenase (LADH) modified only in their nicotinamide group, have been studied using AMBER molecular mechanics energy-minimization procedures. Starting geometries were taken from X-ray crystallographic data for NAD+/Me2SO/LADH reported by Eklund and co-workers. In this study the NAD+ analogues were encaged by the constituent amino acids of the enzyme within a range of 0.6 nm from the initial NAD+/Me2SO/Zn2+ complex. The calculational method used is able to rationalize individual substituent effects and to evaluate the essential interactions between NAD+ analogue, enzyme, Me2SO and Zn2+ without the necessity of additional X-ray data. The results presented here demonstrate that the reactivity of NAD+ derivatives as reported in literature can be qualitatively related to the position of the pyridine moiety in the active site.     

The pH variation of steady-state kinetic parameters of site-specific Co(2+)-reconstituted liver alcohol dehydrogenase. A mechanistic probe for the assignment of metal-linked ionizations

To identify ionizations of the active site metal-bound water in horse liver alcohol dehydrogenase (alcohol:NAD+ oxidoreductase; EC 1.1.1.1), the pH, solvent isotope, temperature, and anion dependences of the steady-state kinetic parameters kcat and kcat/KM have been evaluated under initial velocity conditions for the native and the active site-specific Co(2+)-reconstituted enzyme. In the oxidation of benzyl alcohol, a bell-shaped pattern of four prototropic equilibria was observed under conditions of saturating concentrations of NAD+. It is shown that the ionizations governing kcat (pK1 congruent to 6.7, pK2 congruent to 10.6) belong to the ternary enzyme-NAD(+)-alcohol complex, whereas the ionizations governing kcat/KM (pK1' congruent to 7.5, pK2' congruent to 8.9) belong to the binary enzyme-NAD+ complex. The ionizations pK1 and pK1' are not influenced by metal substitution and are ascribed to His-51 on the basis of experimental estimates of their associated enthalpies of ionization. On the other hand, pK2 and pK2' are significantly decreased (delta pKa congruent to 1.0) in the Co(2+)-enzyme and are attributed to the active site metal-bound water molecule. The shape of the pH profiles requires that the metal ion coordinates a neutral water molecule in the ternary enzyme-NAD(+)-alcohol complex under physiological conditions. The possible catalytic role of the water molecule within a pentacoordinate metal ion complex in the active site is discussed.     

Active site specific cadmium(II)-substituted horse liver alcohol dehydrogenase: crystal structures of the free enzyme, its binary complex with NADH, and the ternary complex with NADH and bound p-bromobenzyl alcohol

Three crystal structures have been determined of active site specific substituted Cd(II) horse liver alcohol dehydrogenase and its complexes. Intensities were collected for the free, orthorhombic enzyme to 2.4-A resolution and for a triclinic binary complex with NADH to 2.7-A resolution. A ternary complex was crystallized from an equilibrium mixture of NAD+ and p-bromobenzyl alcohol. The microspectrophotometric analysis of these single crystals showed the protein-bound coenzyme to be largely NADH, which proves the complex to consist of CdII-LADH, NADH, and p-bromobenzyl alcohol. Intensity data for this abortive ternary complex were collected to 2.9-A resolution. The coordination geometry in the free Cd(II)-substituted enzyme is highly similar to that of the native enzyme. Cd(II) is bound to Cys-46, Cys-174, His-67, and a water molecule in a distorted tetrahedral geometry. Binding of coenzymes induces a conformational change similar to that in the native enzyme. The interactions between the coenzyme and the protein in the binary and ternary complexes are highly similar to those in the native ternary complexes. The substrate binds directly to the cadmium ion in a distorted tetrahedral geometry. No large, significant structural changes compared to the native ternary complex with coenzyme and p-bromobenzyl alcohol were found. The implications of these results for the use of active site specific Cd(II)-substituted horse liver alcohol dehydrogenase as a model system for the native enzyme are discussed.     

Temperature-dependent structure of the E x S complex of Bacillus stearothermophilus alcohol dehydrogenase

The catalytic chemistry of the thermophilic Bacillus stearothermophilus alcohol dehydrogenase (HtADH) closely resembles that of mesophilic horse liver alcohol dehydrogenase (HLADH). Molecular dynamics (MD) simulations of the htADH x NAD+ x EtO- complex at 298, 323, and 348 K show that the structure of the ligated Zn2+...EtO- complex varies slightly with change in temperature. The MD-created Boltzmann distribution of htADH x NAD+ x EtO- structures establishes the formation of multiple states which increase in number with a decrease in temperature. The motions of the cofactor domain are highly correlated with the motions of NAD+ at the optimal growth temperature (348 K), with NAD+ being pushed toward the substrate by Val260. With a decrease in temperature, the motion together of the cofactor and substrate is reversed, and at 298 K, the nicotinamide ring of the cofactor moves away from the substrate. Both the distance between and the angle of approach of C4 of NAD+ and HD of EtO- become distorted from those of the reactive conformation. The percentages of ground state present as the reactive conformation at different temperatures are approximately correlated with the kcat for the htADH enzymatic reaction. The rate constant for the htADH x NAD+ x EtOH --> htADH x NAD+ x EtO- proton dissociation, which is mediated by Thr40-OH, becomes slower at lower temperatures. The time-dependent distance between EtO- and Thr40-OH reveals that the Thr40 hydroxyl group sways between the substrate and NAD+ ribose 2'-hydroxyl group at the optimal enzyme growth temperature, and this movement is effectively frozen out as the temperature decreases. The temperature dependence of active site conformations is due to the change in both long-range and short-range motions of the E x S complex.     

Active site-specific reconstituted copper(II) horse liver alcohol dehydrogenase: a biological model for type 1 Cu2+ and its changes upon ligand binding and conformational transitions

Insertion of Cu2+ ions into horse liver alcohol dehydrogenase depleted of its catalytic Zn2+ ions creates an artificial blue copper center similar to that of plastocyanin and similar copper proteins. The esr spectrum of a frozen solution and the optical spectra at 296 and 77 K are reported, together with the corresponding data for binary and ternary complexes with NAD+ and pyrazole. The binary complex of the cupric enzyme with pyrazole establishes a novel type of copper proteins having the optical characteristics of Type 1 and the esr parameters of Type 2 Cu2+. Ternary complex formation with NAD+ converts the Cu2+ ion to a Type 1 center. By an intramolecular redox reaction the cuprous enzyme is formed from the cupric enzyme. Whereas the activity of the cupric alcohol dehydrogenase is difficult to assess (0.5%-1% that of the native enzyme), the cuprous enzyme is distinctly active (8% of the native enzyme). The implications of these findings are discussed in view of the coordination of the metal in native copper proteins.     

Mechanism of action of Drosophila melanogaster alcohol dehydrogenase.

Reported kinetic pH dependence data for alcohol dehydrogenase from Drosophila melanogaster are analyzed with regard to differences in rate behaviour between this non-metallo enzyme and the zinc-containing liver alcohol dehydrogenase present in vertebrates. For the Drosophila enzyme a mechanism of action is proposed according to which catalytic proton release to solution during alcohol oxidation occurs at the binary-complex level as an obligatory step preceding substrate binding. Such proton release involves an ionizing group with a pKa of about 7.6 in the enzyme.NAD+ complex, tentatively identified as a tyrosyl residue. The ionized form of this group is proposed to participate in the binding of alcohol substrates and to act as a nucleophilic catalyst of the subsequent step of hydride ion transfer from the bound alcohol to NAD+. Herein lie fundamental mechanistic differences between the metallo and non-metallo short chain alcohol dehydrogenases.     

Reaction of 4-trans-(N,N-dimethylamino)cinnamaldehyde with the liver alcohol dehydrogenase-oxidized nicotinamide adenine dinucleotide complex

Evidence that horse liver alcohol dehydrogenase forms a ternary complex with 4-trans-(N,N-dimethylamino)cinnamaldehyde (DACA) and oxidized nicotinamide adenine dinucleotide (NAD+) is presented. Formation of the complex is characterized by a 97-nm red shift of the free chromophore to 495 nm (epsilon 495 approximately 6.0 X 10(4) M-1 cm-1). This shift is larger than the 66-nm red shift of the E(NADH,-DACA) complex (lambda max = 464 nm) previously reported by Dunn and Hutchinson [Dunn, M.F., & Hutchison, J.S. (1973) Biochemistry 12, 4882-4892]. The large red shift of the E(NAD+,DACA) complex is due to the combined effects of coordination of the carbonyl oxygen of DACA to the active-site zinc ion and to the close proximity of the positively charged nicotinamide ring of NAD+. The stability of this complex is pH dependent and depends on a single apparent ionization with pKa = 7.6 +/- 0.3. The pH-independent dissociation constant for binding of DACA to E(NAD+) is 23 +/- 6 microM. The stoichiometry of DACA binding to the E(NAD+) complex is shown to be one per active site (two per enzyme molecule). Liver alcohol dehydrogenase is also shown to catalyze the NAD+-mediated oxidation of DACA to the corresponding carboxylic acid with a very slow turnover rate. The possibility that the observed E(NAD+,DACA) complex is an intermediate in the enzyme-catalyzed oxidation of DACA is discussed.     

Substitution of arginine for histidine-47 in the coenzyme binding site of yeast alcohol dehydrogenase I

Molecular modeling of alcohol dehydrogenase suggests that His-47 in the yeast enzyme (His-44 in the protein sequence, corresponding to Arg-47 in the horse liver enzyme) binds the pyrophosphate of the NAD coenzyme. His-47 in the Saccharomyces cerevisiae isoenzyme I was substituted with an arginine by a directed mutation. Steady-state kinetic results at pH 7.3 and 30 degrees C of the mutant and wild-type enzymes were consistent with an ordered Bi-Bi mechanism. The substitution decreased dissociation constants by 4-fold for NAD+ and 2-fold for NADH while turnover numbers were decreased by 4-fold for ethanol oxidation and 6-fold for acetaldehyde reduction. The magnitudes of these effects are smaller than those found for the same mutation in the human liver beta enzyme, suggesting that other amino acid residues in the active site modulate the effects of the substitution. The pH dependencies of dissociation constants and other kinetic constants were similar in the two yeast enzymes. Thus, it appears that His-47 is not solely responsible for a pK value near 7 that controls activity and coenzyme binding rates in the wild-type enzyme. The small substrate deuterium isotope effect above pH 7 and the single exponential phase of NADH production during the transient oxidation of ethanol by the Arg-47 enzyme suggest that the mutation makes an isomerization of the enzyme-NAD+ complex limiting for turnover with ethanol.     

Covalent fixation of NAD+ to dehydrogenases and properties of the modified enzymes

Starting from 6-chloropurine riboside and NAD+, different reactive analogues of NAD+ have been obtained by introducing diazoniumaryl or aromatic imidoester groups via flexible spacers into the nonfunctional adenine moiety of the coenzyme. The analogues react with different amino-acid residues of dehydrogenases and form stable amidine or azobridges, respectively. After the formation of a ternary complex by the coenzyme, the enzyme and a pseudosubstrate, the reactive spacer is anchored in the vicinity of the active site. Thus, the coenzyme remains covalently attached to the protein even after decomposition of the complex. On addition of substrates the covalently bound coenzyme is converted to the dihydro-form. In enzymatic tests the modified dehydrogenases show 80-90% of the specific activity of the native enzymes, but they need remarkably higher concentrations of free NAD+ to achieve these values. The dihydro-coenzymes can be reoxidized by oxidizing agents like phenazine methosulfate or by a second enzyme system. Various systems for coenzyme regeneration were investigated; the modified enzymes were lactate dehydrogenase from pig heart and alcohol dehydrogenase from horse liver; the auxiliary enzymes were alcohol dehydrogenase from yeast and liver, lactate dehydrogenase from pig heart, glutamate dehydrogenase and alanine dehydrogenase. Lactate dehydrogenase from heart muscle is inhibited by pyruvate. With alanine dehydrogenase as the auxiliary enzyme, the coenzyme is regenerated and the reaction product, pyruvate, is removed. This system succeeds to convert lactate quantitatively to L-alanine. The thermostability of the binary enzyme systems indicates an interaction of covalently bound coenzymes with both dehydrogenases; both binding sites seem to compete for the coenzyme. The comparison of dehydrogenases with different degrees of modifications shows that product formation mainly depends on the amount of incorporated coenzyme.     

Parallelism between ethanol and imidazole interactions with horse liver alcohol dehydrogenase

The rate effects of imidazole on the EE isoenzyme of horse liver alcohol dehydrogenase have been analysed in terms of the elucidated kinetic mechanism of the enzyme. These imidazole effects on both directions of the reaction within nonexcess as well as excess ranges of substrate concentrations pointed to the competition between imidazole and ethanol for binding to the same three enzyme species in the kinetic mechanism, namely the free enzyme, the enzyme-NAD+ complex, and the enzyme-NADH complex. Moreover, both imidazole and ethanol brought about an enhancement in the rate of dissociation of NAD+ from its binding site on the enzyme.     

Modelling studies on the binding of substrate and inhibitor to the active site of human sorbitol dehydrogenase

This study reports a molecular modelling investigation of human sorbitol dehydrogenase complexed with the substrate sorbitol and the inhibitor WAY135 706 based on the structures of human beta3 alcohol dehydrogenase, human sigma alcohol dehydrogenase and horse liver alcohol dehydrogenase. The tertiary structure of human beta3 alcohol dehydrogenase was used as a template for the construction of the model. The rms positional deviation between the main-chain atoms of the initial and final models of sorbitol dehydrogenase is 1.37 A. Similar residue interactions exist between sorbitol dehydrogenase and both sorbitol and inhibitor. Binding of sorbitol in the substrate-binding site results in interactions with Lys-294, Tyr-50, His-69, Glu-150, and NAD+ while WAY135 706 interacts with Ser-46, Lys-294 and Phe-59. The enzyme-inhibitor interactions revealed by this study will be useful in the design of more specific inhibitors.     

Active-site cobalt(II)-substituted horse liver alcohol dehydrogenase: characterization of intermediates in the oxidation and reduction processes as a function of pH

Substitution of Co(II) for the catalytic site Zn(II) of horse liver alcohol dehydrogenase (LADH) yields an active enzyme derivative, CoIIE, with characteristic Co(II) charge-transfer and d-d electronic transitions that are sensitive to the events which take place during catalysis [Koerber, S. C., MacGibbon, A. K. H., Dietrich, H., Zeppezauer, M., & Dunn, M. F. (1983) Biochemistry 22, 3424-3431]. In this study, UV-visible spectroscopy and rapid-scanning stopped-flow (RSSF) kinetic methods are used to detect and identify intermediates in the LADH catalytic mechanism. In the presence of the inhibitor isobutyramide, the pre-steady-state phase of alcohol (RCH2OH) oxidation at pH above 7 is characterized by the formation and decay of an intermediate with lambda max = 570, 640, and 672 nm for both aromatic and aliphatic alcohols (benzyl alcohol, p-nitrobenzyl alcohol, anisyl alcohol, ethanol, and methanol). By comparison with the spectrum of the stable ternary complex formed with oxidized nicotinamide adenine dinucleotide (NAD+) and 2,2',2'-trifluoroethoxide ion (TFE-), CoIIE(NAD+, TFE-), the intermediate which forms is proposed to be the alkoxide ion (RCH2O-) complex, CoIIE(NAD+, RCH2O-). The timing of reduced nicotinamide adenine dinucleotide (NADH) formation indicates that intermediate decay is limited by the interconversion of ternary complexes, i.e., CoIIE(NAD+, RCH2O-) in equilibrium CoIIE(NADH, RCHO). From competition experiments, we infer that, at pH values below 5, NAD+ and alcohol form a CoIIE(NAD+, RCH2OH) ternary complex. RSSF studies carried out as a function of pH indicate that the apparent pKa values for the ionization of alcohol within the ternary complex, i.e., CoIIE(NAD+, RCH2OH) in equilibrium CoIIE(NAD+, RCH2O-) + H+, fall in the range 5-7.5. Using pyrazole as the dead-end inhibitor, we find that the single-turnover time courses for the reduction of benzaldehyde, p-nitrobenzaldehyde, anisaldehyde, and acetaldehyde at pH above 7 all show evidence for the formation and decay of an intermediate. Via spectral comparisons with CoIIE-(NAD+, TFE-) and with the intermediate formed during alcohol oxidation, we identify the intermediate as the same CoIIE(NAD+, RCH2O-) ternary complex detected during alcohol oxidation.