Reversible inactivation of the O2-labile hydrogenases from Azotobacter vinelandii and Rhizobium japonicum

Hydrogenases catalyze the reversible activation of dihydrogen. The hydrogenases from the aerobic, N2-fixing microorganisms Azotobacter vinelandii and Rhizobium japonicum are nickel- and iron-containing dimers that belong to the group of O2-labile enzymes. Exposure of these hydrogenases to O2 results in an irreversible inactivation; therefore, these enzymes are purified anaerobically in a fully active state. We describe in this paper an electron acceptor-requiring and pH-dependent, reversible inactivation of these hydrogenases. These results are the first example of an anaerobic, reversible inactivation of the O2-labile hydrogenases. The reversible inactivation required the presence of an electron acceptor. The rate of inactivation was first-order, with similar rates observed for methylene blue, benzyl viologen, and phenazine-methosulfate. The rate of inactivation was also dependent on the pH. However, increasing the pH of the enzyme in the absence of an electron acceptor did not result in inactivation. Thus, the reversible inactivation was not a result of high pH alone. The inactive enzyme could not be reactivated by H2 or other reductants at high pH. Titration of enzyme inactivated at high pH back to low pH was also ineffective at reactivating the enzyme. However, if reductants were present during this titration, the enzyme could be fully reactivated. The temperature dependence of inactivation yielded an activation energy of 44 kJ X mol-1. Gel filtration chromatography of active and inactive hydrogenase indicated that neither dissociation nor aggregation of the dimer hydrogenase was responsible for this reversible inactivation. We propose a four-state model to describe this reversible inactivation.     

Purification and properties of membrane-bound hydrogenase from Azotobacter vinelandii

Uptake hydrogenase (EC 1.12) from Azotobacter vinelandii has been purified 250-fold from membrane preparations. Purification involved selective solubilization of the enzyme from the membranes, followed by successive chromatography on DEAE-cellulose, Sephadex G-100, and hydroxylapatite. Freshly isolated hydrogenase showed a specific activity of 110 mumol of H2 uptake (min X mg of protein)-1. The purified hydrogenase still contained two minor contaminants that ran near the front on sodium dodecyl sulfate-polyacrylamide gels. The enzyme appears to be a monomer of molecular weight near 60,000 +/- 3,000. The pI of the protein is 5.8 +/- 0.2. With methylene blue or ferricyanide as the electron acceptor (dyes such as methyl or benzyl viologen with negative midpoint potentials did not function), the enzyme had pH optima at pH 9.0 or 6.0, respectively, It has a temperature optimum at 65 to 70 degrees C, and the measured half-life for irreversible inactivation at 22 degrees C by 20% O2 was 20 min. The enzyme oxidizes H2 in the presence of an electron acceptor and also catalyzes the evolution of H2 from reduced methyl viologen; at the optimal pH of 3.5, 3.4 mumol of H2 was evolved (min X mg of protein)-1. The uptake hydrogenase catalyzes a slow deuterium-water exchange in the absence of an electron acceptor, and the highest rate was observed at pH 6.0. The Km values varied widely for different electron acceptors, whereas the Km for H2 remained virtually constant near 1 to 2 microM, independent of the electron acceptors.     

Fermentation of biomass-generated synthesis gas: effects of nitric oxide

The production of renewable fuels, such as ethanol, has been steadily increasing owing to the need for a reduced dependency on fossil fuels. It was demonstrated previously that biomass-generated synthesis gas (biomass-syngas) can be converted to ethanol and acetic acid using a microbial catalyst. The biomass-syngas (primarily CO, CO(2), H(2), and N(2)) was generated in a fluidized-bed gasifier and used as a substrate for Clostridium carboxidivorans P7(T). Results showed that the cells stopped consuming H(2) when exposed to biomass-syngas, thus indicating that there was an inhibition of the hydrogenase enzyme due to some biomass-syngas contaminant. It was hypothesized that nitric oxide (NO) detected in the biomass-syngas could be the possible cause of this inhibition. The specific activity of hydrogenase was monitored with time under varying concentrations of H(2) and NO. Results indicated that NO (at gas concentrations above 40 ppm) was a non-competitive inhibitor of hydrogenase activity, although the loss of hydrogenase activity was reversible. In addition, NO also affected the cell growth and increased the amount of ethanol produced. A kinetic model of hydrogenase activity with inhibition by NO was demonstrated with results suggesting there are multiple binding sites of NO on the hydrogenase enzyme. Since other syngas-fermenting organisms utilize the same metabolic pathways, this study estimates that NO < 40 ppm can be tolerated by cells in a syngas-fermentation system without compromising the hydrogenase activity, cell growth, and product distribution.     

Role of hydrogen in the activation and regulation of hydrogen oxidation by the soluble hydrogenase from Alcaligenes eutrophus H16.

The activation kinetics of the H2-oxidizing activity of the soluble hydrogenase from Alcaligenes eutrophus H16 were investigated. Activation with Na2S2O4 plus 101 kPa H2 resulted in a rapid increase in activity over 1 h and constant activity after 3 h incubation. Less-stable activations were achieved if enzyme was incubated with Na2S2O4 under 1 kPa H2 or 101 kPa N2. The enzyme could also be partly activated either with NADH alone or with H2 alone. The level of activity obtained with both 101 kPa H2 and NADH present was greater than that obtained with either 101 kPa H2 or NADH alone. Activation with H2 plus NADH was virtually independent of NADH concentration but highly dependent on H2 concentration. The effects of various concentrations of H2 and constant concentration of NADH on the level of activation were the same whether H2 oxidation was assayed by H2-dependent Methylene Blue or NAD+ reduction. Diaphorase activity did not require activation and was little affected by the treatments that activated H2-oxidizing activity. The results suggest that H2 plays an important role in regulating the level of H2-oxidizing activity in this soluble hydrogenase.     

Purification of hydrogenases by affinity chromatography on Procion Red-agarose.

The agarose-coupled triazine dye Procion Red HE-3B has been demonstrated to be applicable as an affinity gel for the purification of five diverse hydrogenases, namely the soluble, NAD-specific and the membrane-bound hydrogenase of Alcaligenes eutrophus, the membrane-bound hydrogenase of the N2-fixing Alcaligenes latus, the reversible H2-evolving and the unidirectional H2-oxidizing hydrogenase of Clostridium pasteurianum. In the case of the soluble hydrogenase of A. eutrophus, chromatography on Procion Red-agarose even permitted the separation of inactive from active enzyme, thus yielding a 2-3-fold increase in specific activity. For the homogeneous enzyme preparation obtained after two column steps (Procion Red-agarose, DEAE-Sephacel), a specific activity of 121 mumol of H2 oxidized/min per mg of protein was determined. Kinetic studies with free Procion Red provided evidence that the diverse hydrogenases are competitively inhibited by the dye, each with respect to the electron carrier (NAD, Methylene Blue, Methyl Viologen), indicating a specific interaction between Procion Red and the catalytic centres of the enzymes. For the highly purified preparations of the soluble and the membrane-bound hydrogenase of A. eutrophus, in 50 mM-potassium phosphate, pH 7.0, Ki values for Procion Red of 103 and 19 microM have been determined.     

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.     

Hydrogenase activities in cyanobacteria

In the unicellular Anacystis nidulans, the expression of both the H2-uptake (with phenazine methosulfate or methylene blue as the electron acceptor) and H2-evolution (with methyl viologen reduced by Na2S2O4) was dependent on Ni in the culture medium. In extracts from Anacystis and Anabaena 7119, H2-evolution and uptake activities were strongly inhibited by Cu2+, p-chloromercuribenzoate and HgCl2 suggesting that at least one functional SH-group is involved in catalysis by hydrogenase. Extracts from the N2-fixing Anabaena 7119 contained two different hydrogenase fractions which could be separated by chromatography on DE-52 cellulose using a linear NaCl concentration gradient. The fraction eluting with 0.13 M NaCl from the column catalyzed only the uptake of H2 with methylene blue as the electron acceptor but virtually not the evolution of H2 ("uptake" hydrogenase fraction). The fraction eluting at a NaCl strength of 0.195 M catalyzed both H2-uptake with methylene blue and H2-evolution with reduced methyl viologen ("reversible" hydrogenase fraction). Growth under anaerobic conditions drastically enhanced the activity levels of the "reversible" but not of the "uptake" hydrogenase fraction. The "uptake" hydrogenase but not the "reversible" protein was activated by reduced thioredoxin. It is suggested that thioredoxin activates the H2-uptake by the membrane-bound "uptake" hydrogenase also in intact cells. The occurrence of the number of hydrogenases in cyanobacteria will be reevaluated.     

The assumption that nitric oxide inhibits mitochondrial ATP synthesis is correct

The assumption that reversible inhibition of mitochondrial respiration by nitric oxide (NO.) represents inhibition of ATP synthesis is unproven. NO. could theoretically inhibit the oxygen consumption with continued ATP synthesis, by acting as an electron acceptor from cytochrome c or as a terminal electron acceptor in stead of oxygen. We report here that NO. does reversibly inhibit brain mitochondrial ATP synthesis with a time course similar to its inhibition of respiration. Whilst such inhibition was largely reversible, there appeared to be a small irreversible component which may theoretically be due to peroxynitrite formation, i.e. as a result of the reaction between NO. and superoxide, generated by the mitochondrial respiratory chain.     

Nickel is a component of hydrogenase in Rhizobium japonicum

The derepression of H2-oxidizing activity in free-living Rhizobium japonicum does not require the addition of exogenous metal to the derepression media. However, the addition of EDTA (6 microM) inhibited derepression of H2 uptake activity by 80%. The addition of 5 microM nickel to the derepression medium overcame the EDTA inhibition. The addition of 5 microM Cu or Zn also relieved EDTA inhibition, but to a much lesser extent; 5 microM Fe, Co, Mg, or Mn did not. The kinetics of induction and magnitude of H2 uptake activity in the presence of EDTA plus Ni were similar to those of normally derepressed cells. Nickel also relieved EDTA inhibition of methylene blue-dependent Hup activity, suggesting that nickel is involved directly with the H2-activating hydrogenase enzyme. Adding nickel or EDTA to either whole cells or crude extracts after derepression did not affect the hydrogenase activity. Cells were grown in 63Ni and the hydrogenase was subsequently purified by gel electrophoresis. 63Ni comigrated with the H2-dependent methylene blue reducing activity on native polyacrylamide gels and native isoelectric focusing gels. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the nickel-containing hydrogenase band revealed a single polypeptide with a molecular weight of ca. 67,000. We conclude that the hydrogenase enzyme in R. japonicum is a nickel-containing metalloprotein.     

Incorporation of a bacterial membrane-bound hydrogenase into proteoliposomes.

Membrane-bound nickel-iron hydrogenases from diverse genera of bacteria have been previously characterized and they are closely related. We report the reconstitution of purified Bradyrhizobium japonicum hydrogenase into proteoliposomes by a detergent dialysis method followed by two or three cycles of freeze-thaw. Sedimentation experiments revealed that more than 60% of the H2-uptake activity was particulate when reconstituted into Escherichia coli phospholipids. Sucrose-gradient centrifugation separated hydrogenase activity into two peaks, the less dense of which was phospholipid-associated and turbid, thereby showing successful incorporation. Purified enzyme did not bind to performed phospholipid vesicles, and 1.0 M NaCl failed to remove incorporated hydrogenase. The optimal micellar detergent:phospholipid ratio (rho) value for hydrogenase incorporation was 2.0. Proteoliposomes containing acidic phospholipids were the most effective for incorporation as well as for activity. The artificial electron acceptor specificity was similar for proteoliposomes and for H2-oxidizing membranes from B. japonicum. Proteoliposomes formed under optimal conditions had a broad size distribution centered around 400 nm diameter. Hydrogenase activity in proteoliposomes was partially protected from inactivation by the protein modification reagent diazobenzene sulfonate (DABS) (inactivation t1/2 = 30 min), whereas DABS rapidly inactivated the purified enzyme (t1/2 = 4 min). The latter result indicates protection of a catalytically important site by the phospholipid bilayer. This experimental system should be useful in addressing questions regarding the in vivo situation of bacterial membrane-bound hydrogenases.     

Interaction of HydSL hydrogenase from the purple sulfur bacterium Thiocapsa roseopersicina BBS with methyl viologen and positively charged polypeptides

The effect of polypeptides having different charge on the activity of Thiocapsa roseopersicina HydSL hydrogenase was studied. Strong inhibition was shown for poly-L-lysine bearing positive charge. The inhibition was reversible and competitive to methyl viologen, an electron acceptor, in the reaction of hydrogen oxidation catalyzed by the hydrogenase. Peptides carrying less positive charge had weaker inhibiting effect, while neutral and negatively charged peptides did not inhibit the hydrogenase. Molecular docking of poly-L-lysine to T. roseopersicina hydrogenase showed strong affinity of this polypeptide to the acceptor-binding site of the enzyme. The calculated binding constant is close to the experimentally measured value (K _i = 2.1 μM).     

Effect of nickel on activity and subunit composition of purified hydrogenase from Nocardia opaca 1 b

The NAD-reducing hydrogenase of Nocardia opaca 1 b was found to be a soluble, cytoplasmic enzyme. N. opaca 1 b does not contain an additional membrane-bound hydrogenase. The soluble enzyme was purified to homogeneity with a yield of 19% and a final specific activity of 45 mumol H2 oxidized min-1 mg protein-1. NAD reduction with H2 was completely dependent on the presence of divalent metal ions (Ni2+, Co2+, Mg2+, Mn2+) or of high salt concentrations (0.5-1.5 M). The most specific effect was caused by NiCl2, whose optimal concentration turned out to be 1 mM. The stimulation of activity by salts was the greater the less chaotrophic the anion. Maximal activity was achieved in 0.5 M potassium phosphate. Hydrogenase was also activated by protons. The pH optimum in 50 mM triethanolamine/HCl buffer containing 1 mM NiCl2 was 7.8-8.0. In the absence of Ni2+, hydrogenase was only active at pH values below 7.0. The reduction of other electron acceptors was not dependent on metal ions or salts, even though an approximately 1.5-fold stimulation of the reactions by 0.1-10 microM NiCl2 was observed. With the most effective electron acceptor, benzyl viologen, a 50-fold higher specific activity was determined than with NAD. The total molecular weight of hydrogenase has been estimated to be 200 000 (gel filtration) and 178 000 (sucrose density gradient centrifugation, and sodium dodecyl sulfate electrophoresis) respectively. The enzyme is a tetramer consisting of non-identical subunits with molecular weights of 64 000, 56 000, 31 000 and 27 000. It was demonstrated by electrophoretic analyses that in the absence of NiCl2 and at alkaline pH values the native hydrogenase dissociates into two subunit dimers. The first dimer was dark yellow coloured, completely inactive and composed of subunits with molecular weights of 64 000 and 31 000. The second dimer was light yellow, inactive with NAD but still active with methyl viologen. It was composed of subunits with molecular weights of 56 000 and 27 000. Immunological comparison of the hydrogenase of N. opaca 1 b and the soluble hydrogenase of Alcaligenes eutrophus H16 revealed that these two NAD-linked hydrogenases are partially identical proteins.     

Enumeration of free-living aerobic n(2)-fixing h(2)-oxidizing bacteria by using a heterotrophic semisolid medium and most-probable-number technique

A heterotrophic semisolid medium was used with two sensitive assay methods, C(2)H(2) reduction and O(2)-dependent tritium uptake, to determine nitrogenase and hydrogenase activities, respectively. Organisms known to be positive for both activities showed hydrogenase activity in both the presence and absence of 1% C(2)H(2), and thus, it was possible to test a single culture for both activities. Hydrogen uptake activity was detected for the first time in N(2)-fixing strains of Pseudomonas stutzeri. The method was then applied to the most-probable-number method of counting N(2)-fixing and H(2)-oxidizing bacteria in some natural systems. The numbers of H(2)-oxidizing diazotrophs were considerably higher in soil surrounding nodules of white beans than they were in the other systems tested. This observation is consistent with reports that the rhizosphere may be an important ecological niche for H(2) transformation.     

Transport of Ca2+ and Na+ across the chromaffin-granule membrane.

The soluble hydrogenase (hydrogen-NAD+ oxidoreductase, EC 1.12.1.2) of Alcaligenes eutrophus H16 was shown to be stabilized by oxidation with oxygen and ferricyanide as long as electron donors and reducing compounds were absent. The simultaneous presence of H2, NADH and O2 in the enzyme solution, however, caused an irreversible inactivation of hydrogenase that was dependent on the O2 concentration. The half-life periods of 4 degrees C under partial pressures of 0.1, 5, 20 and 50% O2 were 11, 5, 2.5 and 1.5 h respectively. Evidence has been obtained that hydrogenase produces superoxide free radical anions (O2-.), which were detected by their ability to oxidize hydroxylamine to nitrite. The correlation between O2 concentration, nitrite formation and inactivation rates and the stabilization of hydrogenase by addition of superoxide dismutase indicated that superoxide radicals are responsible for enzyme inactivation. During short-term activity measurements (NAD+ reduction, H2 evolution from NADH), hydrogenase activity was inhibited by O2 only very slightly. In the presence of 0.7 mM-O2 an inhibition of about 20% was observed.     

Nitric oxide synthase: irreversible inhibition by L-NG-nitroarginine in brain in vitro and in vivo.

Inhibition of nitric oxide (NO) synthase activity by L-NG-Nitroarginine (NO2Arg) in brain preparations is not reversed by dialysis and is enhanced by prolonged preincubation of NO2Arg with the enzyme. By contrast, the weaker inhibition by NO2Arg of macrophage NO synthase is fully reversible. NO2Arg inhibits NO synthase activity in the brain after i.p. administration of 5 or 50 mg/kg. This in vivo inhibition also appears to be irreversible. The potent in vivo inhibition of central NO synthase by NO2Arg may facilitate studies of the physiologic function of NO as a neuronal messenger.     

Activation and inhibition of microsomal glutathione transferase from mouse liver.

Mouse liver microsomal glutathione transferase was purified in an N-ethylmaleimide-activated as well as an unactivated form. The enzyme had a molecular mass of 17 kDa and a pI of 8.8. It showed cross-reactivity with antibodies raised against rat liver microsomal glutathione transferase, but not with any of the available antisera raised against cytosolic glutathione transferases. The fully N-ethylmaleimide-activated enzyme could be further activated 1.5-fold by inclusion of 1 microM-bromosulphophthalein in the assay system. The latter effect was reversible, which was not the case for the N-ethylmaleimide activation. At 20 microM-bromosulphophthalein the activated microsomal glutathione transferase was strongly inhibited, while the unactivated form was activated 2.5-fold. Inhibitors of the microsomal glutathione transferase from mouse liver showed either about the same I50 values for the activated and the unactivated form of the enzyme, or significantly lower I50 values for the activated form compared with the unactivated form. The low I50 values and the steep slope of the activity-versus-inhibitor-concentration curves for the latter group of inhibitors tested on the activated enzyme indicate a co-operative effect involving conversion of activated enzyme into the unactivated form, as well as conventional inhibition of the enzyme.     

Content and localization of FMN, Fe-S clusters and nickel in the NAD-linked hydrogenase of Nocardia opaca 1b

By preparative polyacrylamide gel electrophoresis at pH 8.5, and in the absence of nickel ions, two types of subunit dimers of the NAD-linked hydrogenase from Nocardia opaca 1b were separated and isolated, and their properties were compared with each other as well as with the properties of the native enzyme. The intact hydrogenase contained 14.3 +/- 0.4 labile sulphur, 13.6 +/- 1.1 iron and 3.8 +/- 0.1 nickel atoms and approximately 1 FMN molecule per enzyme molecule. The oxidized hydrogenase showed an absorption spectrum with maxima (shoulders) at 380 nm and 420 nm and an electron spin resonance (ESR) spectrum with a signal at g = 2.01. The midpoint redox potential of the Fe-S cluster giving rise to this signal was +25 mV. In the reduced state, hydrogenase gave characteristic low-temperature (10-20 K) and high-temperature (greater than 40 K) ESR spectra which were interpreted as due to [4Fe-4S] and [2Fe-2S] clusters, respectively. The midpoint redox potentials of these clusters were determined to be -420 mV and -285 mV, respectively. The large hydrogenase dimer, consisting of subunits with relative molecular masses Mr, of 64000 and 31000, contained 9.9 +/- 0.4 S2- and 9.3 +/- 0.5 iron atoms per protein molecule. This dimer contained the FMN molecule, but no nickel. The absorption and ESR spectra of the large dimer were qualitatively similar to the spectra of the whole enzyme. This dimer did not show any hydrogenase activity, but reduced several electron acceptors with NADH as electron donor (diaphorase activity). The small hydrogenase dimer, consisting of subunits with Mr of 56000 and 27000, was demonstrated to have substantially different properties. For iron and labile sulphur average values of 3.9 and 4.3 atoms/dimer molecule have been determined, respectively. The dimer contained, in addition, about 2 atoms of nickel and was free of flavins. In the oxidized state this dimer showed an absorption spectrum with a broad band in the 400-nm region and a characteristic ESR signal at g = 2.01. The reduced form of the dimer was ESR-silent. The small dimer alone was diaphorase-inactive and did not reduce NAD with H2, but it displayed high H2-uptake activities with viologen dyes, methylene blue and FMN, and H2-evolving activity with reduced methyl viologen. Hydrogen-dependent NAD reduction was fully restored by recombining both subunit dimers, although the reconstituted enzyme differed from the original in its activity towards artificial acceptors and the ESR spectrum in the oxidized state.     

The hoxZ gene of the Azotobacter vinelandii hydrogenase operon is required for activation of hydrogenase.

The roles of the product of the hoxZ gene immediately downstream of the hydrogenase gene (hoxKG) in Azotobacter vinelandii were investigated by constructing and characterizing a mutant with the center of the hoxZ gene deleted. The strain lacking the functional hoxZ gene product exhibited a low rate of H2 oxidation with O2 as the electron acceptor relative to that of the wild-type strain. Nevertheless, when the enzyme was exogenously activated and methylene blue was used as the electron acceptor from hydrogenase, rates of H2 oxidation comparable to those in the wild-type strain were observed. These results suggest that the gene product of hoxZ plays a role in activating and maintaining hydrogenase in a reduced active state. The product of hoxZ could also be the linkage necessary for transfer of electrons from H2 to the electron transport chain.     

Activation of Escherichia coli pyruvate oxidase enhances the oxidation of hydroxyethylthiamin pyrophosphate

The catalytic efficiency (kcat/Km) of Escherichia coli flavin pyruvate oxidase can be stimulated 450-fold either by the addition of lipid activators or by limited proteolytic hydrolysis. Previous studies have shown that a functional lipid binding site is a mandatory prerequisite for the in vivo functioning of this enzyme (Grabau, C., and Cronan, J. E., Jr. (1986) Biochemistry 25, 3748-3751). The effect of activation on the transient state kinetics of partial reactions in the overall oxidative conversion of pyruvate to acetate and CO2 has now been examined. The rate of decarboxylation of pyruvate to form CO2 and hydroxyethylthiamin pyrophosphate for both activated and unactivated forms of the enzyme is identical within experimental error. The decarboxylation step was measured using substrate concentrations of the enzyme in the absence of an electron acceptor. The pseudo-first order rate constant for the decarboxylation step is 60-80 s-1. The rate of oxidation of hydroxyethylthiamin pyrophosphate and concomitant enzyme-bound flavin reduction was analyzed by stopped-flow methods utilizing synthetic hydroxyethylthiamin pyrophosphate. The pseudo-first order rate for this step with unactivated enzyme was 2.85 s-1 and increased 145-fold for lipid-activated enzyme to 413 s-1 and 61-fold for the proteolytically activated enzyme to 173 s-1. The analysis of a third reaction step, the reoxidation of enzyme-bound FADH, was also investigated by stopped-flow techniques utilizing ferricyanide as the electron acceptor. The rate of oxidation of enzyme.FADH is very fast for both unactivated (1041 s-1) and activated enzyme (645 s-1). The data indicate that the FAD reduction step is the rate-limiting step in the overall reaction for unactivated enzyme. Alternatively, the rate-limiting step in the overall reaction with the activated enzyme shifts to one of the partial steps in the decarboxylation reaction.     

Characterization of hydrogenase from the hyperthermophilic archaebacterium, Pyrococcus furiosus

The archaebacterium, Pyrococcus furiosus, grows optimally at 100 degrees C by a fermentative type metabolism in which H2 and CO2 are the only detectable products. The organism also reduces elemental sulfur (S0) to H2S. Cells grown in the absence of S0 contain a single hydrogenase, located in the cytoplasm, which has been purified 350-fold to apparent homogeneity. The yield of H2 evolution activity from reduced methyl viologen at 80 degrees C was 40%. The hydrogenase has a Mr value of 185,000 +/- 15,000 and is composed of three subunits of Mr 46,000 (alpha), 27,000 (beta), and 24,000 (gamma). The enzyme contains 31 +/- 3 g atoms of iron, 24 +/- 4 g atoms of acid-labile sulfide, and 0.98 +/- 0.05 g atoms of nickel/185,000 g of protein. The H2-reduced hydrogenase exhibits an electron paramagnetic resonance (EPR) signal at 70 K typical of a single [2Fe-2S] cluster, while below 15 K, EPR absorption is observed from extremely fast relaxing iron-sulfur clusters. The oxidized enzyme is EPR silent. The hydrogenase is reversibly inhibited by O2 and is remarkably thermostable. Most of its H2 evolution activity is retained after a 1-h incubation at 100 degrees C. Reduced ferredoxin from P. furiosus also acts as an electron donor to the enzyme, and a 350-fold increase in the rate of H2 evolution is observed between 45 and 90 degrees C. The hydrogenase also catalyzes H2 oxidation with methyl viologen or methylene blue as the electron acceptor. The temperature optimum for both H2 oxidation and H2 evolution is greater than 95 degrees C. Arrhenius plots show two transition points at approximately 60 and approximately 80 degrees C independent of the mode of assay. That occurring at 80 degrees C is associated with a dramatic increase in H2 production activity. The enzyme preferentially catalyzes H2 production at all temperatures examined and appears to represent a new type of "evolution" hydrogenase.