Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:1.12.7.2 (hydrogenase)
3,522 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

An original gas chromatographic-mass spectrometric technique is described for studying simultaneous dihydrogen-deuteron exchange and para-ortho H2 conversion catalyzed by different Desulfovibrio hydrogenases. Para and orthohydrogens are separated on an alumina column at the temperature of liquid nitrogen, but if both HD and ortho H2 are present, their retention times are too close to each other for total separation and only one peak is observed with a thermal conductivity detector. In order to resolve the peaks from one another, a fraction of the gas released from the gas chromatograph column is admitted to the ion source of a mass spectrometer, where the gases are separated according to their respective masses. Because of a peak-jumping system, the different components involved in the exchange and in the conversion reactions can be scanned so that the spectra corresponding to mass m/e 2 (para and ortho H2), m/e 3 (HD), and m/e 4 (D2) can be obtained simultaneously. This technique has been employed to resolve a controversial problem concerning the occurrence or lack of any para-orthohydrogen conversion in heavy water. Actually both exchange and conversion were demonstrated to occur with a (NiFe) hydrogenase, whereas with a (NiFeSe) hydrogenase, which had an exchange activity equivalent to that of the former, practically no para-ortho conversion could be observed in D2O. These findings are related to the constitutional and catalytic properties of the hydrogenases belonging to the different classes.
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PMID:A gas chromatographic-mass spectrometric technique for studying simultaneous hydrogen-deuteron exchange and para-orthohydrogen conversion in hydrogenases of Desulfovibrio vulgaris Hildenborough. 222 93

The two iron-only hydrogenases (I and II) from Clostridium pasteurianum have been investigated by variable temperature magnetic circular dichroism (MCD) and electron paramagnetic resonance (EPR) spectroscopies. Samples were studied both reduced with dithionite under an atmosphere of H2 and after oxidation with thionine. The results are consistent with four and two [4Fe-4S]1+,2+ (F)-clusters in hydrogenases I and II, respectively. All four F-clusters are reduced and paramagnetic in reduced hydrogenase I, with up to one exhibiting an S = 3/2 ground state and the remainder having conventional S = 1/2 ground states. Both F-clusters have S = 1/2 ground states in reduced hydrogenase II; however, one appears to be only partially reduced under the conditions used for reduction. MCD studies of the oxidized enzymes show no temperature-dependent features in the visible region which can be attributed to the EPR-active S = 1/2 hydrogen-activating cluster, suggesting predominantly oxygen and nitrogen coordination for the iron atoms of this center. However, temperature-dependent MCD transitions arising from a hitherto undetected S greater than 1/2 Fe-S clusters are apparent in both oxidized hydrogenases. Detailed EPR studies of oxidized hydrogenase I revealed resonances from an S = 3/2 species, however, spin quantitation reveals this to be a trace component that is unlikely to be responsible for the observed low temperature MCD spectrum. The nature and origin of these S greater than 1/2 Fe-S clusters are discussed in light of the available spectroscopic data for these and other iron-only hydrogenases.
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PMID:Magnetic circular dichroism and electron paramagnetic resonance studies of hydrogenases I and II from Clostridium pasteurianum. 255 90

H2 uptake and H2-supported O2 uptake were measured in N2-fixing cultures of Frankia strain ArI3 isolated from root nodules of Alnus rubra. H2 uptake by intact cells was O2 dependent and maximum rates were observed at ambient O2 concentrations. No hydrogenase activity could be detected in NH4+-grown, undifferentiated filaments cultured aerobically indicating that uptake hydrogenase activity was associated with the vesicles, the cellular site of nitrogen fixation in Frankia. Hydrogenase activity was inhibited by acetylene but inhibition could be alleviated by pretreatment with H2. H2 stimulated acetylene reduction at supraoptimal but not suboptimal O2 concentrations. These results suggest that uptake hydrogenase activity in ArI3 may play a role in O2 protection of nitrogenase, especially under conditions of carbon limitation.
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PMID:Interaction between hydrogenase, nitrogenase, and respiratory activities in a Frankia isolate from Alnus rubra. 276 17

The detrimental effects of excessive Ni on plant growth have been well known for many years. More recent evidence indicates that Ni is required in small amounts for normal plant growth and development. Ni is an essential component of urease in plants and microorganisms. A deficiency of Ni in plants is reported to result in necrotic lesions in leaves in response to toxic accumulations of urea. Urease plays an essential role in mobilization of nitrogenous compounds in plants, a process that is especially important during seed germination and fruit formation when protein reserves are degraded into amino acids. Arginine, an abundant amino acid in plants, when degraded produces urea as a product and urease is needed for urea utilization. Theories of urea formation during allantoin degradation in Glycine max have been recently refuted. In G. max ureides apparently are metabolized via an amidohydrolase reaction with subsequent degradation of ureidoglycine, yielding glyoxylate, NH+4 and CO2. No evidence is available for the formation of urea in this pathway. Nitrogen-fixing symbionts, such as Rhizobium and Bradyrhizobium, contain two known Ni enzymes: urease and hydrogenase. Optimum growth of nodulated legumes and actinorhizal plants may depend on an adequate supply of Ni to meet the requirements of the Ni-requiring enzymes in host plants and endophytes. The seeds of severely Ni-deficient Hordeum are completely inviable, thus providing conclusive evidence for the essentiality of Ni for this species. The evidence indicates that Ni must be added to the list of micronutrient elements generally required by plants.
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PMID:Nickel as a micronutrient element for plants. 307 27

The nitrogenase activity, nitrate reductase activity and oxygen uptake as well as the hydrogen incorporation and ATP content were examined in the root nodules and bacteroids, respectively, formed by Rhizobium leguminosarum strains 128C53 (hydrogenase positive) and 300 (hydrogenase negative) in symbiosis with Pisum sativum plants grown in the presence of 2 mM KNO3. The strain 128C53 showed the greatest values for all parameters analyzed, except for the nitrate reductase activity, which was higher for the strain 300. Similarly, nodule nitrate reductase activity in strain 300 was greater than that in strain 128C53 when plants grew in the absence of combined nitrogen. In general, the highest values were obtained when determinations were made after 7 hours of plant illumination. However, the hydrogenase activity of strain 128C53 and the nitrate reductase activities of both strains increased with the light period, reaching a maximum after 14 hours of illumination. These results suggest that the benefits derived from the superior symbiotic properties and from the presence of hydrogenase activity in strain 128C53 could be counteracted by the higher rates of the nodule nitrate reductase activity in strain 300.
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PMID:[Nitrogenase, hydrogenase and nitrate reductase activities, oxygen consumption, and ATP content in nodules formed by strains of Rhizobium leguminosarum 128C53 and 300 in symbiosis with pea plants]. 307 42

The hydrogenase activities of the heterocystous cyanobacteria Anabaena cylindrica and Mastigocladus laminosus are nickel dependent, based on their inability to consume hydrogen with various electron acceptors or produce hydrogen with dithionite-reduced methyl viologen, after growth in nickel-depleted medium. Upon addition of nickel ions to nickel-deficient cultures of A. cylindrica, the hydrogenase activity recovered in a manner which was protein synthesis-dependent, the recovery being inhibited by chloramphenicol. We have used the nickel dependence of the hydrogenase as a probe of the possible roles of H2 consumption in enhancing nitrogen fixation, and particularly for protecting nitrogenase against oxygen inhibition. Although at the usual growth temperatures (25 degrees for A. cylindrica and 40 degrees for M. laminosus), the cells consume H2 vigorously in an oxyhydrogen reaction after growth in the presence of nickel ions, we have not found that the reaction confers any significant additional protection of nitrogenase, either at aerobic pO2 (for both organisms) or at elevated pO2 (for A. cylindrica). However, at elevated temperatures (e.g., 40 degrees for A. cylindrica and 48 degrees for M. laminosus) a definite protective effect was observed. At these temperatures both organisms rapidly lost acetylene reduction activity under aerobic conditions. When hydrogen gas (10%) was present, the cells retained approximately 50% of the nitrogenase activity observed under anaerobic conditions (argon gas phase). No such protection by hydrogen gas was observed with nickel-deficient cells. Studies with cell-free extracts of A. cylindrica showed that the predominant effect of temperature was not due to thermal inactivation of nitrogenase.
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PMID:The use of nickel to probe the role of hydrogen metabolism in cyanobacterial nitrogen fixation. 308 4

A marine, unicellular, nitrogen-fixing cyanobacterium was isolated from the blades of a brown alga, Sargassum fluitans. This unicellular cyanobacterium, identified as Synechococcus sp. strain SF1, is capable of photoautotrophic growth with bicarbonate as the sole carbon source and dinitrogen as the sole nitrogen source. Among the organic carbon compounds tested, glucose and sucrose supported growth. Of the nitrogen compounds tested, with bicarbonate serving as the carbon source, both ammonia and nitrate produced the highest growth rates. Most amino acids failed to support growth when present as sole sources of nitrogen. Nitrogenase activity in Synechococcus sp. strain SF1 was induced after depletion of ammonia from the medium. This activity required the photosynthetic utilization of bicarbonate, but pyruvate and hydrogen gas were also effective sources of reductant for nitrogenase activity. Glucose, fructose, and sucrose also supported nitrogenase activity but to a lesser extent. Optimum light intensity for nitrogenase activity was found to be 70 microE/m2 per s, while the optimum oxygen concentration in the gas phase for nitrogenase activity was about 1%. A hydrogenase activity was coinduced with nitrogenase activity. It is proposed that this light- and oxygen-insensitive hydrogenase functions in recycling the hydrogen produced by nitrogenase under microaerobic conditions.
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PMID:Physiological conditions for nitrogen fixation in a unicellular marine cyanobacterium, Synechococcus sp. strain SF1. 311 63

Hydrogenases catalyze the reversible activation of dihydrogen. We have previously demonstrated that the purified hydrogenase from the nitrogen-fixing microorganism Azotobacter vinelandii is an alpha beta dimer (98,000 Da) with subunits of 67,000 (alpha) and 31,000 (beta) daltons and that this enzyme contains iron and nickel. The enzyme can be purified anaerobically in the presence of dithionite in a fully active state that is irreversibly inactivated by exposure to O2. Analysis of this hydrogenase by sodium dodecyl sulfate (SDS) polyacrylamide gel electrophoresis (PAGE) following boiling in SDS yields two protein staining bands corresponding to the alpha and beta subunits. However, when this enzyme was treated with SDS (25-65 degrees C) for up to 30 min under anaerobic/reductive conditions and then analyzed by anaerobic SDS-PAGE, a protein staining band corresponding to an apparent molecular mass of 58,000 Da was observed that stained for hydrogenase activity. Analysis of the 58,000-Da activity staining band by a Western immunoblot or a second aerobic SDS-polyacrylamide gel revealed that this protein actually consisted of both the alpha and beta subunits. Thus, the activity staining band (apparent 58,000 Da) represents the 98,000-Da dimer migrating abnormally on SDS-PAGE. Treatment of the anaerobically purified hydrogenase with SDS under aerobic conditions or under anaerobic conditions with electron acceptors prior to electrophoresis resulted in no activity staining band and the separated alpha and beta subunits. A. vinelandii hydrogenase was also purified under aerobic conditions in an inactive O2 stable form that can be activated by removal of oxygen followed by addition of reductant. This enzyme (as isolated), the activated form, and the reoxidized form were analyzed for their stability toward denaturation by SDS. We conclude that the dissociation of the A. vinelandii hydrogenase subunits in SDS is controlled by the redox state of the enzyme suggesting an important role of one or more redox sites in controlling the structure of this enzyme.
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PMID:Redox-dependent subunit dissociation of Azotobacter vinelandii hydrogenase in the presence of sodium dodecyl sulfate. 331 26

The ntr A gene product, required for expression of genes involved in nitrogen fixation (nif) and regulation (ntr), was shown to be necessary for the expression of the two enzymes of the anaerobically inducible formate hydrogenlyase (FHL) pathway, formate dehydrogenase (FDHH) and hydrogenase isoenzyme 3. Consistent with this finding, the gene encoding the selenopolypeptide (fdhF) of FDHH was shown to have a nif consensus promoter. The levels of six other anaerobically inducible enzymes were examined and found to be ntrA independent. Significantly, these latter six enzymes are dependent upon the fnr gene product for their expression while FDHH and hydrogenase 3 are fnr independent. These findings indicate that there are at least two classes of anaerobically regulated promoters: one class which is ntrA dependent and fnr independent and a second class which is fnr dependent and ntr A independent.
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PMID:Involvement of the ntrA gene product in the anaerobic metabolism of Escherichia coli. 332 48

Chemostat cultures of Rhizobium ORS571 limited by the supply of oxygen or an anabolic substrate contained poly-beta-hydroxybutyrate (PHB). Low amounts of PHB (about 10%) were present in ammonia- or nitrate-limited cultures; higher amounts were found in Mg++-limited cultures (about 20%) and in oxygen-limited nitrogen-fixing cultures (37%). A method is described to calculate YATP values (g PHB-free biomass . mol-1 ATP) from the Ysucc values (g dry wt . mol-1 succinate) measured. Ysucc and YATP values in cultures limited by the supply of an anabolic substrate and in the oxygen-limited ammonia-assimilating culture were much lower than the values found in the PHB-free succinate-limited cultures. This shows that uncoupling of growth and energy production occurred. Therefore, H2/N2 ratio (mol hydrogen formed per mol nitrogen fixed) in nitrogen-fixing cultures could not be calculated from the comparison of the YATP value found in the nitrogen-fixing culture and the value found in the corresponding ammonia-assimilating culture. Although the optimal dissolved oxygen concentration (d.o.c.) for nitrogen-fixing cultures of Rhizobium ORS571 is 5 or 10 microM, nitrogen-fixing cultures could be obtained up to a d.o.c. of 40 microM. Not only nitrogenase but also hydrogenase was active at this d.o.c. However, accumulation of PHB (10%) may indicate that cultures grown at unfavourable oxygen concentrations (15-40 microM O2) were N-limited rather than energy-limited, which may be the result of partial inactivation or repression of nitrogenase at a higher d.o.c.
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PMID:The effect of the dissolved oxygen concentration and anabolic limitations on the behaviour of Rhizobium ORS571 in chemostat cultures. 352 45


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