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.     

Cyanide inactivation of hydrogenase from Azotobacter vinelandii.

The effects of cyanide on membrane-associated and purified hydrogenase from Azotobacter vinelandii were characterized. Inactivation of hydrogenase by cyanide was dependent on the activity (oxidation) state of the enzyme. Active (reduced) hydrogenase showed no inactivation when treated with cyanide over several hours. Treatment of reversibly inactive (oxidized) states of both membrane-associated and purified hydrogenase, however, resulted in a time-dependent, irreversible loss of hydrogenase activity. The rate of cyanide inactivation was dependent on the cyanide concentration and was an apparent first-order process for purified enzyme (bimolecular rate constant, 23.1 M-1 min-1 for CN-). The rate of inactivation decreased with decreasing pH. [14C]cyanide remained associated with cyanide-inactivated hydrogenase after gel filtration chromatography, with a stoichiometry of 1.7 mol of cyanide bound per mol of inactive enzyme. The presence of saturating concentrations of CO had no effect on the rate or extent of cyanide inactivation of hydrogenases. The results indicate that cyanide can cause a time-dependent, irreversible inactivation of hydrogenase in the oxidized, activatable state but has no effect when hydrogenase is in the reduced, active state.     

Aerobically purified hydrogenase from Azotobacter vinelandii: activity, activation, and spectral properties

The hydrogenase from Azotobacter vinelandii is typically purified under anaerobic conditions. In this work, the hydrogenase was purified aerobically. The yields were low (about 2%) relative to those of the anaerobic purification (about 20%). The rate of enzyme activity depended upon the history of the enzyme. The enzyme preparations were active as isolated in H2 oxidation, and isotope exchange. The activity increased during the assay to a new maximal level (turnover activation). Treatment with reductants (e.g., H2, dithionite, dithiothreitol, indigo carmine) resulted in greater activation (reductant activation). Activation of the hydrogenase was accompanied by decrease in visible light absorption (300-600 nm) with maximal decreases at 450 and 345 nm which indicated the reduction of iron-sulfur clusters. The aerobically purified hydrogenase was susceptible to irreversible inactivation by cyanide. Pretreatment with acetylene did not influence activation of the hydrogenase. Once activated, the aerobically purified hydrogenase was indistinguishable from the anaerobically purified hydrogenase with respect to the catalytic properties tested.     

Purification and properties of the soluble hydrogenase from Desulfovibrio desulfuricans (strain Norway 4)

A soluble hydrogenase has been isolated from Desulfovibrio desulfuricans (strain Norway 4) grown on Postgate's medium. The enzyme differs significantly from a membrane-bound hydrogenase previously purified from the same organism grown on Starkey's medium. The enzyme consisted of two subunits of 56 kDa and 29 kDa compared with masses of 60 kDa and 27 kDa for the membrane-bound enzyme. Analysis of preparations of the soluble enzyme by various methods gave values of 5-10 iron atoms, 6 labile sulphur atoms and 0.45-0.8 nickel atom per molecule. The enzyme was unusual in that it contained selenium, in quantities equivalent to nickel. The highly purified active enzyme produced no electron-spin-resonance (ESR) signals in the oxidized state. ESR signals due to a [3Fe-xS] cluster and nickel were observed only in some of the less active fractions of the enzyme, demonstrating that neither of these ESR-detectable components is a prerequisite for hydrogenase activity. Treatment of D. desulfuricans (Norway) cells with EDTA released a minor fraction with hydrogenase activity, which might indicate the presence of a periplasmic enzyme.     

Nickel in the catalytically active hydrogenase of Alcaligenes eutrophus.

Nickel is a constituent of soluble and particulate hydrogenase of Alcaligenes eutrophus. Incorporation of 63Ni2+ revealed that almost the total nickel taken up by the cells was bound to the protein. Chromatography of a crude extract on diethylaminoethyl cellulose demonstrated an association of 63Ni2+ with soluble and particulate hydrogenase, supported by further analysis like polyacrylamide gel electrophoresis. Unspecific binding of 63Ni2+ to the protein was excluded by comparison with a mutant extract free of hydrogenase protein. X-ray fluorescence analysis of the homogeneous soluble hydrogenase indicated the presence of 2 mol of nickel per mol of enzyme, whereas the amount of nickel determined by incorporation of 63Ni2+ was calculated to be approximately 1 mol/mol of enzyme. Cells grown under nickel limitation contained catalytically inactive, but serologically active, soluble and particulate hydrogenase. The immunochemical reactions were only partially identical with the enzyme from nickel-cultivated cells indicating a structural modification of the proteins in the absence of nickel. It is concluded that nickel is essential for the catalytic activity of hydrogenase and not involved as a regulatory component in the synthesis of this enzyme.     

Regulation of hydrogenase in Rhizobium japonicum.

Factors that regulate the expression of an H2 uptake system in free-living cultures of Rhizobium japonicum have been investigated. Rapid rates of H2 uptake by R. japonicum were obtained by incubation of cell suspensions in a Mg-phosphate buffer under a gas phase of 86.7% N2, 8.3% H2, 4.2% CO2, and 0.8% O2. Cultures incubated under conditions comparable with those above, with the exception that Ar replaced H2, showed no hydrogenase activity. When H2 was removed after initiation of hydrogenase derepression, further increase in hydrogenase activity ceased. Nitrogenase activity was not essential for expression of hydrogenase activity. All usable carbon substrates tested repressed hydrogenase formation, but none of them inhibited hydrogenase activity. No effect on hydrogenase formation was observed from the addition of KNO3 or NH4Cl at 10 mM. Oxygen repressed hydrogenase formation, but did not inhibit activity of the enzyme in whole cells. The addition of rifampin or chloramphenicol to derepressed cultures resulted in inhibition of enzyme formation similar to that observed by O2 repression. The removal of CO2 during derepression caused a decrease in the rate of hydrogenase formation. No direct effect of CO2 on hydrogenase activity was observed.     

The presence of a SO molecule in [NiFe] hydrogenase from Desulfovibrio vulgaris Miyazaki as detected by mass spectrometry

The active site of [NiFe] hydrogenase is a binuclear metal complex composed of Fe and Ni atoms and is called the Ni–Fe site, where the Fe atom is known to be coordinated to three diatomic ligands. Two mass spectrometric techniques, pyrolysis-MS (pyrolysis-mass spectrometry) and TOF-SIMS (time-of-flight secondary ion mass spectrometry), were applied to several proteins, including native and denatured forms of [NiFe] hydrogenase from Desulfovibrio vulgaris Miyazaki F, [Fe₄S₄]₂-ferredoxin from Clostridium pasteurianum, [Fe₂S₂]-ferredoxin from Spirulina platensis, and porcine pepsin. Pyrolysis-MS revealed that only native hydrogenase liberated SO/SO₂ (ions of m/z 48 and 64 at an equilibrium ratio of SO and SO₂) at relatively low temperatures before the covalent bonds in the polypeptide moiety started to decompose. TOF-SIMS indicated that native Miyazaki hydrogenase released SO/SO₂ (m/z 47.97 and 63.96) as secondary ions when irradiated with a high-energy Ga⁺ beam. Denatured hydrogenase, clostridial ferredoxin, and pepsin did not release SO as a secondary ion. The FT-IR spectrum of the enzyme suggested the presence of CO and CN. These lines of evidence suggest that the three diatomic ligands coordinated to the Fe atom at the Ni–Fe site in Miyazaki hydrogenase are SO, CO, and CN. The role of the SO ligand in helping to cleave H₂ molecules at the active site and stabilizing the Fe atom in the diamagnetic Fe(II) state in the redox cycle of this enzyme is discussed.     

Purification and properties of soluble hydrogenase from Alcaligenes eutrophus H 16.

The soluble hydrogenase (hydrogen: NAD+ oxidoreductase, EC 1.12.1.2) from Alcaligenes eutrophus H 16 was purified 68-fold with a yield of 20% and a final specific activity (NAD reduction) of about 54 mumol H2 oxidized/min per mg protein. The enzyme was shown to be homogenous by polyacrylamide gel electrophoresis. Its molecular weight and isoelectric point were determined to be 205 000 and 4.85 respectively. The oxidized hydrogenase, as purified under aerobic conditions, was of high stability but not reactive. Reductive activation of the enzyme by H2, in the presence of catalytic amounts of NADH, or by reducing agents caused the hydrogenase to become unstable. The purified enzyme, in its active state, was able to reduce NAD, FMN, FAD, menaquinone, ubiquinone, cytochrome c, methylene blue, methyl viologen, benzyl viologen, phenazine methosulfate, janus green, 2,6-dichlorophenoloindophenol, ferricyanide and even oxygen. In addition to hydrogenase activitiy, the enzyme exhibited also diaphorase and NAD(P)H oxidase activity. The reversibility of hydrogenase function (i.e. H2 evolution from NADH, methyl viologen and benzyl viologen) was demonstrated. With respect to H2 as substrate, hydrogenase showed negative cooperativity; the Hill coefficient was n = 0.4. The apparent Km value for H2 was found to be 0.037 mM. The absorption spectrum of hydrogenase was typical for non-heme iron proteins, showing maxima (shoulders) at 380 and 420 nm. A flavin component could be extracted from native hydrogenase characterized by its absorption bands at 375 and 447 nm and a strong fluorescense at 526 nm.     

Purification and catalytic properties of Ech hydrogenase from Methanosarcina barkeri.

Methanosarcina barkeri has recently been shown to produce a multisubunit membrane-bound [NiFe] hydrogenase designated Ech (Escherichia coli hydrogenase 3) hydrogenase. In the present study Ech hydrogenase was purified to apparent homogeneity in a high yield. The enzyme preparation obtained only contained the six polypeptides which had previously been shown to be encoded by the ech operon. The purified enzyme was found to contain 0.9 mol of Ni, 11.3 mol of nonheme-iron and 10.8 mol of acid-labile sulfur per mol of enzyme. Using the purified enzyme the kinetic parameters were determined. The enzyme catalyzed the H2 dependent reduction of a M. barkeri 2[4Fe-4S] ferredoxin with a specific activity of 50 U x mg protein-1 at pH 7.0 and exhibited an apparent Km for the ferredoxin of 1 microM. The enzyme also catalyzed hydrogen formation with the reduced ferredoxin as electron donor at a rate of 90 U x mg protein-1 at pH 7.0. The apparent Km for the reduced ferredoxin was 7.5 microM. Reduction or oxidation of the ferredoxin proceeded at similar rates as the reduction or oxidation of oxidized or reduced methylviologen, respectively. The apparent Km for H2 was 5 microM. The kinetic data strongly indicate that the ferredoxin is the physiological electron donor or acceptor of Ech hydrogenase. Ech hydrogenase amounts to about 3% of the total cell protein in acetate-grown, methanol-grown or H2/CO2-grown cells of M. barkeri, as calculated from quantitative Western blot experiments. The function of Ech hydrogenase is ascribed to ferredoxin-linked H2 production coupled to the oxidation of the carbonyl-group of acetyl-CoA to CO2 during growth on acetate, and to ferredoxin-linked H2 uptake coupled to the reduction of CO2 to the redox state of CO during growth on H2/CO2 or methanol.     

The membrane-bound hydrogenase from Paracoccus denitrificans. Purification and molecular characterization

The membrane-bound hydrogenase from Paracoccus denitrificans was purified 68-fold with a yield of 14.6%. The final preparation had a specific activity of 161.9 mumol H2 min-1 (mg protein)-1 (methylene blue reduction). Purification involved solubilization by Triton X-114, phase separation, chromatography on DEAE-Sephacel, ammonium-sulfate precipitation and chromatography on Procion-red HE-3B-Sepharose. Gel electrophoresis under denaturing conditions revealed two non-identical subunits with molecular masses of 64 kDa and 34 kDa. The molecular mass of the native enzyme was 100 kDa, as estimated by FPLC gel filtration in the presence of Chaps, a zwitterionic detergent. The isoelectric point of the Paracoccus hydrogenase was 4.3. Metal analysis of the purified enzyme indicated a content of 0.6 nickel and 7.3 iron atoms/molecule. ESR spectra of the reduced enzyme exhibited a close similarity to the membrane-bound hydrogenase from Alcaligenes eutrophus H16 with g values of 1.86, 1.92 and 1.98. The half-life for inactivation under air at 20 degrees C was 8 h. The Paracoccus hydrogenase reduced several electron acceptors, namely methylene blue, benzyl viologen, methyl viologen, menadione, cytochrome c, FMN, 2,6-dichloroindophenol, ferricyanide and phenazine methosulfate. The highest activity was measured with methylene blue (V = 161.9 U/mg; Km = 0.04 mM), whereas benzyl and methyl viologen were reduced at distinctly lower rates (16.5 U/mg and 12.1 U/mg, respectively). The native hydrogenase from P. denitrificans cross-reacted with purified antibodies raised against the membrane-bound hydrogenase from A. eutrophus H16. The corresponding subunits from both enzymes also showed immunological relationship. All reactions were of partial identity.     

Structural and catalytic properties of hydrogenase from Chromatium.

The enzyme hydrogenase, from the photosynthetic bacterium Chromatium, was purified to homogeneity after solubilization of the particulate enzyme with deoxycholate. The purification procedure included ammonium sulfate fractionation, treatment with manganous phosphate gel, heating at 63 degrees, DEAE-cellulose chromatography, and isoelectric focusing. The last step gave two active enzyme fractions with isoelectric points of 4.2 and 4.4. It was shown that the two fractions were different forms of the same protein. The enzyme was obtained in 23% yield and was purified 1700-fold. The enzyme had a molecular weight of 98,000, a sedimentation coefficient of 5.16 S and gave a single protein and activity band on disc gel electrophoresis. Sodium dodecyl sulfate gel electrophoresis gave a single band of mol wt 50,000, suggesting that the active enzyme was composed of two subunits of the same molecular weight. The pure hydrogenase contained four atoms of iron and four atoms of acid-labile sulfide, and had a visible absorption peak at 410 nm. Electron paramagnetic resonance (EPR) spectroscopy at 10--15 K showed a free-radical signal at g' = 2.003 in the oxidized enzyme and signals at g' = 2.2 and 2.06 in the reduced enzyme. These findings suggest that Chromatium hydrogenase is an iron-sulfur protein. The pure hydrogenase catalyzed the exchange reaction between H2 and HDO or HTO, the reduction of Benzyl Viologen and Methylene Blue, and the evolution of hydrogen from reduced Methyl Viologen. The mechanism of hydrogen activation was shown to be heterolytic cleavage to an enzyme hydride and a proton. Hydrogenase could not catalyze reduction of pyridine nucleotides or ferredoxin with H2. The effect of pH and various inhibitors on the enzymatic activity has been studied.     

Comparison of the properties of two hydrogenases from the photosynthetic bacterium Chromatium vinosum

Chromatium vinosum hydrogenases I and II were purified to specific activities of 9.6 and 28.0 units/mg protein, respectively. They have the same isoelectric point (pI = 4.1), and their visible spectra are typical of iron-sulfur proteins. Hydrogenase II in general was more stable than hydrogenase I. Both enzymes lost their activities slowly during storage in air, and this inactivation was more apparent in preparations of hydrogenase I. Bovine serum albumin helped to stabilize hydrogenase I against thermal and storage inactivation. The pH optima of H2-evolution activity of hydrogenases I and II were 7.4 and 5.4, respectively. Neither enzyme was able to evolve H2 from reduced ferredoxins as the sole electron carrier, but ferredoxins had an effect on the activity with methyl viologen as carrier to hydrogenase I. None of the natural compounds tested was able to serve as a physiological donor for H2 production. Hydrogenase I was more susceptible than hydrogenase II to inhibition by heavy metal ions and other enzyme inhibitors. Both enzymes were reversibly inhibited by CO with Ki values of 12 and 6 Torr for hydrogenase I and II, respectively. Hydrogenase I was more sensitive to denaturation by urea and guanidinium chloride while hydrogenase II was more susceptible to sodium dodecyl sulfate. Both enzymes were rapidly and irreversibly inactivated by dimethyl sulfoxide. Hydrogenase I evolved H2 from methyl viologen and ferredoxin photoreduced by chloroplasts. The enzymes differed in their iron and acid-labile sulfur contents.     

Purification and characterization of putative alkaline [Ni-Fe] hydrogenase from unicellular marine green alga, Tetraselmis kochinensis NCIM 1605

Hydrogenase enzyme from the unicellular marine green alga Tetraselmis kochinensis NCIM 1605 was purified 467 fold to homogeneity. The molecular weight was estimated to be approximately 89kDa by SDS-PAGE. This enzyme consists of two subunits with molecular masses of approximately 70 and approximately 19kDa. The hydrogenase was found to contain 10g atoms of Fe and 1g of atom of Ni per mole of protein. The specific activity of hydrogen evolution was 50micromol H(2)/mg/h of enzyme using reduced methyl viologen as an electron donor. This hydrogenase enzyme has pI value approximately 9.6 representing its alkaline nature. The absorption spectrum of the hydrogenase enzyme showed an absorption peak at 425nm indicating that the enzyme had iron-sulfur clusters. The total of 16 cysteine residues were found per mole of enzyme under the denaturing condition and 20 cysteine residues in reduced denatured enzyme indicating that it has two disulfide bridges.     

Reduction of the amount of periplasmic hydrogenase in Desulfovibrio vulgaris (Hildenborough) with antisense RNA: direct evidence for an important role of this hydrogenase in lactate metabolism.

To establish the function of the periplasmic Fe-only hydrogenase in the anaerobic sulfate reducer Desulfovibrio vulgaris (Hildenborough), derivatives with a reduced content of this enzyme were constructed by introduction of a plasmid that directs the synthesis of antisense RNA complementary to hydrogenase mRNA. It was demonstrated that the antisense RNA technique allowed specific suppression of the synthesis of this hydrogenase in D. vulgaris by decreasing the amount of hydrogenase mRNA but did not result in the complete elimination of the enzyme, as is usual with most conventional mutagenesis techniques. The hydrogenase content in these antisense RNA-producing D. vulgaris clones was two- to threefold lower than in the parental strain when the strains were grown in batch cultures with lactate as a substrate and sulfate as a terminal electron acceptor. Under these conditions, several differences in growth parameters were measured between the hydrogenase-suppressed clones and wild-type D. vulgaris: growth rates of the clones decreased two- to threefold, and at excess lactate, growth yields were reduced by 20%. Furthermore, the amount of hydrogen measured in the culture headspaces was reduced three- to fivefold for the clones. These observations indicate that this hydrogenase has an important function during growth on lactate and is involved in hydrogen production from protons and electrons originating from at least one of the two oxidation reactions in the conversion of lactate to acetate. The implications for the energy metabolism of D. vulgaris are discussed.     

Structural aspects and immunolocalization of the F420-reducing and non-F420-reducing hydrogenases from Methanobacterium thermoautotrophicum Marburg.

The F420-reducing hydrogenase and the non-F420-reducing hydrogenase (EC 1.12.99.1.) were isolated from a crude extract of Methanobacterium thermoautotrophicum Marburg. Electron microscopy of the negatively stained F420-reducing hydrogenase revealed that the enzyme is a complex with a diameter of 15.6 nm. It consists of two ring-like, stacked, parallel layers each composed of three major protein masses arranged in rotational symmetry. Each of these masses appeared to be subdivided into smaller protein masses. Electron microscopy of negatively stained samples taken from intermediate steps of the purification process revealed the presence of enzyme particles bound to inside-out membrane vesicles. Linker particles of 10 to 20 kDa which mediate the attachment of the hydrogenase to the cytoplasmic membrane were seen. Immunogold labelling confirmed that the F420-reducing hydrogenase is a membrane-bound enzyme. Electron microscopy of the negatively stained purified non-F420-reducing hydrogenase revealed that the enzyme is composed of three subunits exhibiting different diameters (5, 4, and 2 to 3 nm). According to immunogold labelling experiments, approximately 70% of the non-F420-reducing hydrogenase protein molecules were located at the cell periphery; the remaining 30% were cytoplasmic. No linker particles were observed for this enzyme.     

Effect of enzyme concentration on apparent specific activity of hydrogenase

The effect of enzyme concentration on the H2-uptake and H2-evolving activities of the reversible hydrogenase from Thiocapsa roseopersicina was examined. In the activity range assayed by a spectrophotometric technique the apparent H2-uptake specific activity varied greatly with hydrogenase concentration. Study of H2-evolving activity measured by the H2 electrode method and compared with a gas chromatographic assay also indicated that specific activity was highly dependent on enzyme concentration. The results indicate that the widely applied hydrogenase assays give systematically erroneous specific activity values. These assays should be used only for relative measurements and the hydrogenase concentration in the reaction mixture should be kept constant. To make the data from various laboratories comparable the assay parameters should be standardized.     

Purification and characterization of the hydrogen uptake hydrogenase from the hyperthermophilic archaebacterium Pyrodictium brockii.

Pyrodictium brockii is a hyperthermophilic archaebacterium with an optimal growth temperature of 105 degrees C. P. brockii is also a chemolithotroph, requiring H2 and CO2 for growth. We have purified the hydrogen uptake hydrogenase from membranes of P. brockii by reactive red affinity chromatography and sucrose gradient centrifugation. The molecular mass of the holoenzyme was 118,000 +/- 19,000 Da in sucrose gradients. The holoenzyme consisted of two subunits by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The large subunit had a molecular mass of 66,000 Da, and the small subunit had a molecular mass of 45,000 Da. Colorometric analysis of Fe and S content in reactive red-purified hydrogenase revealed 8.7 +/- 0.6 mol of Fe and 6.2 +/- 1.2 mol of S per mol of hydrogenase. Growth of cells in 63NiCl2 resulted in label incorporation into reactive red-purified hydrogenase. Growth of cells in 63NiCl2 resulted in label incorporation into reactive red-purified hydrogenase. Temperature stability studies indicated that the membrane-bound form of the enzyme was more stable than the solubilized purified form over a period of minutes with respect to temperature. However, the membranes were not able to protect the enzyme from thermal inactivation over a period of hours. The artificial electron acceptor specificity of the pure enzyme was similar to that of the membrane-bound form, but the purified enzyme was able to evolve H2 in the presence of reduced methyl viologen. The Km of membrane-bound hydrogenase for H2 was approximately 19 microM with methylene blue as the electron acceptor, whereas the purified enzyme had a higher Km value.     

Regulation of hydrogenase activity in enterobacteria.

Proteus vulgaris, Escherichia coli, and Citrobacter freundii cells were devoid of hydrogenase activity when grown on complex medium or minimal medium plus glucose in the presence of saturating levels of dissolved oxygen. Anaerobically grown cells had appreciable hydrogenase activity. Cells grown anaerobically in the presence of CO (an inhibitor of hydrogenase) or nitrate (an electron acceptor) lacked hydrogenase activity. To make hydrogenase essential for anaerobic growth, cells were grown on fumarate, a nonfermentable carbon source. P. vulgaris and C. freundii evolved H2 gas under these conditions, and the hydrogenase-specific activity was 8 to 10 times greater than that in cells grown on glucose. Cell growth was inhibited by CO, and the cells grew but lacked hydrogenase activity when grown in the presence of nitrate. E. coli grew on fumarate plus H2, and the specific activity was five times greater than that in cells grown on glucose. Thus, hydrogenase activity is inducible and is expressed maximally when the enzyme is essential for cellular growth. Under conditions of growth where the enzyme would not be catalytically active, cells contain little active hydrogenase. Under anaerobic conditions where the enzyme is not essential for growth, the level of hydrogenase activity is intermediate.     

Hydrogenase synthesis in Bradyrhizobium japonicum Hupc mutants is altered in sensitivity to DNA gyrase inhibitors

In the Hupc mutants of Bradyrhizobium japonicum SR, regulation of expression of hydrogenase is altered; the mutants synthesize hydrogenase constitutively in the presence of atmospheric levels of oxygen. The DNA gyrase inhibitors nalidixic acid, novobiocin, and coumermycin were used to inhibit growth of wild-type and mutant cells. For each inhibitor tested, growth of mutant and wild-type strains was equally sensitive. However, in contrast to the wild type, the Hupc mutants synthesized hydrogenase in the presence of high levels of any inhibitor. Cells were incubated with the drugs and simultaneously labeled with 14C-labeled amino acids, and hydrogenase was immunoprecipitated with antibody to the large subunit of the enzyme. Fluorograms of antibody blots then were scanned to determine the relative amount of hydrogenase (large subunit) synthesized in the presence or absence of the gyrase inhibitors. The amount of hydrogenase synthesized by the Hupc mutants in the presence of 300 micrograms of nalidixic acid per ml was near the level of enzyme synthesized in the absence of the inhibitor. No hydrogenase was detected in antibody blots of wild-type cultures which were derepressed for hydrogenase in the presence of 100 micrograms of coumermycin or novobiocin per ml. In contrast, hydrogenase was synthesized by the Hupc mutants in the presence of 100 micrograms of either drug per ml. The amount synthesized ranged from 5 to 32% and 20 to 49%, respectively, of that in the absence of those inhibitors, but nevertheless, hydrogenase synthesis was detected in all of the mutants examined.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hydrogenase synthesis in Bradyrhizobium japonicum Hupc mutants is altered in sensitivity to DNA gyrase inhibitors.

In the Hupc mutants of Bradyrhizobium japonicum SR, regulation of expression of hydrogenase is altered; the mutants synthesize hydrogenase constitutively in the presence of atmospheric levels of oxygen. The DNA gyrase inhibitors nalidixic acid, novobiocin, and coumermycin were used to inhibit growth of wild-type and mutant cells. For each inhibitor tested, growth of mutant and wild-type strains was equally sensitive. However, in contrast to the wild type, the Hupc mutants synthesized hydrogenase in the presence of high levels of any inhibitor. Cells were incubated with the drugs and simultaneously labeled with 14C-labeled amino acids, and hydrogenase was immunoprecipitated with antibody to the large subunit of the enzyme. Fluorograms of antibody blots then were scanned to determine the relative amount of hydrogenase (large subunit) synthesized in the presence or absence of the gyrase inhibitors. The amount of hydrogenase synthesized by the Hupc mutants in the presence of 300 micrograms of nalidixic acid per ml was near the level of enzyme synthesized in the absence of the inhibitor. No hydrogenase was detected in antibody blots of wild-type cultures which were derepressed for hydrogenase in the presence of 100 micrograms of coumermycin or novobiocin per ml. In contrast, hydrogenase was synthesized by the Hupc mutants in the presence of 100 micrograms of either drug per ml. The amount synthesized ranged from 5 to 32% and 20 to 49%, respectively, of that in the absence of those inhibitors, but nevertheless, hydrogenase synthesis was detected in all of the mutants examined.(ABSTRACT TRUNCATED AT 250 WORDS)