Localization and stability of hydrogenases from aerobic hydrogen bacteria

Alcaligenes eutrophus strains H 16, B 19, G 27 and N9A contained two different hydrogenases. One enzyme catalyzed the reduction of NAD by hydrogen and was strictly localized in the soluble cell fraction, while the second enzyme was found to be particulate and unable to react with NAD.All other tested strains, Alcaligenes paradoxus SA 29, Pseudomonas facilis, P. palleronii RH 2, Pseudomonas sp. strain GA 3, Paracoccus denitrificans, Aquaspirillum autotrophicum SA 32, and Corynebacterium autotrophicum 14g and 7C contained only a single enzyme exclusively bound to membranes. This was established using fractional centrifugation, indicator enzyme systems, gentle methods of cell disintegration and discontinuous sucrose density gradient centrifugation. In cell-free extracts obtained by rough disruption (sonication) of cells, hydrogenase was associated to particles of different size and sedimentation velocity. A partial solubilization of hydrogenase caused by sonication was observed with P. facilis.Without exception, the particulate hydrogenases were found (1) to be unable to reduce pyridine nucleotides, and (2) to reduce methylene blue at an extremely high activity. The eminent reaction rate of 34 moles H₂ oxidized per min and mg protein has been determined in particle suspensions of Pseudomonas sp. strain GA 3. All hydrogenases were stable during storage under hydrogen atmosphere, except the soluble enzyme from A. eutrophus H 16 which was shown to be more stable under aerobic conditions.     

The membrane-bound hydrogenase of Alcaligenes eutrophus: II. Localization and immunological comparison with other hydrogenase systems

Immunological comparison of the soluble and the membrane-bound hydrogenase of Alcaligenes eutrophus revealed no common antigenic determinants shared by the native proteins, however, a small amount of cross-reacting material was detected after freezing and thawing. Immune precipitation assays supported previous observations indicating the membrane-bound hydrogenase to be localized in the outer surface of the cytoplasmic membrane.The membrane-bound hydrogenases of A. eutrophus and Pseudomonas pseudoflava showed close immunological relationship, and material cross-reacting to both antisera was found in membrane extracts of all hydrogen-oxidizing strains of Pseudomonas, Alcaligenes and Aquaspirillum. Material cross-reacting to the membrane-bound hydrogenase of Xanthobacter autotrophicus GZ 29 was found only in a few hydrogen-oxidizing bacteria. Material cross-reacting to the soluble hydrogenase of A. eutrophus was detected in strains of A. eutrophus and A. ruhlandii only.Comparison of the membrane-bound hydrogenase of A. eutrophus, P. pseudoflava and X. autotrophicus with hydrogenases of other physiological bacterial groups revealed serological relationship to the membrane-bound hydrogenases of the hydrogen bacteria and of Chromatium vinosum only. The results are discussed in terms of physiological, taxonomical, and evolutionary aspects.     

Analysis of a pleiotropic gene region involved in formation of catalytically active hydrogenases in Alcaligenes eutrophus H16

In Alcaligenes eutrophus H16 a pleiotropic DNA-region is involved in formation of catalytically active hydrogenases. This region lies within the hydrogenase gene cluster of megaplasmid pHG1. Nucleotide sequence determination revealed five open reading frames with significant amino acid homology to the products of the hyp operon of Escherichia coli and other hydrogenase-related gene products of diverse organisms. Mutants of A. eutrophus H16 carrying Tn5 insertions in two genes (hypB and hypD) lacked catalytic activity of both soluble (SH) and membrane-bound (MBH) hydrogenase. Immunological analysis showed that the mutants contained SH-and MBH-specific antigen. Growing the cells in the presence of ⁶³Ni²⁺ yielded significantly lower nickel accumulation rates of the mutant strains compared to the wild-type. Analysis of partially purified SH showed only traces of nickel in the mutant protein suggesting that the gene products of the pleiotropic region are involved in the supply and/or incorporation of nickel into the two hydrogenases of A. eutrophus.     

Isolation of hydrogenase regulatory mutants of hydrogen-oxidizing bacteria by a colony-screening method

Mutants derepressible for hydrogenases (Hox d) have been isolated from the wild type of Alcaligenes hydrogenophilus which is inducible for hydrogenases (Hox i). The mutants are able to form the hydrogenases during growth on gluconate under air while the wild type requires molecular hydrogen for hydrogenase systhesis.Mutant selection involved alternating growth under autotrophic and heterotrophic conditions. Mutants derepressed for hydrogenases after growth on gluconate were recognized by a new colony-screening method allowing differentiation between colonies of hydrogenase-containing and hydrogenase-free cells of aerobic hydrogen-oxidizing bacteria. The method is based on the ability of the colonies to reduce triphenyltetrazolium chloride in the presence of monoiodoacetate and gaseous hydrogen to its water-insoluble purple formazan. Endogenous dye reduction (under nitrogen) and the function of the cytoplasmic NAD-reducing hydrogenase were completely inhibited by monoiodoacetate. The applicability of the method has been demonstrated for wild type strains and mutants of various hydrogen-oxidizing bacteria. When mutants of A. hydrogenophilus and A. eutrophus H16 lacking the Hox-encoding plasmids pHG21-a and pHG1, respectively, were used as recipients and Hox d mutant M 201 of A. hydrogenophilus as a donor transconjugants appeared which had received the Hox d character and the megaplasmid pHG21-a.Abbreviations MIAc monoiodoacetate - TTC 2,3,5-triphenyl-2-tetrazolium chloride - Hox ability to oxidize hydrogen Dedicated to Gerhard Drews on the occasion of his 60th birthday, remembering the education and inspiration we received from our teacher Johannes Buder at the Martin-Luther University of Halle     

Mutants of Alcaligenes eutrophus defective in autotrophic metabolism

Forty-four mutants of Alcaligenes eutrophus H 16 were isolated which grew poorly or not at all under autotrophic conditions. Four types were characterized with respect to their defects and their physiological properties. One mutant lacked both enzymes specific for autotrophic CO₂ fixation, another one lacked both hydrogenases, and two mutants lacked either the membrane-bound or the soluble hydrogenase. Comparing the results of studies on these mutant types, the following conclusions were drawn: the lack of each hydrogenase enzyme could be partially compensated by the other one; the lack of membrane-bound hydrogenase did not affect autotrophic growth, whereas the lack of the soluble hydrogenase resulted in a decreased autotrophic growth rate. When pyruvate as well as hydrogen were supplied to the wild-type, the cell yield was higher than in the presence of pyruvate alone. Mutant experiments under these conditions indicated that either of both hydrogenases was able to add to the energy supply of the cell. Only the soluble hydrogenase was involved in the control of the rate of hydrogen oxidation by carbon dioxide; the mutant lacking this enzyme did not respond to the presence or absence of CO₂. The suppression of growth on fructose by hydrogen could be mediated by either of both hydrogenases alone.     

A proton-deuterium exchange study of three types ofDesulfovibrio hydrogenases

Summary Hydrogenases are among the main enzymes involved in bacterial anaerobic corrosion of metals. The study of their mode of action is important for a full comprehension of this phenomenon. The three types ofDesulfovibrio hydrogenases [(Fe), (NiFe), (NiFeSe)] present different patterns in the pH dependence of their activity. The periplasmic enzyme fromDesulfovibrio salexigens and the cytoplasmic enzyme fromDesulfovibrio baculatus both have pH optima at 7.5 for H₂ uptake and 4.0 for H₂ evolution and H⁺–D₂ exchange reaction (measured by membrane-inlet mass-spectrometry). The H₂ to HD ratio at pH above 5.0 is higher than 1.0. The periplasmic hydrogenase fromD. gigas presents the same pH optimum (8.0) for the H⁺–D₂ exchange as for H₂ consumption. In contrast, the enzyme fromD. vulgaris has the highest activity in H₂ production and in the exchange at pH 5.0. Both hydrogenases have a H₂-to-HD ratio below 1.0.     

Transformation of metals and metal ions by hydrogenases from phototrophic bacteria

The ability of hydrogenases isolated from Thiocapsa roseopersicina and Lamprobacter modestohalophilus to reduce metal ions and oxidize metals has been studied. Hydrogenases from both phototrophic bacteria oxidized metallic Fe, Cd, Zn and Ni into their ionic forms with simultaneous evolution of molecular hydrogen. The metal oxidation rate decreased in the series Zn>Fe>Cd>Ni and depended on the pH. The presence of methyl viologen in the reaction system accelerated this process. T. roseopersicina and L. modestohalophilus cells and their hydrogenases reduced Ni(II), Pt(IV), Pd(II) or Ru(III) to their metallic forms under H₂ atmosphere. These results suggest that metals or metal ions can serve as electron donors or acceptors for hydrogenases from phototrophic bacteria.     

Complete Dehydrogenation of N2H4BH3 over Noble‐Metal‐Free Ni0.5Fe0.5–CeOx/MIL‐101 with High Activity and 100% H2 Selectivity

Efficient and selective dehydrogenation of hydrazine borane (HB), a novel hydrogen storage material with very high hydrogen content (HB, 15.4 wt%), is a key challenge for a fuel‐cell‐based hydrogen economy. However, even using the noble metal catalysts for HB decomposition, the activities are still far from satisfying, to say nothing of non‐noble‐metal‐containing catalysts. In response, as a proof‐of‐concept experiment, herein, noble‐metal‐free NiFe–CeO_x nanoparticles are successfully immobilized on an MIL‐101 support without surfactant by a simple liquid impregnation method. Unexpectedly, the resultant Ni_0.5Fe_0.5–CeO_x/MIL‐101 catalyst shows good performance, including 100% H₂ selectivity, 100% conversion, and record catalytic activity (351.3 h^?1) for hydrogen generation at mild temperature, which is even better than most of the noble metal heterogeneous catalysts and might be attributed to the good dispersion and uniform particle size of the Ni_0.5Fe_0.5–CeO_x nanoparticles due to steric restrictions effect of the MIL‐101 support. Additionally, extending MIL‐101 to some other important kinds of metal–organic framework (MOF) structures, the resultant NiFe–CeO_x/MOF catalysts all show good catalytic activity toward HB decomposition, showing the universality of the MOF supported NiFe–CeO_x catalysts.     

Unconventional and effective methods for the regeneration of NAD(P) H in microorganisms or crude extracts of cells

Several yeasts, as well as aerobic and anaerobic bacteria catalyze the reduction of NAD and NADP in the presence of reduced methylviologen. The rates are usually much higher than those of reductions of unsaturated substrates by the organisms in cofermentations with carbohydrates. Since methylviologen can be continuously reduced at the cathode of an electrochemical cell it acts in catalytic amounts as a regenerable electron donor. Such systems may be superior to that with glucose as electron donor, because the NAD(P)H can be used exclusively for the reduction of the unsaturated substrate. The rate of the NAD(P)H formation depends very much on the organism and for the same organism on the growth procedure, the growth medium, the pretreatment of the cells, the pH, the buffer as well as on the ionic strength. Cells of Candida utilis which were frozen and thawed several times were superior to cells freshly harvested. Crude extracts revealed the best activities.Clostridia show the highest activities (up to 15 U per mg protein in the crude extract) and are suitable catalysts for the preparation of [4S-²H]NADH and [4S-²H]NADPH using ²H₂O-buffer in an electrochemical cell.The combinations of Alcaligenes eutrophus or Clostridium kluyveri and Candida utilis extracts in the presence of methylviologen are effective systems to reduce hydroxyacetone with hydrogen gas as electron donor or in an electrochemical cell. In this combination of microorganisms NADH is formed mainly by A. eutrophus or C. kluyveri and consumed for the reduction of hydroxyacetone by a reductase present in Candida utilis. The productivity numbers of such combinations are 10–30 times higher than those of yeasts alone.NAD(P)H regeneration, methylviologen-dependent NAD(P)H formation, deuterated NAD(P)H, Clostridia, yeast, bioreduction     

Multiple and reversible hydrogenases for hydrogen production by Escherichia coli: dependence on fermentation substrate,pH and the F0F1-ATPase

Molecular hydrogen (H₂) can be produced via hydrogenases during mixed-acid fermentation by bacteria. Escherichia coli possesses multiple (four) hydrogenases. Hydrogenase 3 (Hyd-3) and probably 4 (Hyd-4) with formate dehydrogenase H (Fdh-H) form two different H₂-evolving formate hydrogen lyase (FHL) pathways during glucose fermentation. For both FHL forms, the hycB gene coding small subunit of Hyd-3 is required. Formation and activity of FHL also depends on the external pH ([pH]_out) and the presence of formate. FHL is related with the F₀F₁-ATPase by supplying reducing equivalents and depending on proton-motive force. Two other hydrogenases, 1 (Hyd-1) and 2 (Hyd-2), are H₂-oxidizing enzymes during glucose fermentation at neutral and low [pH]_out. They operate in a reverse, H₂-producing mode during glycerol fermentation at neutral [pH]_out. Hyd-1 and Hyd-2 activity depends on F₀F₁. Moreover, Hyd-3 can also work in a reverse mode. Therefore, the operation direction and activity of all Hyd enzymes might determine H₂ production; some metabolic cross-talk between Hyd enzymes is proposed. Manipulating of different Hyd enzymes activity is an effective way to enhance H₂ production by bacteria in biotechnology. Moreover, a novel approach would be the use of glycerol as feedstock in fermentation processes leading to H₂ production, reduced fuels and other chemicals with higher yields than those obtained by common sugars.     

Transfer and Expression of Lithoautotrophy and Denitrification in a Host Lacking These Metabolic Activities

The conjugative 450-kilobase-pair megaplasmid pHG1 from Alcaligenes eutrophus H16 was transferred to the herbicide-degrading soil bacterium A. eutrophus JMP134. This transfer was achieved by means of RP4 mobilization and a Tn5-Mob insertion provided in trans on the megaplasmid replicon. Although kanamycin-resistant transconjugants also occurred with other gram-negative species such as Rhizobium, Agrobacterium, and thiobacteria, A. eutrophus JMP134 was the only recipient which stably maintained the megaplasmid. pHG1-containing transconjugants derived from JMP134 expressed all metabolic functions associated with the plasmid: the ability to oxidize hydrogen through catalysis of two hydrogenases, to assimilate carbon dioxide via the Calvin cycle pathway, and to grow with nitrate anaerobically. All of these metabolic activities were absent in the original strain JMP134.     

Hydrogenase 3 but not hydrogenase 4 is major in hydrogen gas production by Escherichia coli formate hydrogenlyase at acidic pH and in the presence of external formate

Fermenting Escherichia coli is able to produce formate and molecular hydrogen (H₂) when grown on glucose. H₂ formation is possessed by two hydrogenases, 3 (Hyd-3) and 4 (Hyd-4), those, in conjunction with formate dehydrogenase H (Fdh-H), constitute distinct membrane-associated formate hydrogenylases. At slightly alkaline pH (pH 7.5), the production of H₂ was found to be dependent on Hyd-4 and the F₀F₁-adenosine triphosphate (ATPase), whereas external formate increased the activity of Hyd-3. In this study with cells grown without and with external formate H₂ production dependent on pH was investigated. In both types of cells, H₂ production was increased after lowering of pH. At acidic pH (pH 5.5), this production became insensitive either to N,N′-dicyclohexylcarbodiimide or to osmotic shock and it became largely dependent on Fdh-H and Hyd-3 but not Hyd-4 and the F₀F₁-ATPase. The results indicate that Hyd-3 has a major role in H₂ production at acidic pH independently on the F₀F₁-ATPase.     

Measuring the pH dependence of hydrogenase activities

The pH dependences of activities of homogenous hydrogenases of Thiocapsa roseopersicina and Desulfomicrobium baculatum in the reaction of hydrogen uptake in solution in the presence of benzyl viologen and the pH dependences of catalytic currents of hydrogen oxidation by electrodes on which these hydrogenases were immobilized were compared. Maximal activities of the hydrogenases from T. roseopersicina and D. baculatum in the reaction hydrogen uptake in solution were observed at pH 9.5 and 8.5, respectively. However, the steady-state current caused by catalytic uptake of hydrogen was maximal for the T. roseopersicina hydrogenase-containing electrode at pH 5.5-6.5 under overvoltage of 30-60 mV, whereas for electrodes with D. baculatum hydrogenase it was maximal at pH 6.0-6.5. Analysis of these data suggests that pH-dependent changes in the hydrogenase activities in solution during hydrogen uptake are due not only to the effect of proton concentration on the enzyme conformation or protonation of certain groups of the enzyme active center, but they are rather indicative of changes in free energy of the reaction accompanying changes in pH.     

Hydrogen as an energy source for the human pathogen <Emphasis Type="Italic">Bilophila wadsworthia</Emphasis>

The gram-negative anaerobic gut bacterium Bilophila wadsworthia is the third most common isolate in perforated and gangrenous appendicitis, being also found in a variety of other infections. This organism performs a unique kind of anaerobic respiration in which taurine, a major organic solute in mammals, is used as a source of sulphite that serves as terminal acceptor for the electron transport chain. We show here that molecular hydrogen, one of the major products of fermentative bacteria in the colon, is an excellent growth substrate for B. wadsworthia. We have quantified the enzymatic activities associated with the oxidation of H₂, formate and pyruvate for cells obtained in different growth conditions. The cell extracts present high levels of hydrogenase activity, and up to five different hydrogenases can be expressed by this organism. One of the hydrogenases appears to be constitutive, whereas the others show differential expression in different growth conditions. Two of the hydrogenases are soluble and are recognised by antibodies against a [FeFe] hydrogenase of a sulphate reducing bacterium. One of these hydrogenases is specifically induced during fermentative growth on pyruvate. Another two hydrogenases are membrane-bound and show increased expression in cells grown with hydrogen. Further work should be carried out to reveal whether oxidation of hydrogen contributes to the virulence of B. wadsworthia.     

Photo-induced H2 production by [NiFe]-hydrogenase from T. roseopersicina covalently linked to a Ru(II) photosensitizer

The potential of hydrogen as a clean renewable fuel source and the finite reserves of platinum metal to be utilized in hydrogen production catalysts have provided the motivation for the development of non-noble metal-based solutions for catalytic hydrogen production. There are a number of microorganisms that possess highly efficient hydrogen production catalysts termed hydrogenases that generate hydrogen under certain metabolic conditions. Although hydrogenases occur in photosynthetic microorganisms, the oxygen sensitivity of these enzymes represents a significant barrier in directly coupling hydrogen production to oxygenic photosynthesis. To overcome this barrier, there has been considerable interest in identifying or engineering oxygen tolerant hydrogenases or generating mimetic systems that do not rely on oxygen producing photocatalysts. In this work, we demonstrate photo-induced hydrogen production from a stable [NiFe]-hydrogenase coupled to a [Ru(2,2'-bipyridine)₂(5-amino-1,10-phenanthroline)]²⁺ photocatalyst. When the Ru(II) complex is covalently attached to the hydrogenase, photocatalytic hydrogen production occurs more efficiently in the presence of a redox mediator than if the Ru(II) complex is simply present in solution. Furthermore, sustained hydrogen production occurs even in the presence of oxygen by presumably creating a local anoxic environment through the reduction of oxygen similar to what is proposed for oxygen tolerant hydrogenases. These results provide a strong proof of concept for engineering photocatalytic hydrogen production in the presence of oxygen using biohybrid mimetic systems.     

Plasmids required for utilization of molecular hydrogen by Alcaligenes eutrophus

Alcaligenes eutrophus and three other hydrogen bacteria exposed to plasmid-curing agents generated autotrophic-minus mutants at high frequency. These mutants were blocked in the metabolism of H₂ as an energy source and had normal levels of enzymes involved in CO₂ fixation. The loss of hydrogenase activity in A. eutrophus was accompanied by the loss or alteration of a plasmid that had molecular weight of approximately 200×10⁶. Mobilization of this plasmid from wild-type A. eutrophus strains into cured hydrogenase-minus derivatives restored hydrogenase function. It is concluded that A. eutrophus contains a large plasmid required for hydrogen metabolism and thereby autotrophic growth.Abbreviations Aut autotrophic - Hup hydrogen uptake - NTG N-methyl-N-nitro-N-nitrosoguanidine - RuBP ribulose bisphosphate - RuMP ribulose monophosphate - Kan kanamycin - Nal nalidixic acid - Rif rifampicin - Tet tetracycline     

Identification of new peptides synthesized under the hydrogenase control system of Alcaligenes eutrophus

Total protein of Alcaligenes eutrophus was analyzed by two-dimensional protein map. Cells grown at 30° C expressed hydrogen-oxidizing (Hox) ability mediated by a soluble (Hos) and a particulate hydrogenase (Hop). Hox ability was not expressed at 37° C (HoxTs). The six subunits of the two hydrogenases were identified. Besides these six subunits eight peptides were not or hardly detected at 37° C. The mutant HF117 which expressed Hox ability at 37° C (HoxTr), formed the hydrogenase peptides and five of the eight peptides. These peptides designated B, C, E, F, and H were characterized by their isoelectric point and molecular mass (M _r); their M _r were 18 800, 45 400, 41 900, 39 400, and 40 600, respectively. The five peptides were not formed in regulatory Hox^– mutants, and not formed in mutants cured of plasmid pHG1, carrying the genetic information for hydrogenase formation. Strain HF160, carrying a Tn5 insertion in a gene essential for Hos expression specifically did not form the B-peptide. All peptides were found in the soluble fraction of cell extracts, the F-peptide was also detected in the particulate fraction. The function of the new Hox-peptides is presently unknown.Abbreviations PAGE polyacrylamide gelelectrophoresis - SDS sodium dodecylsulfate - Hox hydrogen oxidizing ability     

Immunological characterization of hydrogenases in the nitrogen-fixing cyanobacterium Nostoc sp. strain PCC 73102

N₂-fixing Nostoc sp. strain PCC 73102 was examined for the presence of hydrogenases. Native-PAGE/immunoblots demonstrated that two proteins with molecular masses of approximately 200 kDa and 215 kDa are immunologically related to hydrogenases purified from Bradyrhizobium japonicum, Azotobacter vinelandii, Methanosarcina barkeri, and Thiocapsa roseopersicina. SDS-PAGE/immunoblots showed that one polypeptide, with a molecular mass of about 58 kDa, is immunologically related to the hydrogenases purified from all the microorganisms mentioned above. In addition, two polypeptides, with molecular masses of approximately 34 and 70 kDa, are immunologically related to the hydrogenases purified from T. roseopersicina and M. barkeri respectively. Immunogold/transmission electron microscopy showed that the hydrogenase proteins are present in both the heterocysts and the vegetative cells.     

Genomic Analysis Reveals Multiple [FeFe] Hydrogenases and Hydrogen Sensors Encoded by Treponemes from the H<Subscript>2</Subscript>-Rich Termite Gut

We have completed a bioinformatic analysis of the hydrogenases encoded in the genomes of three termite gut treponeme isolates: hydrogenotrophic, homoacetogenic Treponema primitia strains ZAS-1 and ZAS-2, and the hydrogen-producing, sugar-fermenting Treponema azotonutricium ZAS-9. H₂ is an important free intermediate in the breakdown of wood by termite gut microbial communities, reaching concentrations in some species exceeding those measured for any other biological system. The spirochetes encoded 4, 8, and 5 [FeFe] hydrogenase-like proteins, identified by their H domains, respectively, but no other recognizable hydrogenases. The [FeFe] hydrogenases represented many sequence families previously proposed in an analysis of termite gut metagenomic data. Each strain encoded both putative [FeFe] hydrogenase enzymes and evolutionarily related hydrogen sensor/transducer proteins likely involved in phosphorelay or methylation pathways, and possibly even chemotaxis. A new family of [FeFe] hydrogenases (FDH-Linked) is proposed that may form a multimeric complex with formate dehydrogenase to provide reducing equivalents for reductive acetogenesis in T. primitia. The many and diverse [FeFe] hydrogenase-like proteins encoded within the sequenced genomes of the termite gut treponemes has enabled the discovery of a putative new class of [FeFe] hydrogenase proteins potentially involved in acetogenesis and furthered present understanding of many families, including sensory, of H domain proteins beyond what was possible through the use of fragmentary termite gut metagenome sequence data alone, from which they were initially defined.     

Denitrifikation bei Hydrogenomonas eutropha Stamm H16

Zusammenfassung Hydrogenomonas eutropha (syn. Alcaligenes eutrophus) Stamm H 16 wächst anaerob mit Fructose und Nitrat bzw. Nitrit. Autotrophanaerobes Wachstum unter einer H₂-CO₂-Atmosphäre (90+10 Vol.-%) mit Nitrat als einzigem Wasserstoff-Acceptor ist minimal.Während des anaeroben Wachstums mit Nitrat sind zwei Phasen zu unterscheiden. In der ersten Phase erfolgt die Zellvermehrung auf Kosten der Reduktion von Nitrat zu Nitrit; dieses wird angehäuft. In der zweiten Phase wird Nitrit unter Bildung von Stickstoff reduziert.Gewaschene, anaerob gewachsene Zellen reduzieren Nitrat und Nitrit unter Bildung von N₂. Stöchiometrische Experimente mit H₂ oder Fructose als H-Donatoren lassen darauf schließen, daß Stickstoff das einzige Produkt der Denitrifikation durch die Zellen ist. Diese Schlußfolgerung wurde durch eine massenspektrometrische Analyse des gebildeten Gases bestätigt. Aerob gewachsene Zellen reduzieren Nitrat nur zu Nitrit. In Gegenwart von Ammonium-Salz gewachsene Zellen reduzieren Nitrat mit sehr geringer Rate.Die Ergebnisse deuten darauf hin, daß Stamm H 16 über nur eine Nitratreductase verfügt. Die Bildung des Enzyms ist durch Ammonium reprimierbar; O₂ ist ohne Einfluß. Die Nitritreductase fand sich sowohl in der löslichen Fraktion als auch in den gereinigten Partikeln lokalisiert. Das Nitritreductase-System wird nur unter anaeroben Bedingungen gebildet.

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Denitrification in Hydrogenomonas eutropha strain H16

Summary The hydrogen bacterium Hydrogenomonas eutropha (syn. Alcaligenes eutrophus) strain H 16 is able to grow anaerobically with fructose and nitrate or nitrite, respectively. Autotrophic anaerobic growth under a gas atmosphere of hydrogen and carbon dioxide (90+10 vol-%) with nitrate as the sole hydrogen acceptor is minimal.During anaerobic growth with nitrate as H-acceptor, two growth phases are distinguishable: During the first phase cell growth occurs with the reduction of nitrate to nitrite, which is accumulated; on the second phase nitrite is reduced with the formation of gaseous nitrogen.Washed, anaerobically grown cells reduce nitrate and nitrite with the formation of N₂. Stoichiometric experiments employing hydrogen or fructose as the hydrogen donors are consistent with the conclusion that nitrogen is the sole product of denitrification by these cells. This was confirmed by mass spectrometric analysis of the gas formed. Aerobically grown cells are able to reduce nitrate only to nitrite; when grown in the presence of ammonia, the reduction rate is very low.The results indicate that strain H 16 contains only one nitrate reductase. The formation of this enzyme system is not influenced by oxygen, however, is repressed by ammonia.When employing a purified soluble fraction and particles, nitrite reductases were found in both fractions. The nitrite reductase system is formed only under anaerobic conditions.

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Abkürzungen MB Methylenblau - PMS Phenazinmethosulfat