Characterization of the hydrogen-deuterium exchange activities of the energy-transducing HupSL hydrogenase and H(2)-signaling HupUV hydrogenase in Rhodobacter capsulatus

Rhodobacter capsulatus synthesizes two homologous protein complexes capable of activating molecular H(2), a membrane-bound [NiFe] hydrogenase (HupSL) linked to the respiratory chain, and an H(2) sensor encoded by the hupUV genes. The activities of hydrogen-deuterium (H-D) exchange catalyzed by the hupSL-encoded and the hupUV-encoded enzymes in the presence of D(2) and H(2)O were studied comparatively. Whereas HupSL is in the membranes, HupUV activity was localized in the soluble cytoplasmic fraction. Since the hydrogenase gene cluster of R. capsulatus contains a gene homologous to hoxH, which encodes the large subunit of NAD-linked tetrameric soluble hydrogenases, the chromosomal hoxH gene was inactivated and hoxH mutants were used to demonstrate the H-D exchange activity of the cytoplasmic HupUV protein complex. The H-D exchange reaction catalyzed by HupSL hydrogenase was maximal at pH 4. 5 and inhibited by acetylene and oxygen, whereas the H-D exchange catalyzed by the HupUV protein complex was insensitive to acetylene and oxygen and did not vary significantly between pH 4 and pH 11. Based on these properties, the product of the accessory hypD gene was shown to be necessary for the synthesis of active HupUV enzyme. The kinetics of HD and H(2) formed in exchange with D(2) by HupUV point to a restricted access of protons and gasses to the active site. Measurement of concentration changes in D(2), HD, and H(2) by mass spectrometry showed that, besides the H-D exchange reaction, HupUV oxidized H(2) with benzyl viologen, produced H(2) with reduced methyl viologen, and demonstrated true hydrogenase activity. Therefore, not only with respect to its H(2) signaling function in the cell, but also to its catalytic properties, the HupUV enzyme represents a distinct class of hydrogenases.     

Aerobic hydrogenase activity in Anacystis nidulans. The oxyhydrogen reaction.

1. The oxyhydrogen reaction of Anacystis nidulans was studied manometrically and polarographically in whole cells and in cell-free preparations; the activity was found to be associated with the particulate fraction. 2. Besides O2, the isolated membranes reduced artificial electron acceptors of positive redox potential; the reactions were unaffected by O2 levels less than 10--15%; aerobically the artificial acceptors were reduced simultaneously with O2. 3. H2-supported O2 uptake was inhibited by CO, KCN and 2-n-heptyl-8-hydroxyquinoline-N-oxide. Inhibition by CO was partly reversed by strong light. Uncouplers stimulated the oxyhydrogen reaction. 4. The kinetic properties of O2 uptake by isolated membranes were the same in presence of H2 and of other respiratory substrates. 5. Low rates of H2 evolution by the membrane preparations were found in presence of dithionite; methyl viologen stimulated the reaction. 6. The results indicate that under certain growth conditions Anacystis synthesizes a membrane-bound hydrogenase which appears to be involved in phosphorylative electron flow from H2 to O2 through the respiratory chain.     

HupUV proteins of Rhodobacter capsulatus can bind H2: evidence from the H-D exchange reaction.

The H-D exchange reaction has been measured with the D2-H2O system, for Rhodobacter capsulatus JP91, which lacks the hupSL-encoded hydrogenase, and R. capsulatus BSE16, which lacks the HupUV proteins. The hupUV gene products, expressed from plasmid pAC206, are shown to catalyze an H-D exchange reaction distinguishable from the H-D exchange due to the membrane-bound, hupSL-encoded hydrogenase. In the presence of O2, the uptake hydrogenase of BSE16 cells catalyzed a rapid uptake and oxidation of H2, D2, and HD present in the system, and its activity (H-D exchange, H2 evolution in presence of reduced methyl viologen [MV+]) depended on the external pH, while the H-D exchange due to HupUV remained insensitive to external pH and O2. These data suggest that the HupSL dimer is periplasmically oriented, while the HupUV proteins are in the cytoplasmic compartment.     

Ferredoxin requirement for electron transport from the carbon monoxide dehydrogenase complex to a membrane-bound hydrogenase in acetate-grown Methanosarcina thermophila

Cell extracts from acetate-grown Methanosarcina thermophila contained CO-oxidizing:H2-evolving activity 16-fold greater than extracts from methanol-grown cells. Following fractionation of cell extracts into soluble and membrane components, CO-dependent H2 evolution and CO-dependent methyl-coenzyme M methylreductase activities were only present in the soluble fraction, but addition of the membrane fraction enhanced both activities. A b-type cytochrome(s), present in the membrane fraction, was linked to a membrane-bound hydrogenase. CO-oxidizing:H2-evolving activity was reconstituted with: (i) CO dehydrogenase complex, (ii) a ferredoxin, and (iii) purified membranes with associated hydrogenase. The ferredoxin was a direct electron acceptor for the CO dehydrogenase complex. The ferredoxin also coupled CO oxidation by CO dehydrogenase complex to metronidazole reduction.     

Partial purification and characterization of the first hydrogenase isolated from a thermophilic sulfate-reducing bacterium.

A soluble [NiFe] hydrogenase has been partially purified from the obligate thermophilic sulfate-reducing bacterium Thermodesulfobacterium mobile. A 17% purification yield was obtained after four chromatographic steps and the hydrogenase presents a purity index (A398 nm/A277 nm) equal to 0.21. This protein appears to be 75% pure on SDS-gel electrophoresis showing two major bands of molecular mass around 55 and 15 kDa. This hydrogenase contains 0.6-0.7 nickel atom and 7-8 iron atoms per mole of enzyme and has a specific activity of 783 in the hydrogen uptake reaction, of 231 in the hydrogen production assay and of 84 in the deuterium-proton exchange reaction. The H2/HD ratio is lower than one in the D2-H+ exchange reaction. The enzyme is very sensitive to NO, relatively little inhibited by CO but unaffected by NO2-. The EPR spectrum of the native hydrogenase shows the presence of a [3Fe-4S] oxidized cluster and of a Ni(III) species.     

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.     

Measurement in vivo of hydrogenase-catalysed hydrogen evolution in the presence of nitrogenase enzyme in cyanobacteria.

A method was devised that allows measurement in vivo of hydrogenase-catalysed H2 evolution from the cyanobacterium Anabaena cylindrica, independent of nitrogenase activity, which is also present. Addition of low concentrations of reduced Methyl Viologen (1-10mM) to intact heterocystous filaments of the organism resulted in H2 evolution, but produced conditions giving total inhibition of nitrogenase (acetylene-reducing and H2-evolving) activity. That the H2 formed under these conditions was not contributed to by nitrogenase was also supported by the observation that its rate of formation was similar in the dark or with Ar replaced by N2 in the gas phase, and also in view of the pattern of H2 evolution at very low Methyl Viologen concentrations. Conclusive evidence that the H2 formed in the presence of Methyl Viologen was solely hydrogenase-mediated was its evolution even from nitrogenase-free (non-heterocystous) cultures; by contrast 'uptake' hydrogenase activity in such cultures was greatly decreased. The hydrogenase activity was inhibited by CO and little affected by acetylene. Finally the hydrogenase activity was shown to be relatively constant at different stages during the batch growth of the organism, as opposed to nitrogenase activity, which varied.     

Sulfhydryl groups of L-asparaginase A from Pseudomonas fluorescens AG]

It has been demonstrated that the activity of asparaginase A from Ps. fluorescens AG is completely inhibited by 10(-4) M p-chloromercurybenzoate and by 70-85% by Zn2+, Ca2+ and Cu2+ (2.10(-2) M). Iodoacetate, iodoacetamide, N-ethylimide of maleic acid and 5,5'-dithiobis-(2-nitrobenzoic acid) do not decrease the enzyme activity. Dithiothreitol and beta-mercaptoethanol reactivate the enzyme. L-asparagine, the substrate of asparaginase, protects the enzyme in a large degree against the inhibitory action of p-chloromercurybenzoate. p-chloromercurybenzoate induces a sharp increase in the asparaginase inactivation rate at acidic (6.5--5.5) and alkaline (7.5-8.5) values of pH. The enzyme modification by p-chloromercurybenzoate does not change the Km value for L-asparagine, but decreases Vmax. Thus it may be assumed, that asparaginase from Ps. fluorescens AG contains sulfhydryl groups essential for the enzyme activity.     

Continuous monitoring, by mass spectrometry, of H2 production and recycling in Rhodopseudomonas capsulata.

Hydrogen evolution and consumption by cell and chromatophore suspensions of the photosynthetic bacterium Rhodopseudomonas capsulata was measured with a sensitive and specific mass spectrometric technique which directly monitors dissolved gases. H2 production by nitrogenase was inhibited by acetylene and restored by carbon monoxide. An H2 evolution activity coupled with HD formation and D2 uptake (H-D exchange) was unaffected by C2H2 and CO. Cultures lacking nitrogenase activity also exhibited H-D exchange activity, which was catalyzed by a membrane-bound hydrogenase present in the chromatophores of R. capsulata. A net hydrogen uptake, mediated by hydrogenase, was observed when electron acceptors such as CO2, O2, or ferricyanide were present in the medium.     

Characterization of catalytic properties of hydrogenase isolated from the unicellular cyanobacterium Gloeocapsa alpicola CALU 743

The main catalytic properties of the Hox type hydrogenase isolated from the Gloeocapsa alpicola cells have been studied. The enzyme effectively catalyzes reactions of oxidation and evolution of H2 in the presence of methyl viologen (MV) and benzyl viologen (BV). The rates of these reactions in the interaction with the physiological electron donor/acceptor NADH/NAD+ are only 3-8% of the MV(BV)-dependent values. The enzyme interacts with NADP+ and NADPH, but is more specific to NAD+ and NADH. Purification of the hydrogenase was accompanied by destruction of its multimeric structure and the loss of ability to interact with pyridine nucleotides with retained activity of the hydrogenase component (HoxYH). To show the catalytic activity, the enzyme requires reductive activation, which occurs in the presence of H2, and NADH accelerates this process. The final hydrogenase activity depends on the redox potential of the activation medium (E(h)). At pH 7.0, the enzyme activity in the MV-dependent oxidation of H2 increased with a decrease in E(h) from -350 mV and reached the maximum at E(h) of about -390 mV. However, the rate of H2 oxidation in the presence of NAD+ in the E(h) range under study was virtually constant and equal to 7-8% of the maximal rate of H2 oxidation in the presence of MV.     

Appearance of a reversible hydrogenase activity in Anabaena cylindrica grown in high light

In vivo H₂ evolution by Anabaena cylindrica Lemm. strain PCC 7122 grown in the presence of ammonia at low and high light intensities was studied. We found that after 2 h of anaerobic incubation, H₂ evolution [at a rate of 0.5 μmol (mg dry weight)¹ h⁻¹] via reversible hydrogenase occurred in high light grown cells, while this kind of activity was not found in low light grown cells. H₂ evolution was inhibited by 3-(3'. 4'-dichlorophenyl-1, 1-dimethylurea (DCMU). Illuminating the cells in the phycocyanin absorption region resulted in a higher rate of H₂ evolution than illuminating the cells in the chlorophyll absorption region. The results indicate that reversible hydrogenase receives reducing equivalents from photosynthetic water photolysis and that both photosystem II and photosystem I participate in the H₂ production. Hydrogenase activity was found in the soluble fraction after mild sonication in the case of low light grown cells. After this treatment high light grown cells retained 70% of their hydrogenase activity in the particulate fraction, but released it into the soluble fraction in the presence of 2% deoxycholic acid.
In vitro H₂ evolution did not differ significantly in the low and high light grown cells. Hence, the differences in the in vivo H₂ evolution reflect the different availability of endogenous reductants for hydrogenase in the two kinds of cells. On the basis of our results it is suggested that high light grown Anabaena cells eliminate part of the photosynthetically produced excess electrons via an induced reversible hydrogenase activity. This is the first report of H₂ evolution associated with water photolysis and catalyzed by hydrogenase in cyanobacteria.     

Hydrogenase activity of the methylotroph, Pseudomonas methylica]

The cells of Pseudomonas methylica, strain 2, cultivated in a medium containing methanol, displayed the activity of hydrogenase in the exchange reaction (D2--H2O) and in the absorption of H2 in the presence of methylviologen, azocarmine, methylene blue, and ferricyanide. The rate of H2 utilization was highest in the presence of methylviologen. Cell extracts absorb H2 in the presence of methylviologen, NAD, and NADP, but much faster in the presence of flavin mononucleotide. The bulk of the hydrogenase remains, during centrifugation of the initial cell extract (3,000 g), in the soluble fraction (144,000 g). The absorption of oxygen by the cell suspensions and the incorporation of 14C of formiate into the cells are stimulated by H2. The cells, however, cannot grow in the autotrophic conditions at the account of molecular hydrogen and CO2.     

Comparison of the membrane-bound hydrogenases from Alcaligenes eutrophus H16 and Alcaligenes eutrophus type strain

Whereas the membrane-bound hydrogenase from Alcaligenes eutrophus H16 is an integral membrane protein and can only be solubilized by detergent treatment, the membrane-bound hydrogenase of Alcaligenes eutrophus type strain was found to be present in a soluble form after cell disruption. For the enzyme of A. eutrophus H16 a new, highly effective purification procedure was developed including phase separation with Triton X-114 and triazine dye chromatography on Procion Blue H-ERD-Sepharose. The purification led to an homogeneous hydrogenase preparation with a specific activity of 269 U/mg protein (methylene blue reduction) and a yield of 45%. During purification and storage the enzyme was optimally stabilized by the presence of 0.2 mM MnCl2. The hydrogenase of A. eutrophus type strain was purified from the soluble extract by a similar procedure, however, with less specific activity and activity yield. Comparison of the two purified enzymes revealed no significant differences: They have the same molecular weight, both consist of two different subunits (Mr = 62,000, 31,000) and both have an isoelectric point near pH 7.0. They have the same electron acceptor specificity reacting with similar high rates and similar Km values. The acceptors reduced include viologen dyes, flavins, quinones, cytochrome c, methylene blue, 2,6-dichlorophenolindophenol, phenazine methosulfate and ferricyanide. Ubiquinones and NAD were not reduced. The two hydrogenases were shown to be immunologically identical and both have identical electrophoretic mobility. For the membrane-bound hydrogenase of A. eutrophus H16 it was demonstrated that this type of hydrogenase in its solubilized, purified state is able to catalyze also the reverse reaction, the H2 evolution from reduced methyl viologen.     

Activation of soluble guanylate cyclase from rat lung by incubation or by hydrogen peroxide.

A 37,000 X g supernatant fraction prepared from fat lung homogenate demonstrated a 2- to 3-fold increase in guanylate cyclase activity after incubation at 30 degrees for 30 min (preincubation). Treatment of the supernatant fraction with Triton X-100 increased activity to approximately the same extent as preincubation, but would not increase the activity after preincubation. By chromatography on Sepharose 2B, before and after preincubation, it was demonstrated that the increase in activity was only associated with the soluble guanylate cyclase, and not the particulate enzyme. Activation by preincubation required O2. It was completely inhibited by thiols such as 2-mercaptoethanol, and by bovine serum albumin, KCN, and sodium diethyldithiocarbamate. These inhibitors suggested a copper requirement for activation, and this was confirmed by demonstrating that 20 to 60 muM CuCl2 could relieve the inhibition by 0.1 mM sodium diethyldithiocarbamate. 2-Mercaptoethanol inhibition could also be reversed by removal of the thiol on a Sephadex G-25 column, however, this treatment partially activated the enzyme. Addition of 2-mercaptoethanol to a preincubated preparation would not reverse the activation. H2O2 was found to activate guanylate cyclase, either by its generation in the lung supernatant with glucose oxidase and glucose, or by its addition to a preparation in which the catalase was inhibited with KCN. KCN or bovine serum albumin was able to partially inhibit activation by glucose oxidase plus glucose, however, larger amounts of glucose oxidase could overcome that inhibition, indicating a catalytic role for Cu2+ at low H2O2 concentrations. No direct evidence for H2O2 formation during preincubation could be found, however, indirect evidence was obtained by the spectrophotometric detection of choleglobin formation from hemoglobin present in the lung supernatant fluid. The H2O2 is believed to result from the reaction of oxyhemoglobin with ascorbate.     

Hydrogenase activity of Rhodopseudomonas capsulata growing on organic media

When Rhodopseudomonas capsulata B10 grows in media with different organic compounds, the hydrogenase activity estimated both by the evolution and uptake of H2 is lowest in cells taken from the middle of the exponential growth phase, and highest in cells from the beginning of the stationary phase. Cells grown in a medium containing malate have a higher hydrogenase activity than those cultivated in a medium with lactate or other compounds (900 and 20 nmoles of H2 per 1 min per 1 mg of protein, respectively). In the experiments with chloramphenicol (10(-5) M), organic compounds (not CO2) were shown to repress hydrogenase synthesis. When the cells were incubated in a medium without an organic substrate or in its presence, the exogenous H2 or H2 evolved as the result of nitrogenase action causes an increase in the activity of hydrogenase.     

Linoleic acid isomerase in Lactobacillus plantarum AKU1009a proved to be a multi-component enzyme system requiring oxidoreduction cofactors

Linoleic acid isomerase in Lactobacillus plantarum was found to be a novel multi-component enzyme system widespread in membrane and soluble fractions. The isomerization reaction involved a hydration step, 10-hydroxy-12-octadecenoic acid production from linoleic acid, as part of the reaction, and the hydration reaction was catalyzed by the membrane fraction. Both membrane and soluble fractions were required for the whole isomerization reaction, i.e., conjugated linoleic acid (CLA) production from linoleic acid, and for CLA production from 10-hydroxy-12-octadecenoic acid, a reaction intermediate. The multi-component enzyme system was inhibited by o-phenanthroline, and divalent metal ions such as Ni(2+) and Co(2+) restored activity. Metal oxides such as VO(4)(3+), MoO(4)(2+), and MnO(4)(2+) enhanced activity. The multi-component enzyme systems required oxidoreduction cofactors such as NADH together with FAD or NADPH for total activity.     

Purification and properties of hydrogenase from phototrophic bacterium Thiocapsa roseopersicina]

The isolation method and some peoperties of purple sulphur bacteria (Thiocapsa roseopersicina strain BBS) hydrogenase are described Hydrogenase molecular weight is found to be 66000; it contains 3.7 moles of S2- and 3.9 moles of Fe2+ per one mole of the enzyme;pI=4.2. The enzyme absorption spectrum has the maximum at 400-412 nm which is characteristic of proteins containing non-haem iron. Hydrogenase is suggested to consist pf 4 subunits of two types: with molar weight 27000 and 6000. Unlike other hydrogenases, this enzyme is rather resistant to O2 and is more thermostable: the inactivation of the enzyme was observed at the temperature above 80 degrees C; Hydrogenase preparation catalyses D2-H2O exchange reaction, H2 evolution from the reduced methyl viologene (MV) and H2 absorption in the presense of MV or benzylviologene but not in the presense of NAD(P), FAD, FMN, azocarmine, methylene blue and ferricyanide.     

Substitution of Azotobacter vinelandii hydrogenase small-subunit cysteines by serines can create insensitivity to inhibition by O2 and preferentially damages H2 oxidation over H2 evolution.

Mutants in which conserved cysteines 294, 297 or 64 and 65 of the Azotobacter vinelandii hydrogenase small subunit were replaced by serines were studied. Cysteines 294 and 297 are homologous to cysteines 246 and 249 of the Desulfovibrio gigas hydrogenase, and these cysteines are ligands to the [3Fe-4S] clusters (A. Volbeda, M.-H. Charon, C. Piras, E. C. Hatchikian, M. Frey, and J. C. Fontecilla-Camps, Nature (London) 373:580-587, 1995). Cysteine 65 is homologous to cysteine 20 of the D. gigas hydrogenase, and this cysteine is a ligand to the proximal [4Fe-4S] cluster. All three mutants retained some hydrogenase activity. All three mutants studied had H2 oxidation-to-H2 evolution activity ratios with whole cells of approximately 1.5, compared with 46 for the wild type. The changes preferentially deplete H2 oxidation activity, while having less effect on evolution. The K64,65C-->S hydrogenase was partially purified and had a specific activity for the evolution reaction that was 22% that of the wild type, while the oxidation-specific activity was 2% that of the wild type. Because cysteine 65 provides a ligand to the proximal [4Fe-4S] cluster, this cluster can be altered without entirely eliminating enzyme activity. Likewise, the detection of H2 evolution and H2 oxidation activities with whole cells and membranes of the K294C-->S and K297C-->S mutants indicates that the [3Fe-4S] cluster can also be altered or possibly eliminated without entirely eliminating enzyme activity. Membranes with K294C-->S or K297C-->S hydrogenase were uninhibited by O2 in H2 oxidation and uninhibited by H2 in H2 evolution. Wild-type membranes and membranes with K64,65C-->S hydrogenase were both sensitive to these inhibitors. These data indicate that the [3Fe-4S] cluster controls the reversible inhibition of hydrogenase activity by O2 or H2.     

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.     

The pH dependence of proton-deuterium exchange, hydrogen production and uptake catalyzed by hydrogenases from sulfate-reducing bacteria

Different patterns have been found in the pH dependence of hydrogenase activity with enzymes purified from different species of Desulfovibrio. With the cytoplasmic hydrogenase from Desulfovibrio baculatus strain 9974, the pH optima in H2 production and uptake were respectively 4.0 and 7.5 with a higher activity in production than in uptake. The highest D2-H+ exchange activity was found also at pH 4.0 but the optima differed for the HD and the H2 components. Both similarly rose when the pH decreased from 9.0 to 4.5, but the rate of H2 evolution slowed whereas the HD evolution continued rising till pH values around 3.0 were reached. The H2 to HD ratio at pH above 4.5 was higher than one. With the periplasmic hydrogenase from Desulfovibrio vulgaris Hildenborough, the highest exchange activity was near pH 5.5, the same value as in hydrogen production. The periplasmic hydrogenase from Desulfovibrio gigas had in contrast the same pH optimum in the exchange (7.5-8.0) as in the H2 uptake. The ratio of H2 to HD was below one for both enzymes. These different patterns may be related to functional and structural differences in the three hydrogenases so far studied, particularly in the composition of their catalytic centers.