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.     

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.     

Purification and characterization of an NADH oxidase from extremely thermophilic anaerobic bacterium Thermotoga hypogea

Thermotoga hypogea is an extremely thermophilic anaerobic bacterium capable of growing at 90°C. It was found to be able to grow in the presence of micromolar molecular oxygen (O₂). Activity of NADH oxidase was detected in the cell-free extract of T. hypogea, from which an NADH oxidase was purified to homogeneity. The purified enzyme was a homodimeric flavoprotein with a subunit of 50 kDa, revealed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. It catalyzed the reduction of O₂ to hydrogen peroxide (H₂O₂), specifically using NADH as electron donor. Its catalytic properties showed that the NADH oxidase had an apparent V_max value of 37 mol NADH oxidized min^–1 mg^–1 protein. Apparent K_m values for NADH and O₂ were determined to be 7.5 M and 85 M, respectively. The enzyme exhibited a pH optimum of 7.0 and temperature optimum above 85°C. The NADH-dependent peroxidase activity was also present in the cell-free extract, which could reduce H₂O₂ produced by the NADH oxidase to H₂O. It seems possible that O₂ can be reduced to H₂O by the oxidase and peroxidase, but further investigation is required to conclude firmly if the purified NADH oxidase is part of an enzyme system that protects anaerobic T. hypogea from accidental exposure to O₂.     

Chemical Modification of Catalytically Essential Functional Groups of NAD-Dependent Hydrogenase from Ralstonia eutropha H16

Amino acid residues His and Cys of the NAD-dependent hydrogenase from the hydrogen-oxidizing bacterium Ralstonia eutropha H16 were chemically modified with specific reagents. The modification of His residues of the nonactivated hydrogenase resulted in decrease in both hydrogenase and diaphorase activities of the enzyme. Activation of NADH hydrogenase under anaerobic conditions additionally modified a His residue (or residues) significant only for the hydrogenase activity. The rate of decrease in the diaphorase activity was unchanged. The modification of thiol groups of the nonactivated enzyme did not affect the hydrogenase activity. The effect of thiol-modifying agents on the activated hydrogenase was accompanied by inactivation of both diaphorase and hydrogenase activities. The modification degree and changes in the corresponding catalytic activities depended on conditions of the enzyme activation. Data on the modification of cysteine and histidine residues of the hydrogenase suggested that the enzyme activation should be associated with significant conformational changes in the protein globule.     

Use of a Reverse Micelle System for Study of Oligomeric Structure of NAD<Superscript>+</Superscript>-Reducing Hydrogenase from <Emphasis Type="Italic">Ralstonia eutropha</Emphasis> H16

Inclusion of an oligomeric enzyme, NAD⁺-dependent hydrogenase from the hydrogen-oxidizing bacterium Ralstonia eutropha, into a system of reverse micelles of different sizes resulted in its dissociation into catalytically active heterodimers and subunits, which were characterized in reactions with various substrates. It was found that: 1) the native tetrameric form of this enzyme catalyzes all types of studied reactions; 2) hydrogenase dimer, HoxHY, is a minimal structural unit catalyzing hydrogenase reaction with an artificial electron donor, reduced methyl viologen; 3) all structural fragments containing FMN and NAD⁺/NADH-binding sites exhibit catalytic activity in diaphorase reactions with one- and two-electron acceptors; 4) small subunits, HoxY and HoxU also exhibit activity in diaphorase reactions with artificial acceptors. These results can be considered as indirect evidence that the second FMN molecule may be associated with one of the small subunits (HoxY or HoxU) of the hydrogenase from R. eutropha.__________Translated from Biokhimiya, Vol. 70, No. 6, 2005, pp. 782–789.Original Russian Text Copyright © 2005 by Tikhonova, Kurkin, Klyachko, Popov.     

NADP-Specific Electron-Bifurcating [FeFe]-Hydrogenase in a Functional Complex with Formate Dehydrogenase in Clostridium autoethanogenum Grown on CO

Flavin-based electron bifurcation is a recently discovered mechanism of coupling endergonic to exergonic redox reactions in the cytoplasm of anaerobic bacteria and archaea. Among the five electron-bifurcating enzyme complexes characterized to date, one is a heteromeric ferredoxin- and NAD-dependent [FeFe]-hydrogenase. We report here a novel electron-bifurcating [FeFe]-hydrogenase that is NADP rather than NAD specific and forms a complex with a formate dehydrogenase. The complex was found in high concentrations (6% of the cytoplasmic proteins) in the acetogenic Clostridium autoethanogenum autotrophically grown on CO, which was fermented to acetate, ethanol, and 2,3-butanediol. The purified complex was composed of seven different subunits. As predicted from the sequence of the encoding clustered genes (fdhA/hytA-E) and from chemical analyses, the 78.8-kDa subunit (FdhA) is a selenocysteine- and tungsten-containing formate dehydrogenase, the 65.5-kDa subunit (HytB) is an iron-sulfur flavin mononucleotide protein harboring the NADP binding site, the 51.4-kDa subunit (HytA) is the [FeFe]-hydrogenase proper, and the 18.1-kDa (HytC), 28.6-kDa (HytD), 19.9-kDa (HytE1), and 20.1-kDa (HytE2) subunits are iron-sulfur proteins. The complex catalyzed both the reversible coupled reduction of ferredoxin and NADP⁺ with H₂ or formate and the reversible formation of H₂ and CO₂ from formate. We propose the complex to have two functions in vivo, namely, to normally catalyze CO₂ reduction to formate with NADPH and reduced ferredoxin in the Wood-Ljungdahl pathway and to catalyze H₂ formation from NADPH and reduced ferredoxin when these redox mediators get too reduced during unbalanced growth of C. autoethanogenum on CO (E_0′ = −520 mV).     

UDP-galactose 4′-epimerase from vicia faba seeds

UDP-Galactose 4′-epimerase was purified ca 800-fold through a multi-step procedure which included affinity chromatography using NAD⁺ -Agarose. Three forms of the enzyme were separated by gel-filtration but only the major form was purified. The pH optimum of the enzyme was 9.5. Exogenous NAD⁺ was not required for enzymic activity but its removal caused inactivation. The enzyme was unstable below pH 7.0 but stable at pH 8.0 in the presence of glycerol and at ?20° for two months. The equilibrium constant for the enzyme-catalysed reaction was 3.2 ± 0.15. The K_m for UDP-galactose and UDP-glucose were 0.12 mM and 0.25 mM, respectively. The inhibition by NADH was competitive, with a K_i of 5 μM. The MW of the enzyme was 78 000; the two minor forms showed the values of 158 000 and 39 000, respectively.     

Lactate dehydrogenase isoenzymes of sperm cells and testes

1. The kinetic and metabolic properties of lactate dehydrogenase isoenzyme LDH_x from human sperm cells and rat testes were studied. 2. LDH_x shows a sensitivity to inhibition by stilboestrol diphosphate, urea and guanidinium chloride different from that of the LDH-H₄ and LDH-M₄ isoenzymes. 3. About 10 and 20% of the total lactate dehydrogenase activity of testes and sperm cells respectively were associated with particulate fractions. In sperm cells 11% was localized in the middle piece and 18·8% in the head fraction. LDH_x was found in all particulate fractions of sperm cells. The middle piece contained 41·0% of total LDH_x activity and showed high succinate dehydrogenase activity. 5. The pH-dependence of lactate/pyruvate and NAD⁺/NADH concentration ratios were estimated. Lactate dehydrogenase in sperm cells has maximal activity with NADH as coenzyme at pH7·5 and with NADPH as coenzyme at pH6·0. At pH6·0 a 10% greater oxidation of NADPH than of NADH was found. At acid pH lactate hydrogenase may function as an enzyme bringing about transhydrogenation from NADPH to NAD⁺. 6. In agreement with the stoicheiometry of the lactate de- hydrogenase reaction, the lactate/pyruvate concentration ratio decreased with increasing pH. 7. The lactate/pyruvate and NAD⁺/NADH concentration ratios were estimated with glucose, fructose and sorbitol as substrates and as a function of time after addition of these substrates. During a 20min. period after the addition of the substrates, changes in lactate/pyruvate and NAD⁺/NADH concentration ratios were noticed. Increasing concentration of the substrates mentioned gave rise to asymptotic increases in lactate and pyruvate. 8. Sorbitol did not act as a substrate for LDH_x. 9. The findings described are consistent with the idea that LDH_x is different from other known lactate dehydrogenase isoenzymes, but that it has a metabolic function similar to that of the isoenzymes of other tissues.     

Intact Functional Fourteen-subunit Respiratory Membrane-bound [NiFe]-Hydrogenase Complex of the Hyperthermophilic Archaeon Pyrococcus furiosus

The archaeon Pyrococcus furiosus grows optimally at 100 °C by converting carbohydrates to acetate, CO₂, and H₂, obtaining energy from a respiratory membrane-bound hydrogenase (MBH). This conserves energy by coupling H₂ production to oxidation of reduced ferredoxin with generation of a sodium ion gradient. MBH is encoded by a 14-gene operon with both hydrogenase and Na⁺/H⁺ antiporter modules. Herein a His-tagged MBH was expressed in P. furiosus and the detergent-solubilized complex purified under anaerobic conditions by affinity chromatography. Purified MBH contains all 14 subunits by electrophoretic analysis (13 subunits were also identified by mass spectrometry) and had a measured iron:nickel ratio of 15:1, resembling the predicted value of 13:1. The as-purified enzyme exhibited a rhombic EPR signal characteristic of the ready nickel-boron state. The purified and membrane-bound forms of MBH both preferentially evolved H₂ with the physiological donor (reduced ferredoxin) as well as with standard dyes. The O₂ sensitivities of the two forms were similar (half-lives of ∼15 h in air), but the purified enzyme was more thermolabile (half-lives at 90 °C of 1 and 25 h, respectively). Structural analysis of purified MBH by small angle x-ray scattering indicated a Z-shaped structure with a mass of 310 kDa, resembling the predicted value (298 kDa). The angle x-ray scattering analyses reinforce and extend the conserved sequence relationships of group 4 enzymes and complex I (NADH quinone oxidoreductase). This is the first report on the properties of a solubilized form of an intact respiratory MBH complex that is proposed to evolve H₂ and pump Na⁺ ions.     

Purification and properties of the membrane-bound NADH oxidase of a facultatively anaerobic alkaliphile

A membrane-bound NADH oxidase of an anaerobic alkaliphile, M-12 (a strain of Amphibacillus sp.), was solubilized with decanoyl N-methylglucamide and purified by chromatography on DEAE-Sepharose and hydroxyapatite. The purified enzyme appears to consist of a single polypeptide component with an apparent molecular mass of 56 kDa. The enzyme catalyzed the oxidation of NADH with the formation of H₂O₂ and exhibited a specific activity of 46 μmol NADH min^–1 (mg protein)^–1. NADPH did not serve as a substrate for the enzyme. The K _m for NADH was estimated to be 0.05 mM. The enzyme exhibited a pH dependence for activity, with a pH optimum at approximately 9.5. The enzyme required a high concentration of salt and exhibited maximum activity in the presence of 600 mM NaCl. Received: 3 August 1998 / Accepted: 23 December 1998     

Kinetic parameters for hydrogen evolution by the NAD-linked hydrogenase of Alcaligenes eutrophus

The hydrogen-evolving reaction of the purified soluble NAD-linked hydrogenase of Alcaligenes eutrophus was used to determine kinetic parameters of the enzyme. The H₂-evolving activity with methyl viologen as electron mediator was 20-fold as compared to that with NADH. In the assay with dithionite-reduced methyl viologen (K _m 0.7 mM) the hydrogenase was most active at a redox potential of –560 mV and exhibited a pH optimum of 7.0. The K _m for protons, the second substrate for H₂ evolution, was 6.2 nM. With electrochemically reduced methyl viologen the pH optimum was shifted to pH 6.0. Double-reciprocal plots of reaction rates versus proton concentrations intercepted at the ordinate for different methyl viologen concentrations. At different pH values such an intercept was also observed with the dye as the varied substrate. The kinetic data are diagnostic for an ordered bisubstrate mechanism where both substrates are bound before the product H₂ is released. Hydrogenase coupled to thylakoid membranes resulted in a constant H₂ evolution rate over 6 h. The system appeared to be limited by the capacity of the thylakoid membranes.     

Anaerobic dissimilatory phosphite oxidation,an extremely efficient concept of microbial electron economy

Phosphite is a stable phosphorus compound that, together with phosphate, made up a substantial part of the total phosphorus content of the prebiotic Earth's crust. Oxidation of phosphite to phosphate releases electrons at an unusually low redox potential (−690 mV at pH 7.0). Numerous aerobic and anaerobic bacteria use phosphite as a phosphorus source and oxidise it to phosphate for synthesis of nucleotides and other phosphorus-containing cell constituents. Only two pure cultures of strictly anaerobic bacteria have been isolated so far that use phosphite as an electron donor in their energy metabolism, the Gram-positive Phosphitispora fastidiosa and the Gram-negative Desulfotignum phosphitoxidans. The key enzyme of this metabolism is an NAD⁺-dependent phosphite dehydrogenase enzyme that phosphorylates AMP to ADP. These phosphorylating phosphite dehydrogenases were found to be related to nucleoside diphosphate sugar epimerases. The produced NADH is channelled into autotrophic CO₂ fixation via the Wood-Ljungdahl (CO-DH) pathway, thus allowing for nearly complete assimilation of the substrate electrons into bacterial biomass. This extremely efficient type of electron flow connects energy and carbon metabolism directly through NADH and might have been important in the early evolution of life when phosphite was easily available on Earth.     

Electron bifurcation involved in the energy metabolism of the acetogenic bacterium Moorella thermoacetica growing on glucose or H2 plus CO2

Moorella thermoacetica ferments glucose to three acetic acids. In the oxidative part of the fermentation, the hexose is converted to 2 acetic acids and 2 CO(2) molecules with the formation of 2 NADH and 2 reduced ferredoxin (Fd(red)(2-)) molecules. In the reductive part, 2 CO(2) molecules are reduced to acetic acid, consuming the 8 reducing equivalents generated in the oxidative part. An open question is how the two parts are electronically connected, since two of the four oxidoreductases involved in acetogenesis from CO(2) are NADP specific rather than NAD specific. We report here that the 2 NADPH molecules required for CO(2) reduction to acetic acid are generated by the reduction of 2 NADP(+) molecules with 1 NADH and 1 Fd(red)(2-) catalyzed by the electron-bifurcating NADH-dependent reduced ferredoxin:NADP(+) oxidoreductase (NfnAB). The cytoplasmic iron-sulfur flavoprotein was heterologously produced in Escherichia coli, purified, and characterized. The purified enzyme was composed of 30-kDa (NfnA) and 50-kDa (NfnB) subunits in a 1-to-1 stoichiometry. NfnA harbors a [2Fe2S] cluster and flavin adenine dinucleotide (FAD), and NfnB harbors two [4Fe4S] clusters and FAD. M. thermoacetica contains a second electron-bifurcating enzyme. Cell extracts catalyzed the coupled reduction of NAD(+) and Fd with 2 H(2) molecules. The specific activity of this cytoplasmic enzyme was 3-fold higher in H(2)-CO(2)-grown cells than in glucose-grown cells. The function of this electron-bifurcating hydrogenase is not yet clear, since H(2)-CO(2)-grown cells additionally contain high specific activities of an NADP(+)-dependent hydrogenase that catalyzes the reduction of NADP(+) with H(2). This activity is hardly detectable in glucose-grown cells.     

Insights into electron flux through manipulation of fermentation conditions and assessment of protein expression profiles in Clostridium thermocellum

While annotation of the genome sequence of Clostridium thermocellum has allowed predictions of pathways catabolizing cellobiose to end products, ambiguities have persisted with respect to the role of various proteins involved in electron transfer reactions. A combination of growth studies modulating carbon and electron flow and multiple reaction monitoring (MRM) mass spectrometry measurements of proteins involved in central metabolism and electron transfer was used to determine the key enzymes involved in channeling electrons toward fermentation end products. Specifically, peptides belonging to subunits of ferredoxin-dependent hydrogenase and NADH:ferredoxin oxidoreductase (NFOR) were low or below MRM detection limits when compared to most central metabolic proteins measured. The significant increase in H₂ versus ethanol synthesis in response to either co-metabolism of pyruvate and cellobiose or hypophosphite mediated pyruvate:formate lyase inhibition, in conjunction with low levels of ferredoxin-dependent hydrogenase and NFOR, suggest that highly expressed putative bifurcating hydrogenases play a substantial role in reoxidizing both reduced ferredoxin and NADH simultaneously. However, product balances also suggest that some of the additional reduced ferredoxin generated through increased flux through pyruvate:ferredoxin oxidoreductase must be ultimately converted into NAD(P)H either directly via NADH-dependent reduced ferredoxin:NADP⁺ oxidoreductase (NfnAB) or indirectly via NADPH-dependent hydrogenase. While inhibition of hydrogenases with carbon monoxide decreased H₂ production 6-fold and redirected flux from pyruvate:ferredoxin oxidoreductase to pyruvate:formate lyase, the decrease in CO₂ was only 20 % of that of the decrease in H₂, further suggesting that an alternative redox system coupling ferredoxin and NAD(P)H is active in C. thermocellum in lieu of poorly expressed ferredoxin-dependent hydrogenase and NFOR.     

Microbial oxidation of methanol: Purification and properties of formaldehyde dehydrogenase from a Pichia sp. NRRL-Y-11328

An NAD⁺-linked, reduced glutathione-dependent formaldehyde dehydrogenase was purified to homogeneity from soluble extracts of methanol-grown yeast, Pichia sp. Formaldehyde and methylglyoxal are oxidized in the presence of NAD⁺ as an electron acceptor. NADP⁺ could not replace NAD⁺. Other straight chain aldehydes (C₂–C₆ tested), branched-chain aldehydes (e.g., isobutyaldehyde), aromatic aldehydes (e.g., salicylal-dehyde, benzaldehyde), glutyraldehyde, glyceraldehyde, glycoaldehyde, and glyoxal-dehyde tested were not oxidized by the purified formaldehyde dehydrogenase. The product of formaldehyde oxidation by purified enzyme was demonstrated to be S-for-mylglutathione by measuring the absorption at 240 nm due to the formation of thioester of formaldehyde and reduced glutathione. The K_m values for NAD⁺, formaldehyde, and reduced glutathione were 0.12, 0.31, and 0.16 mm, respectively, for the forward reaction at pH 8.0. The purified formaldehyde dehydrogenase also catalyzed the reduction of S-formylglutathione in the presence of NADH. Formate was not reduced by the purified enzyme. The K_m values for S-formylglutathione and NADH were 0.60 and 0.25 mm, respectively, for the reverse reaction at pH 6.0. Formaldehyde dehydrogenase has a molecular weight of 84,000 as determined by gel filtration and subunit molecular weight of 41,000 as determined by sodium dodecyl sulfate-gel electrophoresis. S-Formylglutathione, a product of formaldehyde oxidation, was oxidized by the partially purified formate dehydrogenase from Pichia sp. Formate dehydrogenase has a higher affinity toward S-formylglutathione (K_m value 1.8 mm) than toward formate (K_m value 25 mm). Antiserum prepared against the purified formaldehyde dehydrogenase from Pichia sp. NRRL-Y-11328 forms strong precipitin bands with isofunctional enzymes from methanol-grown Pichia pastoris NRRL-Y-7556 and Torulopsis candida Y-11419 and weak precipitin bands with Hansenula polymorpha NRRL-Y-2214. No cross-reaction was observed with isofunctional enzyme derived from methanol-grown Kloeckera sp.     

A novel mode of lactate metabolism in strictly anaerobic bacteria

Lactate is a common substrate for major groups of strictly anaerobic bacteria, but the biochemistry and bioenergetics of lactate oxidation is obscure. The high redox potential of the pyruvate/lactate pair of E₀′ = ?190 mV excludes direct NAD⁺ reduction (E₀′ = ?320 mV). To identify the hitherto unknown electron acceptor, we have purified the lactate dehydrogenase (LDH) from the strictly anaerobic, acetogenic bacterium Acetobacterium woodii. The LDH forms a stable complex with an electron‐transferring flavoprotein (Etf) that exhibited NAD⁺ reduction only when reduced ferredoxin (Fd^2?) was present. Biochemical analyses revealed that the LDH/Etf complex of A. woodii uses flavin‐based electron confurcation to drive endergonic lactate oxidation with NAD⁺ as oxidant at the expense of simultaneous exergonic electron flow from reduced ferredoxin (E₀′ ≈ –500 mV) to NAD⁺ according to: lactate + Fd^2? + 2 NAD⁺ → pyruvate + Fd + 2 NADH. The reduced Fd^2? is regenerated from NADH by a sequence of events that involves conversion of chemical (ATP) to electrochemical and finally redox energy (Fd^2? from NADH) via reversed electron transport catalysed by the Rnf complex. Inspection of genomes revealed that this metabolic scenario for lactate oxidation may also apply to many other anaerobes.     

Properties of the solubilized membrane-bound hydrogenase from the photosynthetic bacterium Rhodospirillum rubrum.

The membrane-bound hydrogenase of the photosynthetic bacterium Rhodospirillum rubrum has been purified 490-fold with a yield of 5.8%. The enzyme was homogeneous by disc gel electrophoresis. A method for the permanent, oxygen-insensitive, staining of hydrogenase on polyacrylamide gels is described. The enzyme is a monomer of molecular weight about 66,000 containing four iron and four acid-labile sulfur atoms per molecule. The electron paramagnetic resonance spectrum at 20 °K exhibits a strong signal in the oxidized state only with g > 2—this is characteristic of high potential iron-sulfur protein. The hydrogenase is thermostable and also resistant to both denaturation agents and oxygen inactivation. Carbon monoxide reversibly inhibits the enzyme but metal-complexing and thiol-blocking reagents have little effect on activity. The enzyme will catalyze both H₂ evolution and H₂ uptake in the presence of many artificial electron carriers but the two activities differ in their pH optima. There is a correlation between H₂ evolution activity and the redox potential of the mediator dye. Ferredoxins and pyridine nucleotides do not readily interact with the hydrogenase. We have shown that irradiation of a solution containing methyl viologen, EDTA, proflavin, and R. rubrum hydrogenase will evolve hydrogen continuously for over 9 h. However, the enzyme evolves hydrogen at only very low rates from in vitro chloroplast-ferredoxin and chloroplast-methyl viologen systems. R. rubrum hydrogenase has a number of properties in common with the hydrogenases purified from two other photosynthetic bacteria, Chromatium and Thiocapsa, but is distinct from the hydrogenases of nonphotosynthetic bacteria.     

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.