Heme-bound nitroxyl, hydroxylamine, and ammonia ligands as intermediates in the reaction cycle of cytochrome c nitrite reductase: a theoretical study

In this article, we consider, in detail, the second half-cycle of the six-electron nitrite reduction mechanism catalyzed by cytochrome c nitrite reductase. In total, three electrons and four protons must be provided to reach the final product, ammonia, starting from the HNO intermediate. According to our results, the first event in this half-cycle is the reduction of the HNO intermediate, which is accomplished by two PCET reactions. Two isomeric radical intermediates, HNOH^? and H₂NO^?, are formed. Both intermediates are readily transformed into hydroxylamine, most likely through intramolecular proton transfer from either Arg₁₁₄ or His₂₇₇. An extra proton must enter the active site of the enzyme to initiate heterolytic cleavage of the N–O bond. As a result of N–O bond cleavage, the H₂N⁺ intermediate is formed. The latter readily picks up an electron, forming H₂N^+?, which in turn reacts with Tyr₂₁₈. Interestingly, evidence for Tyr₂₁₈ activity was provided by the mutational studies of Lukat (Biochemistry 47:2080, 2008), but this has never been observed in the initial stages of the overall reduction process. According to our results, an intramolecular reaction with Tyr₂₁₈ in the final step of the nitrite reduction process leads directly to the final product, ammonia. Dissociation of the final product proceeds concomitantly with a change in spin state, which was also observed in the resonance Raman investigations of Martins et al. (J Phys Chem B 114:5563, 2010).     

A needle in a haystack: the active site of the membrane-bound complex cytochrome c nitrite reductase

Cytochrome c nitrite reductase is a multicenter enzyme that uses a five-coordinated heme to perform the six-electron reduction of nitrite to ammonium. In the sulfate reducing bacterium Desulfovibrio desulfuricans ATCC 27774, the enzyme is purified as a NrfA2NrfH complex that houses 14 hemes. The number of closely-spaced hemes in this enzyme and the magnetic interactions between them make it very difficult to study the active site by using traditional spectroscopic approaches such as EPR or UV-Vis. Here, we use both catalytic and non-catalytic protein film voltammetry to simply and unambiguously determine the reduction potential of the catalytic heme over a wide range of pH and we demonstrate that proton transfer is coupled to electron transfer at the active site.     

Effect of pH on the Steady State Kinetics of Bovine Heart NADH: Coenzyme Q Oxidoreductase

Complete initial steady state kinetics of NADH-decylubiquinone (DQ) oxidoreductase reaction between pH 6.5 and 9.0 show an ordered sequential mechanism in which the order of substrate bindings and product releases is NADH-DQ–DQH₂-NAD⁺. NADH binding to the free enzyme is accelerated by protonation of an amino acid (possibly a histidine) residue. The NADH release is negligibly slow under the turnover conditions. The rate of DQ binding to the NADH-bound enzyme and the maximal rate at the saturating concentrations of the two substrates, which is determined by the rates of DQH₂ formation in the active site and releases of DQH₂ and NAD⁺ from the enzyme, are insensitive to pH, in contrast to clear pH dependencies of the maximal rates of cytochrome c oxidase and cytochrome bc ₁ complex. Physiological significances of these results are discussed.     

Dynamical study,hydrogen bond analysis,and constant pH simulations of the beta carbonic anhydrase of Methanobacterium thermoautotrophicum

Within the five classes (α, β, γ, δ, and ζ) of carbonic anhydrases (CAs) the first two, containing mammal and plant representatives, are the most studied among all CAs. In this study, we have focused our investigation on the beta-class carbonic anhydrase of Methanobacterium thermoautotrophicum. We investigated both the importance of the Asp-Arg dyad near the catalytic zinc-bound water and the possible roles that water molecules within the active site and residues near the entrance of the catalytic cleft have on the first step of the enzyme’s reaction mechanism. Hydrogen-bonding analysis of selected residues within the active site and constant pH replica exchange molecular dynamics constant pH replica exchange simulations were performed. The latter was done in order to evaluate the pK_a values of possible proton acceptors. We found an intricate hydrogen-bonding network involving two acidic residues within the active site, Asp16 and Asp34, and the catalytic water molecule. We also observed a very strong interaction between the zinc-bound water and residues Asp34 and Arg36. This interaction was not significantly affected by the change in the protonation state of both the catalytic water and aspartate residue 34. The pK_a analysis show that the effect of the R36A mutation affects not only the possible proton acceptors, but also the catalytic water itself.     

Reductive activation of the heme iron–nitrosyl intermediate in the reaction mechanism of cytochrome c nitrite reductase: a theoretical study

Cytochrome c nitrite reductase catalyzes the six-electron, seven-proton reduction of nitrite to ammonia without release of any detectable reaction intermediate. This implies a unique flexibility of the active site combined with a finely tuned proton and electron delivery system. In the present work, we employed density functional theory to study the recharging of the active site with protons and electrons through the series of reaction intermediates based on nitrogen monoxide [Fe(II)-NO(+), Fe(II)-NO·, Fe(II)-NO(-), and Fe(II)-HNO]. The activation barriers for the various proton and electron transfer steps were estimated in the framework of Marcus theory. Using the barriers obtained, we simulated the kinetics of the reduction process. We found that the complex recharging process can be accomplished in two possible ways: either through two consecutive proton-coupled electron transfers (PCETs) or in the form of three consecutive elementary steps involving reduction, PCET, and protonation. Kinetic simulations revealed the recharging through two PCETs to be a means of overcoming the predicted deep energetic minimum that is calculated to occur at the stage of the Fe(II)-NO· intermediate. The radical transfer role for the active-site Tyr(218), as proposed in the literature, cannot be confirmed on the basis of our calculations. The role of the highly conserved calcium located in the direct proximity of the active site in proton delivery has also been studied. It was found to play an important role in the substrate conversion through the facilitation of the proton transfer steps.     

Peroxidase activity of octaheme nitrite reductases from bacteria of the <Emphasis Type="Italic">Thioalkalivibrio</Emphasis> genus

Closely related penta- and octaheme nitrite reductases catalyze the reduction of nitrite, nitric oxide, and hydroxylamine to ammonium and of sulfite to sulfide. NrfA pentaheme nitrite reductase plays the key role in anaerobic nitrate respiration and the protection of bacterial cells from stresses caused by nitrogen oxides and hydrogen peroxide. Octaheme nitrite reductases from bacteria of the Thioalkalivibrio genus are less studied, and their function in the cell is unknown. In order to estimate the possible role of octaheme nitrite reductases in the cell resistance to oxidative stress, the peroxidase activity of the enzyme from T. nitratireducens (TvNiR) has been studied in detail. Comparative analysis of the active site structure of TvNiR and cytochrome c peroxidases has shown some common features, such as a five-coordinated catalytic heme and identical catalytic residues in active sites. A model of the possible productive binding of peroxide at the active site of TvNiR has been proposed. The peroxidase activity has been measured for TvNiR hexamers and trimers under different conditions (pH, buffers, the addition of CaCl₂ and EDTA). The maximum peroxidase activity of TvNiR with ABTS as a substrate (k _cat = 17 s^–1; k _cat/K _m = 855 mM^–1 s^–1) has been 100–300 times lower than the activity of natural peroxidases. The different activities of TvNiR trimers and hexamers indicate that the rate-limiting stage of the reaction is not the catalytic event at the active site but the electron transfer along the heme c electron-transport chain.     

Laser-flash photolysis indicates that internal electron transfer is triggered by proton uptake by Alcaligenes xylosoxidans copper-dependent nitrite reductase

Enzyme-catalysed electron transfer reactions are often controlled by protein motions and coupled to chemical change such as proton transfer. We have investigated the nature of this control in the blue copper-dependent nitrite reductase from Alcaligenes xylosoxidans (AxNiR). Inter-Cu electron transfer from the T1Cu site to the T2Cu catalytic site in AxNiR occurs via a proton-coupled electron transfer mechanism. Here we have studied the kinetics of both electron and proton transfer independently using laser-flash photolysis for native AxNiR and its proton-channel mutant N90S. In native AxNiR, both inter-Cu electron transfer and proton transfer exhibit similar rates, and show an unusual dependence on the nitrite concentration. An initial decrease in the observed rates at low nitrite concentrations is followed by an increase in the observed rates at high nitrite concentrations (> 5 mm). In N90S, in which the T1Cu reduction potential is elevated by 60 mV, no inter-Cu electron transfer or proton transfer was observed in the absence of nitrite. Only in the presence of nitrite were both processes detected, with similar [nitrite] dependence, but the nitrite dependence was different compared with native enzyme. The substrate dependence in N90S was similar to that observed in steady-state assays, suggesting that this substitution resulted in proton-coupled electron transfer becoming rate-limiting. A pH perturbation experiment with native AxNiR revealed that protonation triggers inter-Cu electron transfer and generation of NO. Our results show a strong coupling of inter-Cu electron transfer and proton transfer for both native AxNiR and N90S, and provide novel insights into the controlled delivery of electrons and protons to the substrate-utilization T2Cu active site of AxNiR.     

Mechanism of O-acetylserine sulfhydrylase fromSalmonella typhimurium LT-2

Summary O-Acetylserine sulfhydrylase is a pyridoxal 5-phosphate (PLP) dependent enzyme that catalyzes the final step of L-cysteine biosynthesis inSalmonella, viz. the conversion of O-acetyl-L-serine (OAS) and sulfide to L-cysteine and acetate. A spectrophotometric assay is available using 5-thio(2-nitrobenzoate) (TNB) as an analog of sulfide and monitoring the disappearance of absorbance at 412 nm. The enzyme catalyzes a ping pong mechanism with-aminoacrylate in Schiff base with the active site PLP as a covalent intermediate. Using data obtained from the pH dependence of kinetic parameters, the acid-base chemical mechanism and the optimum protonation state of enzyme and substrate functional groups necessary for binding has been determined. The Schiff base and the-amine of the substrate OAS are unprotonated for binding. There also appears to be a requirement for one active site general base to accept a proton from the-amine and to donate a proton to form cysteine. The enzyme also catalyzes an OAS hydrolase activity, and the pH dependence of this reaction suggests that the active site lysine that participated in the Schiff base linkage is protonated to start the second half reaction, and has a pK of about 8.2. The stereochemistry of³H-borohydride reduction of the Schiff base in free enzyme has been determined by degradation of the resulting pyridoxyllysine to pyridoxamine and measuring³H-release with apo-aspartate aminotransferase. The sequence around the active site lysine is AsnProSerPheSerValLysCysArg.     

Unexpected dependence on pH of NO release from Paracoccus pantotrophus cytochrome cd1

A previous study of nitrite reduction by Paracoccus pantotrophus cytochrome cd₁ at pH 7.0 identified early reaction intermediates. The c-heme rapidly oxidised and nitrite was reduced to NO at the d₁-heme. A slower equilibration of electrons followed, forming a stable complex assigned as 55% cFe(III)d₁Fe(II)-NO and 45% cFe(II)d₁Fe(II)-NO⁺. No catalytically competent NO release was observed. Here we show that at pH 6.0, a significant proportion of the enzyme undergoes turnover and releases NO. An early intermediate, which was previously overlooked, is also identified; enzyme immediately following product release is a candidate. However, even at pH 6.0 a considerable fraction of the enzyme remains bound to NO so another component is required for full product release. The kinetically stable product formed at the end of the reaction differs significantly at pH 6.0 and 7.0, as does its rate of formation; thus the reaction is critically dependent on pH.     

Mechanisms for enzymatic reduction of nitric oxide to nitrous oxide - A comparison between nitric oxide reductase and cytochrome c oxidase

Cytochrome c oxidases (CcO) reduce O₂ to H₂O in the respiratory chain of mitochondria and many aerobic bacteria. In addition, some species of CcO can also reduce NO to N₂O and water while others cannot. Here, the mechanism for NO-reduction in CcO is investigated using quantum mechanical calculations. Comparison is made to the corresponding reaction in a “true” cytochrome c-dependent NO reductase (cNOR). The calculations show that in cNOR, where the reduction potentials are low, the toxic NO molecules are rapidly reduced, while the higher reduction potentials in CcO lead to a slower or even impossible reaction, consistent with experimental observations. In both enzymes the reaction is initiated by addition of two NO molecules to the reduced active site, forming a hyponitrite intermediate. In cNOR, N₂O can then be formed using only the active-site electrons. In contrast, in CcO, one proton-coupled reduction step most likely has to occur before N₂O can be formed, and furthermore, proton transfer is most likely rate-limiting. This can explain why different CcO species with the same heme a₃-Cu active site differ with respect to NO reduction efficiency, since they have a varying number and/or properties of proton channels. Finally, the calculations also indicate that a conserved active site valine plays a role in reducing the rate of NO reduction in CcO.     

Redox-linked protonation state changes in cytochrome bc1 identified by Poisson-Boltzmann electrostatics calculations

Cytochrome bc₁ is a major component of biological energy conversion that exploits an energetically favourable redox reaction to generate a transmembrane proton gradient. Since the mechanistic details of the coupling of redox and protonation reactions in the active sites are largely unresolved, we have identified residues that undergo redox-linked protonation state changes. Structure-based Poisson-Boltzmann/Monte Carlo titration calculations have been performed for completely reduced and completely oxidised cytochrome bc₁. Different crystallographically observed conformations of Glu272 and surrounding residues of the cytochrome b subunit in cytochrome bc₁ from Saccharomyces cerevisiae have been considered in the calculations. Coenzyme Q (CoQ) has been modelled into the CoQ oxidation site (Q_o-site). Our results indicate that both conformational and protonation state changes of Glu272 of cytochrome b may contribute to the postulated gating of CoQ oxidation. The Rieske iron-sulphur cluster could be shown to undergo redox-linked protonation state changes of its histidine ligands in the structural context of the CoQ-bound Q_o-site. The proton acceptor role of the CoQ ligands in the CoQ reduction site (Q_i-site) is supported by our results. A modified path for proton uptake towards the Q_i-site features a cluster of conserved lysine residues in the cytochrome b (Lys228) and cytochrome c₁ subunits (Lys288, Lys289, Lys296). The cardiolipin molecule bound close to the Q_i-site stabilises protons in this cluster of lysine residues.     

Cytochrome oxidase: pathways for electron tunneling and proton transfer

 Electrons from cytochrome c, the substrate of cytochrome oxidase, a redox-linked proton pump, are accepted by Cu_A in subunit II. From there they are transferred to the proton pumping machinery in subunit I, cytochrome a and cytochrome a ₃–Cu_B. The reduction of the latter site, which is the dioxygen reducing unit, is coupled to proton uptake. Dioxygen reduction involves a peroxide and a ferryl ion intermediate, and it is the transition between these and back to the resting oxidized enzyme that are coupled to proton pumping. The X-ray structures suggest electron–transfer pathways that can account for the observed rates provided that the reorganization energies are small. They also reveal two proton-transfer pathways, and mutagenesis experiments have shown that one is used for proton uptake during the initial reduction of cytochrome a ₃–Cu_B, whereas the other mediates transfer of the pumped protons. Received: 23 March 1998 / Accepted: 11 May 1998     

Spectroscopic study on the communication between a heme a3 propionate, Asp399 and the binuclear center of cytochrome c oxidase from Paracoccus denitrificans

The proton pumping mechanism of cytochrome c oxidase on a molecular level is highly disputed. Recently theoretical calculations and real time electron transfer measurements indicated the involvement of residues in the vicinity of the ring A propionate of heme a₃, including Asp399 and the Cu_B ligands His 325, 326. In this study we probed the interaction of Asp399 with the binuclear center and characterize the protonation state of its side chain. Redox induced FTIR difference spectra of mutations at the site in direct comparison to wild type, indicate that below pH 5 Asp 399 displays signals typical for the deprotonation of the acidic residue with reduction of the enzyme. Interestingly at a pH higher than 5, no contributions from Asp 399 are evident. In order to probe the interaction of the site with the binuclear center we followed the rebinding of CO by infrared spectroscopy for mutations on residue Asp399 to Glu, Asn and Leu. Previously different CO conformers have been identified for bacterial cytochrome c oxidases, and its pH dependent behaviour discussed to be relevant for catalysis. Interestingly we observe the lack of this pH dependency and a strong influence on the observable conformers for all mutants studied here, clearly suggesting a communication of the site with the heme-copper center and the nearby histidine residues.     

Protein film voltammetry reveals distinctive fingerprints of nitrite and hydroxylamine reduction by a cytochrome C nitrite reductase

The cytochrome c nitrite reductases perform a key step in the biological nitrogen cycle by catalyzing the six-electron reduction of nitrite to ammonium. Graphite electrodes painted with Escherichia coli cytochrome c nitrite reductase and placed in solutions containing nitrite (pH 7) exhibit large catalytic reduction currents during cyclic voltammetry at potentials below 0 V. These catalytic currents were not observed in the absence of cytochrome c nitrite reductase and were shown to originate from an enzyme film engaged in direct electron exchange with the electrode. The catalytic current-potential profiles observed on progression from substrate-limited to enzyme-limited nitrite reduction revealed a fingerprint of catalytic behavior distinct from that observed during hydroxylamine reduction, the latter being an alternative substrate for the enzyme that is reduced to ammonium in a two electron process. Cytochrome c nitrite reductase clearly interacts differently with these two substrates. However, similar features underlie the development of the voltammetric response with increasing nitrite or hydroxylamine concentration. These features are consistent with coordinated two-electron reduction of the active site and suggest that the mechanisms for reduction of both substrates are underpinned by common rate-defining processes.     

Electron and proton transfer in the <Emphasis Type="Italic">ba</Emphasis><Subscript>3</Subscript> oxidase from <Emphasis Type="Italic">Thermus thermophilus</Emphasis>

The ba ₃-type cytochrome c oxidase from Thermus thermophilus is phylogenetically very distant from the aa ₃–type cytochrome c oxidases. Nevertheless, both types of oxidases have the same number of redox-active metal sites and the reduction of O₂ to water is catalysed at a haem a ₃-Cu_B catalytic site. The three-dimensional structure of the ba ₃ oxidase reveals three possible proton-conducting pathways showing very low homology compared to those of the mitochondrial, Rhodobacter sphaeroides and Paracoccus denitrificans aa ₃ oxidases. In this study we investigated the oxidative part of the catalytic cycle of the ba ₃ -cytochrome c oxidase using the flow-flash method. After flash-induced dissociation of CO from the fully reduced enzyme in the presence of oxygen we observed rapid oxidation of cytochrome b (k ≅ 6.8 × 10⁴ s⁻¹) and formation of the peroxy (P_R) intermediate. In the next step a proton was taken up from solution with a rate constant of ~1.7 × 10⁴ s⁻¹, associated with formation of the ferryl (F) intermediate, simultaneous with transient reduction of haem b. Finally, the enzyme was oxidized with a rate constant of ~1,100 s⁻¹, accompanied by additional proton uptake. The total proton uptake stoichiometry in the oxidative part of the catalytic cycle was ~1.5 protons per enzyme molecule. The results support the earlier proposal that the P_R and F intermediate spectra are similar (Siletsky et al. Biochim Biophys Acta 1767:138, 2007) and show that even though the architecture of the proton-conducting pathways is different in the ba ₃ oxidases, the proton-uptake reactions occur over the same time scales as in the aa ₃-type oxidases. Smirnova and Zaslavsky contributed equally to the work described in this paper.     

Enzyme inhibition by iminosugars: Analysis and insight into the glycosidase–iminosugar dependency of pH

Imino- and azasugar glycosidase inhibitors display pH dependant inhibition reflecting that both the inhibitor and the enzyme active site have groups that change protonation state with pH. With the enzyme having two acidic groups and the inhibitor one basic group, enzyme–inhibitor complexes with three (EH₃I), two (EH₂I), one (EHI), or no protons (EI), are possible. In the present work an analysis method is presented that from pH-inhibition data allows one to distinguish between the different complexes and determine which protonation state is preferred. It is also possible to determine the pH-independent binding constants of the inhibitor. Analysis of pH data for imino- and azasugar inhibition of β-glucosidases revealed that basic glycosidase inhibitors bind as the monoprotonated (EHI) complex. Three neutral inhibitors were also studied and two of these were also bound exclusively as the EHI complex while a third bound both as a EHI and a EH₂I complex.     

Purification of cytochrome a 1 c 1 from Nitrobacter agilis and characterization of nitrite oxidation system of the bacterium

Cytochrome a ₁ c ₁ was highly purified from Nitrobacter agilis. The cytochrome contained heme a and heme c of equimolar amount, and its reduced form showed absorption peaks at 587, 550, 521, 434 and 416 nm. Molecular weight per heme a of the cytochrome was estimated to be approx. 100,000–130,000 from the amino acid composition. A similar value was obtained by determining the protein content per heme a. The cytochrome molecule was composed of three subunits with molecular weights of 55,000, 29,000 and 19,000, respectively. The 29 kd subunit had heme c.Hemes a and c of cytochrome a ₁ c ₁ were reduced on addition of nitrite, and the reduced cytochrome was hardly autoxidizable. Exogenously added horse heart cytochrome c was reduced by nitrite in the presence of cytochrome a ₁ c ₁; K _m values of cytochrome a ₁ c ₁ for nitrite and N. agilis cytochrome c were 0.5 mM and and 6 M, respectively. V _max was 1.7 mol ferricytochrome c reduced/min·mol of cytochrome a ₁ c ₁ The pH optimum of the reaction was about 8. The nitrite-cytochrome c reduction catalyzed by cytochrome a ₁ c ₁ was 61% and 88% inhibited by 44M azide and cyanide, respectively. In the presence of 4.4 mM nitrate, the reaction was 89% inhibited. The nitrite-cytochrome c reduction catalysed by cytochrome a ₁ c ₁ was 2.5-fold stimulated by 4.5 mM manganous chloride. An activating factor which was present in the crude enzyme preparation stimulated the reaction by 2.8-fold, and presence of both the factor and manganous ion activated the reaction by 7-fold.Cytochrome a ₁ c ₁ showed also cytochrome c-nitrate reductase activity. The pH optimum of the reaction was about 6. The nitrate reductase activity was also stimulated by manganous ions and the activating factor.     

The c‐ring ion binding site of the ATP synthase from Bacillus pseudofirmus OF4 is adapted to alkaliphilic lifestyle

In the c‐ring rotor of ATP synthases ions are shuttled across the membrane during ATP synthesis by a unique rotary mechanism. We investigated characteristics of the c‐ring from the alkaliphile Bacillus pseudofirmus OF4 with respect to evolutionary adaptations to operate with protons at high environmental pH. The X‐ray structures of the wild‐type c₁₃ ring at pH 9.0 and a ‘neutralophile‐like’ mutant (P51A) at pH 4.4, at 2.4 and 2.8 Å resolution, respectively, reveal a dependency of the conformation and protonation state of the proton‐binding glutamate (E⁵⁴) on environmental hydrophobicity. Faster labelling kinetics with the inhibitor dicyclohexylcarbodiimide (DCCD) demonstrate a greater flexibility of E⁵⁴ in the mutant due to reduced water occupancy within the H⁺ binding site. A second ‘neutralophile‐like’ mutant (V21N) shows reduced growth at high pH, which is explained by restricted conformational freedom of the mutant's E⁵⁴ carboxylate. The study directly connects subtle structural adaptations of the c‐ring ion binding site to in vivo effects of alkaliphile cell physiology.     

Protonation states of active‐site lysines of penicillin‐binding protein 6 from Escherichia coli and the mechanistic implications

The protonation states of the two active‐site lysines (Lys69 and Lys235) of PBP 6 of Escherichia coli were explored to understand the active site chemistry of this enzyme. Each lysine was individually mutated to cysteine, and the resultant two mutant proteins were purified to homogeneity. Each protein was denatured, and its cysteine was chemically modified to produce an S‐aminoethylated cysteine (γ‐thialysine) residue. Following renaturation, the evaluation of the kinetics of the dd ‐carboxypeptidase activity of PBP 6 as a function of pH was found consistent with one lysine in its free‐base (Lys69) and the other in the protonated state (Lys235) for optimal catalysis. The experimental estimates for their pK_a values were compared with the pK_a values calculated computationally, using molecular‐dynamics simulations and a thermodynamic cycle. Study of the γ‐thialysine69 showed that lysine at position 69 influenced the basic limb of catalysis, consistent with the fact that the two lysine side chains are in proximity to each other in the active site. Based on these observations, a reaction sequence for PBP 6 is proposed, wherein protonated Lys235 serves as the electrostatic substrate anchor and Lys69 as the conduit for protons in the course of the acylation and deacylation half‐reactions. Proteins 2014; 82:1348–1358. © 2013 Wiley Periodicals, Inc.     

Kinetic methods for the study of the enzyme systems of β-oxidation

Kinetic methods for studying the reactions of the “general” fatty acyl CoA dehydrogenase under three sets of substrate and enzyme concentration conditions have been developed. The reaction of butyryl-CoA and electron transfer flavoprotein (ETF) can be studied either under steady-state conditions with enzyme at catalytic concentration or under single-turnover conditions with enzyme in excess. Under the latter conditions, acyl-CoA dehydrogenase acts both as a catalyst and an ultimate electron-transfer acceptor. The reductive half-reaction of butyryl-CoA and enzyme can also be studied in a separate kinetic experiment. Comparison of the pH dependences of the rate constants and isotope effects of the steady-state reaction of butyryl-CoA and ETF with the same parameters for the reductive half-reaction is consistent with a mechanism involving transfer of electrons from butyryl-CoA to ETF within a ternary complex. An alternative mechanism in which the reductive half-reaction takes place prior to the binding and reaction of ETF seems unlikely because the pH 8.5 isotope effect on the reductive half-reaction is much larger than that on the complete reaction in spite of the fact that the rates of the reactions are comparable. The pH dependence of the K_m for substrate and K_I for inhibitor is consistent with a mechanism for transfer of electrons within the ternary complex which involves protonation of the C group of substrates. The protonation labilizes the C-2 proton and base catalysis of the removal of the C-2 proton results in the production of the active enzyme-substrate species, namely the C-2 anion of substrate.