Investigation of the NADH/NAD+ ratio in Ralstonia eutropha using the fluorescence reporter protein Peredox

Ralstonia eutropha is a hydrogen-oxidizing (“Knallgas”) bacterium that can easily switch between heterotrophic and autotrophic metabolism to thrive in aerobic and anaerobic environments. Its versatile metabolism makes R. eutropha an attractive host for biotechnological applications, including H₂-driven production of biodegradable polymers and hydrocarbons. H₂ oxidation by R. eutropha takes place in the presence of O₂ and is mediated by four hydrogenases, which represent ideal model systems for both biohydrogen production and H₂ utilization. The so-called soluble hydrogenase (SH) couples reversibly H₂ oxidation with the reduction of NAD⁺ to NADH and has already been applied successfully in vitro and in vivo for cofactor regeneration. Thus, the interaction of the SH with the cellular NADH/NAD⁺ pool is of major interest. In this work, we applied the fluorescent biosensor Peredox to measure the [NADH]:[NAD⁺] ratio in R. eutropha cells under different metabolic conditions. The results suggest that the sensor operates close to saturation level, indicating a rather high [NADH]:[NAD⁺] ratio in aerobically grown R. eutropha cells. Furthermore, we demonstrate that multicomponent analysis of spectrally-resolved fluorescence lifetime data of the Peredox sensor response to different [NADH]:[NAD⁺] ratios represents a novel and sensitive tool to determine the redox state of cells.     

Involvement of Molecular Oxygen in the Enzyme-Catalyzed NADH Oxidation and Ferric Leghemoglobin Reduction

Ferric leghemoglobin reductase (FLbR) from soybean (Glycine max [L.] Merr) nodules catalyzed oxidation of NADH, reduction of ferric leghemoglobin (Lb⁺³), and reduction of dichloroindophenol (diaphorase activity). None of these reactions was detectable when O₂ was removed from the reaction system, but all were restored upon readdition of O₂. In the absence of exogenous electron carriers and in the presence of O₂ and excess NADH, FLbR catalyzed NADH oxidation with the generation of H₂O₂ functioning as an NADH oxidase. The possible involvement of peroxide-like intermediates in the FLbR-catalyzed reactions was analyzed by measuring the effects of peroxidase and catalase on FLbR activities; both enzymes at low concentrations (about 2 μg/mL) stimulated the FLbR-catalyzed NADH oxidation and Lb⁺³ reduction. The formation of H₂O₂ during the FLbR-catalyzed NADH oxidation was confirmed using a sensitive assay based on the fluorescence emitted by dichlorofluorescin upon reaction with H₂O₂. The stoichiometry ratios between the FLbR-catalyzed NADH oxidation and Lb⁺³ reduction were not constant but changed with time and with concentrations of NADH and O₂ in the reaction solution, indicating that the reactions were not directly coupled and electrons from NADH oxidation were transferred to Lb⁺³ by reaction intermediates. A study of the affinity of FLbR for O₂ showed that the enzyme required at least micromolar levels of dissolved O₂ for optimal activities. A mechanism for the FLbR-catalyzed reactions is proposed by analogy with related oxidoreductase systems.     

Discriminating changes in intracellular NADH/NAD+ levels due to anoxicity and H2 supply in R. eutropha cells using the Frex fluorescence sensor

The hydrogen-oxidizing “Knallgas” bacterium Ralstonia eutropha can thrive in aerobic and anaerobic environments and readily switches between heterotrophic and autotrophic metabolism, making it an attractive host for biotechnological applications including the sustainable H₂-driven production of hydrocarbons. The soluble hydrogenase (SH), one out of four different [NiFe]-hydrogenases in R. eutropha, mediates H₂ oxidation even in the presence of O₂, thus providing an ideal model system for biological hydrogen production and utilization. The SH reversibly couples H₂ oxidation with the reduction of NAD⁺ to NADH, thereby enabling the sustainable regeneration of this biotechnologically important nicotinamide cofactor. Thus, understanding the interaction of the SH with the cellular NADH/NAD⁺ pool is of high interest. Here, we applied the fluorescent biosensor Frex to measure changes in cytoplasmic [NADH] in R. eutropha cells under different gas supply conditions. The results show that Frex is well-suited to distinguish SH-mediated changes in the cytoplasmic redox status from effects of general anaerobiosis of the respiratory chain. Upon H₂ supply, the Frex reporter reveals a robust fluorescence response and allows for monitoring rapid changes in cellular [NADH]. Compared to the Peredox fluorescence reporter, Frex displays a diminished NADH affinity, which prevents the saturation of the sensor under typical bacterial [NADH] levels. Thus, Frex is a valuable reporter for on-line monitoring of the [NADH]/[NAD⁺] redox state in living cells of R. eutropha and other proteobacteria. Based on these results, strategies for a rational optimization of fluorescent NADH sensors are discussed.     

Reactivity of an FAD-dependent oxygenase with free flavins: a new mode of uncoupling in flavoprotein oxygenases.

Conversion of 2-methyl-3-hydroxypyridine-5-carboxylic acid (Cpd I) to α-(N-acetylaminomethylene)succinic acid (Cpd A) is catalyzed by an FAD protein, Cpd I oxygenase (Sparrow, et al., J. Biol. Chem. [1969] $\text{244}$, 2590–2600) according to the equation: Cpd I + O₂ + NADH + H⁺ → Cpd A + NAD⁺. When free FAD, FMN or riboflavin is added to reaction mixtures, oxidation of NADH remains dependent on presence of oxygenase and Cpd I, but is partially uncoupled from the oxygenation of Cpd I. Under these conditions, free reduced flavins appear in solution, as shown by their ability to reduce cytochrome c. These effects are not due to an increased rate of NADH oxidation. Such uncoupling may lead to appearance of artifactual species of activated oxygen or flavin that play no intermediate role in the oxygenase reaction.     

Vanadate-stimulated NADH oxidation in microsomes

Addition of vanadate, stimulated oxidation of NADH by rat liver microsomes. The products were NAD⁺ and H₂O₂. High rates of this reaction were obtained in the presence of phosphate buffer and at low pH values. The yellow-orange colored polymeric form of vanadate appears to be the active species and both ortho- and meta-vanadate gave poor activities even at mM concentrations.The activity as measured by oxygen uptake was inhibited by cyanide, EDTA, mannitol, histidine, ascorbate, noradrenaline, adriamycin, cytochrome c, Mn²⁺, superoxide dismutase, horseradish peroxidase and catalase. Mitochondrial outer membranes possess a similar activity of vanadate-stimulated NADH oxidation. But addition of mitochondria and some of its derivative particles abolished the microsomal activity. In the absence of oxygen, disappearance of NADH measured by decrease in absorbance at 340 nm continued at nearly the same rate since vanadate served as an electron acceptor in the microsomal system. Addition of excess catalase or SOD abolished the oxygen uptake while retaining significant rates of NADH disappearance indicating that the two activities are delinked. A mechanism is proposed wherein oxygen receives the first electron from NAD radical generated by oxidation of NADH by phosphovanadate and the consequent reduced species of vanadate (V^iv) gives the second electron to superoxide to reduce it H₂O₂. This is applicable to all membranes whereas microsomes have the additional capability of reducing vanadate.     

Copper (II) complex-catalyzed oxidation of NADH by hydrogen peroxide

Among various metal ions of physiological interest, Cu²⁺ is uniquely capable of catalyzing the oxidation of NADH by H₂O₂. This oxidation is stimulated about fivefold in the presence of imidazole. A similar activating effect is found for some imidazole derivatives (1-methyl imidazole, 2-methyl imidazole, andN-acetyl-L-histidine). Some other imidazole-containing compounds (L-histidine,L-histidine methyl ester, andL-carnosine), however, inhibit the Cu²⁺-catalyzed peroxidation of NADH. Other chelating agents such as EDTA andL-alanine are also inhibitory. Stoichiometry for NADH oxidation per mole of H₂O₂ utilized is 1, which excludes the possibility of a two-step oxidation mechanism with a nucleotide free-radical intermediate. About 92% of the NADH oxidation product can be identified as enzymatically active NAD⁺. D₂O, 2,5-dimethylfuran, and 1,4-diazabicyclo [2.2.2]-octane have no significant effect on the oxidation, thus excluding¹O₂ as a mediator. Similarly, OH· is also not a likely intermediate, since the system is not affected by various scavengers of this radical. The results suggest that a copper-hydrogen peroxide intermediate, when complexed with suitable ligands, can generate still another oxygen species much more reactive than its parent compound, H₂O₂.     

Lignin synthesis: The generation of hydrogen peroxide and superoxide by horseradish peroxidase and its stimulation by manganese (II) and phenols

The enzyme horseradish peroxidase (EC 1.11.1.7) catalyses oxidation of NADH. NADH oxidation is prevented by addition of the enzyme superoxide dismutase (EC 1.15.1.1) to the reaction mixture before adding peroxidase but addition of dismutase after peroxidase has little inhibitory effect. Catalase (EC 1.11.1.6) inhibits peroxidase-catalysed NADH oxidation when added at any time during the reaction. Apparently the peroxidase uses hydrogen peroxide (H₂O₂) generated by non-enzymic breakdown of NADH to catalyse oxidation of NADH to a free-radical, NAD., which reduces oxygen to the superoxide free-radical ion, O₂ ^.-. Some of the O₂ ^.- reacts with peroxidase to give peroxidase compound III, which is catalytically inactive in NADH oxidation. The remaining O₂ ^.- undergoes dismutation to O₂ and H₂O₂. O₂ ^.- does not react with NADH at significant rates. Mn²⁺ or lactate dehydrogenase stimulate NADH oxidation by peroxidase because they mediate a reaction between O₂ ^.- and NADH. 2,4-Dichlorophenol, p-cresol and 4-hydroxycinnamic acid stimulate NADH oxidation by peroxidase, probably by breaking down compound III and so increasing the amount of active peroxidase in the reaction mixture. Oxidation in the presence of these phenols is greatly increased by adding H₂O₂. The rate of NADH oxidation by peroxidase is greatest in the presence of both Mn²⁺ and those phenols which interact with compound III. Both O₂ ^.- and H₂O₂ are involved in this oxidation, which plays an important role in lignin synthesis.     

Oxidation of excited-state NADH and NAD dimer in aqueous medium involvement of O2− as a mediator in the presence of oxygen

It has been shown that direct excitation of NADH (or NADPH) in aqueous medium at 254 nm, or at wavelengths longer than 320 nm (where only the reduced nicotinamide moiety absorbs), leads to generation of NAD⁺ (or NADP⁺). The reaction proceeds both in the presence and absence of oxygen. Under aerobic conditions the reaction is accompanied by formation of H₂O₂ at a level equimolar with that of the NADH present in solution. On irradiation at wavelengths longer than 320 nm, conversion of NADH to enzymatically active NAD⁺ is about 75%. Under analogous irradiation conditions, the dimers (NAD)₂ and (NADP)₂ undergo disproportionation to NAD⁺ and NADP⁺, respectively, to the extent of 90%. Both physicochemical and enzymatic criteria were employed to formulate mechanisms for the photooxidation of NADH and the photodisproportionation of the dimer (NAD)₂.     

Regulation of the Na+/Ca2+ Exchanger by Pyridine Nucleotide Redox Potential in Ventricular Myocytes

The cardiac Na⁺/Ca²⁺ exchanger (NCX) is the major Ca²⁺ efflux pathway on the sarcolemma, counterbalancing Ca²⁺ influx via L-type Ca²⁺ current during excitation-contraction coupling. Altered NCX activity modulates the sarcoplastic reticulum Ca²⁺ load and can contribute to abnormal Ca²⁺ handling and arrhythmias. NADH/NAD⁺ is the main redox couple controlling mitochondrial energy production, glycolysis, and other redox reactions. Here, we tested whether cytosolic NADH/NAD⁺ redox potential regulates NCX activity in adult cardiomyocytes. NCX current (I_NCX), measured with whole cell patch clamp, was inhibited in response to cytosolic NADH loaded directly via pipette or increased by extracellular lactate perfusion, whereas an increase of mitochondrial NADH had no effect. Reactive oxygen species (ROS) accumulation was enhanced by increasing cytosolic NADH, and NADH-induced I_NCX inhibition was abolished by the H₂O₂ scavenger catalase. NADH-induced ROS accumulation was independent of mitochondrial respiration (rotenone-insensitive) but was inhibited by the flavoenzyme blocker diphenylene iodonium. NADPH oxidase was ruled out as the effector because I_NCX was insensitive to cytosolic NADPH, and NADH-induced ROS and I_NCX inhibition were not abrogated by the specific NADPH oxidase inhibitor gp91ds-tat. This study reveals a novel mechanism of NCX regulation by cytosolic NADH/NAD⁺ redox potential through a ROS-generating NADH-driven flavoprotein oxidase. The mechanism is likely to play a key role in Ca²⁺ homeostasis and the response to alterations in the cytosolic pyridine nucleotide redox state during ischemia-reperfusion or other cardiovascular diseases.     

A nitrilotriacetic acid monooxygenase with conditional NADH-oxidase activity.

A tertiary amine monoxygenase from a Pseudomonas sp. was partially purified (35-fold) and characterized. In the presence of nitrilotriacetate (NTA), O₂, NADH, and Mn²⁺, the enzyme yielded two sets of products: iminodiacetate, glyoxylate, NAD⁺ and H₂O; or H₂O₂ and NAD⁺. Which set of products predominated was a function of enzyme concentration, ionic strength of solution, pH, and cation supplied. NTA functioned both as a modifiable substrate and as a stimulator of NADH oxidase activity. A requirement for preincubation with Mn²⁺ and NTA to eliminate enzyme hysteresis and the similar Km values for NTA and Mn²⁺ suggested that the substrate and metal were bound as a unit by the enzyme.     

A vanadate-stimulated NADH oxidase in erythrocyte membrane generates hydrogen peroxide

Summary Oxidation of NADH by rat erythrocyte plasma membrane was stimulated by about 50-fold on addition of decavanadate, but not other forms of vanadate like orthovanadate, metavanadate aad vanadyl sulphate. The vanadate-stimulated activity was observed only in phosphate buffer while other buffers like Tris, acetate, borate and Hepes were ineffective. Oxygen was consumed during the oxidation of NADH and the products were found to be NAD⁺ and hydrogen peroxide. The reaction had a stoichiometry of one mole of oxygen consumption and one mole of H₂O₂ production for every mole of NADH that was oxidized.Superoxide dismutase and manganous inhibited the activity indicating the involvement of superoxide anions. Electron spin resonance in the presence of a spin trap, 5, 5-dimethyl pyrroline N-oxide, indicated the presence of superoxide radicals. Electron spin resonance studies also showed the appearance of V^IV species by reduction of V^V of decavanadate indicating thereby participation of vanadate in the redox reaction. Under the conditions of the assay, vanadate did not stimulate lipid peroxidation in erythrocyte membranes. Extracts from lipid-free preparations of the erythrocyte membrane showed full activity. This ruled out the possibility of oxygen uptake through lipid peroxidation. The vanadate-stimulated NADH oxidation activity could be partially solubilized by treating erythrocyte membranes either with Triton X-100 or sodium cholate. Partially purified enzyme obtained by extraction with cholate and fractionation by ammonium sulphate and DEAE-Sephadex was found to be unstable.     

The alpha beta epimerization of reduced nicotinamide adenine dinucleotide.

The proton magnetic resonance spectra of the dihydronicotinamide ring of αNADH³ and the nicotinamide ring of αNAD⁺ are reported and the proton absorptions assigned. The absolute assignment of the C4 methylene protons of αNADH is based on the generation of specifically deuterium-labeled (pro-S) B-deuterio-αNADH from enzymatically prepared B-deuterio-βNADH. The C4 proton absorption of αNAD⁺ is assigned by oxidation of B-deuterio-αNADH by the A specific, yeast alcohol dehydrogenase to yield 4-deuterio-αNAD⁺.The epimerization of either αNADH or βNADH yields an equilibrium ratio of approximately 9:1 βNADH to αNADH. The rate of epimerization of αNADH to βNADH at 38 °C in 0.05, pH 7.5, phosphate buffer is 3.1 × 10^?3 min^?1, corresponding to a half-life of 4 hr. Four related dehydrogenases, yeast and horse liver alcohol dehydrogenase and chicken M₄ and H₄ lactate dehydrogenase, are shown to oxidize αNADH to αNAD⁺ at rates three to four orders of magnitude slower than for βNADH. By using specifically labeled B-deuterio-αNADH the enzymatic oxidation by yeast alcohol dehydrogenase has been shown to occur with the identical stereospecificity as the oxidation of βNADH. The nonenzymatic epimerization of αNADH to βNADH and the enzymatic oxidation αNADH are discussed as a possible source of αNAD⁺in vivo.     

Formation of D-1-amino-2-propanol from L-threonine by enzymes from Escherichia coli K-12

Escherichia coli K-12 cells contain two dehydrogenases which in sequence catalyze the net conversion of L-threonine to the D-isomer of 1-amino-2-propanol. These two enzymes are L-threonine dehydrogenase (L-threonine + NAD⁺ → aminoacetone + CO₂ + NADH + H⁺) and D-1-amino-2-propanol dehydrogenase (aminoacetone + NADH + H⁺D-1-amino-2-propanol + NAD⁺). Each enzyme has been obtained in purified form free of the other; the nature of the reaction catalyzed by the latter dehydrogenase alone and in a coupled system with the former enzyme has been studied. The results provide an explanation on the enzymological level for the utilization of L-threonine by cell suspensions of certain microorganisms for the biosynthesis of the D-1-amino-2-propanol moiety of Vitamin B₁₂.     

The 2-Oxoacid Dehydrogenase Complexes in Mitochondria Can Produce Superoxide/Hydrogen Peroxide at Much Higher Rates Than Complex I

Several flavin-dependent enzymes of the mitochondrial matrix utilize NAD⁺ or NADH at about the same operating redox potential as the NADH/NAD⁺ pool and comprise the NADH/NAD⁺ isopotential enzyme group. Complex I (specifically the flavin, site I_F) is often regarded as the major source of matrix superoxide/H₂O₂ production at this redox potential. However, the 2-oxoglutarate dehydrogenase (OGDH), branched-chain 2-oxoacid dehydrogenase (BCKDH), and pyruvate dehydrogenase (PDH) complexes are also capable of considerable superoxide/H₂O₂ production. To differentiate the superoxide/H₂O₂-producing capacities of these different mitochondrial sites in situ, we compared the observed rates of H₂O₂ production over a range of different NAD(P)H reduction levels in isolated skeletal muscle mitochondria under conditions that favored superoxide/H₂O₂ production from complex I, the OGDH complex, the BCKDH complex, or the PDH complex. The rates from all four complexes increased at higher NAD(P)H/NAD(P)⁺ ratios, although the 2-oxoacid dehydrogenase complexes produced superoxide/H₂O₂ at high rates only when oxidizing their specific 2-oxoacid substrates and not in the reverse reaction from NADH. At optimal conditions for each system, superoxide/H₂O₂ was produced by the OGDH complex at about twice the rate from the PDH complex, four times the rate from the BCKDH complex, and eight times the rate from site I_F of complex I. Depending on the substrates present, the dominant sites of superoxide/H₂O₂ production at the level of NADH may be the OGDH and PDH complexes, but these activities may often be misattributed to complex I.     

Mechanism of nitrite oxidation and oxidoreductase systems inNitrobacter agilis

Chemiosmotic coupling mechanisms operate in the electron transfer reactions from: nitrite to O₂, NO₂ ^– to NAD⁺, ascorbate to O₂, NADH to O₂, and NADH to NO₃ ^–. The enzyme systems catalyzing these reactions are named NO₂ ^–:O₂ oxidoreductase, ATP-dependent NO₂ ^–:NAD⁺ oxidoreductase, ascorbate:O₂ oxidoreductase, NADH:O₂ oxidoreductase, and NADH:NO₃ ^– oxidoreductase, respectively. All of the oxidoreduction reactions are exergonic with the exception of the ATP-dependent NO₂ ^–:NAD⁺ oxidoreductase system, which involves reversed electron flow against the thermodynamic gradients. The mechanism for nitrite oxidation was found to be quite different from that of ascorbate oxidation; both systems were insensitive, however, to rotenone, amytal, antimycin A, and 2-n-heptyl 4-hydroxyquinolineN-oxide. These compounds, on the other hand, severely inhibited the electron transfer reactions catalyzed by NADH:O₂ oxidoreductase, NADH:NO₃ ^– oxidoreductase, and the ATP-dependent NO₂ ^–:NAD⁺ oxidoreductase, indicating a common pathway of electron transport in these oxidoreductase systems. Cyanide inhibited all systems except the NADH:NO₃ ^– oxidoredctase. The uncoupler carbonyl cyanide-m-chlorophenyl hydrazone strongly inhibited NO₂ ^–:O₂ oxidoreductase and ATP-dependent NO₂ ^–:NAD⁺ oxidoreductase, which indicates the involvement of energy-linked reactions in both systems; the uncoupler caused a marked stimulation of the NADH:O₂ oxidoreductase and NADH:NO₃ ^– oxidoreductase without affecting the ascorbate:O₂ oxidoreductase activities.     

Role of peroxidase in lignification of tobacco cells : I. Oxidation of nicotinamide adenine dinucleotide and formation of hydrogen peroxide by cell wall peroxidases

The two peroxidase isoenzyme groups (G_I and G_III) localized in the cell walls of tobacco (Nicotiana tabacum L.) tissues were compared with respect to their capacity for NADH-dependent H₂O₂ formation. Peroxidases of the G_III group are slightly more active than those of the G_I group when both are assayed under optimal conditions. This difference is probably not of major regulatory importance. NADH-dependent formation of H₂O₂ required the presence of Mn²⁺ and a phenol as cofactors. The addition of H₂O₂ to the reaction mixture accelerated subsequent NADH-dependent H₂O₂ formation. In the presence of both cofactors or Mn²⁺ alone, catalase oxidized NADH. However, if the cofactors were absent or if only dichlorophenol was present, catalase inhibited NADH oxidation. No H₂O₂ accumulation occurred in the presence of catalase. Superoxide dismutase inhibited NADH oxidation quite significantly indicating the involvement of the superoxide radical in the peroxidase reaction. These results are interpreted to mean that the reactions whereby tobacco cell wall peroxidases catalyze NADH-dependent H₂O₂ formation are similar to those proposed for horseradish peroxidase (Halliwell 1978 Planta 140: 81-88).     

Exogenous NAD Effects on Plant Mitochondria: A Reinvestigation of the Transhydrogenase Hypothesis

Addition of NAD⁺ to purified potato (Solanum tuberosum L.) mitochondria respiring α-ketoglutarate and malate in the presence of the electron transport inhibitor rotenone, stimulated O₂ uptake. This stimulation was prevented by incubating mitochondria with N-4-azido-2-nitrophenyl-aminobutyryl-NAD⁺ (NAP₄-NAD⁺), an inhibitor of NAD⁺ uptake, but not by 1 mm EGTA, an inhibitor of external NADH oxidation. NAD⁺-stimulated malate-cytochrome c reductase activity, and reduction of added NAD⁺ by intact mitochondria, could be duplicated by rupturing the mitochondria and adding a small quantity to the cuvette. The extent of external NAD⁺ reduction was correlated with the amount of extra mitochondrial malate dehydrogenase present. Malate oxidation by potato mitochondria depleted of endogenous NAD⁺ by storing on ice for 72 hours, was completely dependent on added NAD⁺, and the effect of NAD⁺ on these mitochondria was prevented by incubating them with NAP₄-NAD⁺. External NAD⁺ reduction by these mitochondria was not affected by NAP₄-NAD⁺. We conclude that all effects of exogenous NAD⁺ on plant mitochondrial respiration can be attributed to net uptake of the NAD⁺ into the matrix space.     

Mechanisms of citrate oxidation by percoll-purified mitochondria from potato tuber

The mechanisms and accurate control of citrate oxidation by Percoll-purified potato (Solanum tuberosum) tuber mitochondria were characterized in various metabolic conditions by recording time course evolution of the citric acid cycle related intermediates and O₂ consumption. Intact potato tuber mitochondria showed good rates of citrate oxidation, provided that nonlimiting amounts of NAD⁺ and thiamine pyrophosphate were present in the matrix space. Addition of ATP increased initial oxidation rates, by activation of the energy-dependent net citrate uptake, and stimulated succinate and malate formation. When the intramitochondrial NADH to NAD⁺ ratio was high, α-ketoglutarate only was excreted from the matrix space. After addition of ADP, aspartate, or oxaloacetate, which decreased the NADH to NAD⁺ ratio, flux rates through the Krebs cycle dehydrogenases were strongly increased and α-ketoglutarate, succinate, and malate accumulated up to steady-state concentrations in the reaction medium. It was concluded that NADH to NAD⁺ ratio could be the primary signal for coordination of fluxes through electron transport chain or malate dehydrogenase and NAD⁺-linked Krebs cycle dehydrogenases. In addition, these results clearly showed that the tricarboxylic acid cycle could serve as an important source of carbon skeletons for extra-mitochondrial synthetic processes, according to supply and demand of metabolites.     

Trichomonas vaginalis: NADH oxidase activity.

NADH oxidase activity was detected in the 105,000g supernatant (“soluble”) fraction of Trichomonas vaginalis and the enzyme was purified 50-fold by centrifugation, ammonium sulfate precipitation, Sephadex G-200, and DEAE-Sephadex A-25 chromatography. The ratio of oxygen uptake to NADH oxidation was approximately one-half. Addition of catalase did not affect the rate of oxygen uptake elicited by NADH. Since the purified fraction was free from interfering enzymes, the postulated reaction is as follows: $\text{NADH}\text{+}\text{H}{}^{\mathrm{+}}\text{+}\text{1}\text{2}\text{= NAD}{}^{\mathrm{+}}\text{+ H}{}_2\text{O}$. Among numerous substances tested, only NADH was a functional substrate, whereas NADPH was not oxidized. The purified enzyme had a V_max of 16.5 μmole of oxygen consumed/min/mg protein, and the apparent K_m for NADH was 7.4 μM. Substrate inhibition was observed at 3.7 mM NADH. The purified NADH oxidase was competitively inhibited by NAD⁺ as well as by NADP⁺ with 50% inhibition at 1 and 5 mM, respectively. The enzyme was also markedly inhibited by p-chloromercuribenzoate, hydrogen peroxide, and transient metal-chelators such as bathophenanthroline or o-phenanthroline. A flavoprotein antagonist, atebrin was slightly less inhibitory. Various quinones, flavin nucleotides and artificial dyes, except for p-benzoquinone, ferricyanide and cytochrome c, did not function in accepting electrons from NADH oxidase. These three compounds, however, were still poor electron acceptors in the enzymatic reaction suggesting that the trichomonad NADH oxidase has little diaphorase activity. All of these findings indicate that T. vaginalis has an unique NADH oxidizing enzyme in that H₂O seems to be the prdouct of oxygen reduction. This NADH oxidase appears important in the aerobic metabolism of this parasite.     

Generation of hydrogen peroxide on oxidation of NADH by hepatic plasma membranes

The oxidation of NADH by mouse liver plasma membranes was shown to be accompanied by the formation of H₂O₂. The rate of H₂O₂ formation was less than one-tenth the rate of oxygen uptake and much slower than the rate of reduction of artificial electron acceptors. The optimum pH for this reaction was 7.0 and theK _m value for NADH was found to be 3×10^–6 M. The H₂O₂-generating system of plasma membranes was inhibited by quinacrine and azide, thus distinguishing it from similar activities in endoplasmic reticulum and mitochondria. Both NADH and NADPH served as substrates for plasma membrane H₂O₂ generation. Superoxide dismutase and adriamycin inhibited the reaction. Vanadate, known to stimulate the oxidation of NADH by plasma membranes, did not increase the formation of H₂O₂. In view of the growing evidence that H₂O₂ can be involved in metabolic control, the formation of H₂O₂ by a plasma membrane NAD(P)H oxidase system may be pertinent to control sites at the plasma membrane.