sn-Glycerol-3-phosphate dehydrogenase and its interaction with nitrate reductase in wild-type and hem mutant strains of Staphylococcus aureus

Staphylococcus aureus has membrane-associated sn-glycerol-3-phosphate dehydrogenase activity that is strongly activated by detergents. The enzyme can be measured spectrophotometrically in intact cells in assay systems containing lauryldimethylamine oxide (Ammonyx LO). The dehydrogenase activity was located exclusively in the membrane fraction of cells grown with glycerol under aerobic conditions or under anaerobic conditions with the addition of nitrate; there was no evidence of multiple forms. Development of sn-glycerol-3-phosphate dehydrogenase activity was studied with suspensions of cells grown previously under semianaerobic conditions with glucose and nitrate. The wild-type strain rapidly formed the enzyme when incubated with glycerol under aerobic conditions or under semianaerobic conditions in the presence of nitrate. Under similar conditions, suspensions of hem mutant H-14 required the addition of hemin. Induction of the enzyme was strongly repressed by glucose with both organisms. A procedure was established to obtain cells of mutant H-14 with sn-glycerol-3-phosphate dehydrogenase and nitrate reductase activities, but which could not link the systems unless supplemented with hemin. The coupled activity could also be reconstructed in vitro by the addition of hemin to the depleted membranes.     

Nitrate reductase system in Staphylococcus aureus wild type and mutants.

Respiratory nitrate reductase with lactate as a hydrogen donor has been studied in cells and spheroplast preparations of wild type and heme-deficienct mutants of Staphylococcus aureus. The activity is rapidly induced when suspensions of aerobically grown cells are incubated without aeration in a complete medium with nitrate. In ruptured spheroplast preparations, the activity with lactate as the donor is located in the membrane fraction, whereas at least 50% of the activity assayed with reduced benzyl viologen is in the cytoplasm. The reductase is inhibited by azide and cyanide, and the lactate-linked system is also sensitive to oxamate, 2-heptyl-4-hydroxyquinoline-N-oxide, dicoumarol, and p-chloromercuribenzoate. An inactive form of the reductase is apparently made during induction with tungstate; this can be activated by subsequent incubation with molybdate in the presence of chloramphenicol. Nitrate reductase activity with reduced benzyl viologen as the donor is induced in suspensions of heme-deficient mutants in the presence or absence of heme. The proportion of cytoplasmic activity is increased in the absence of heme. The staphylococcal nitrate reductase has many of the characteristics commonly associated with the respiratory enzyme in other organisms, but the apparent predominance of cytoplasmic activity is unusual.     

The development of nitrate reductase in Chlorella and its repression by ammonium

Summary Chlorella vulgaris, grown with ammonium sulphate as nitrogen source, contains very little nitrate reductase activity in contrast to cells grown with potassium nitrate. When ammonium-grown cells are transferred to a nitrate medium, nitrate reductase activity increases rapidly and the increase is partially prevented by chloramphenicol and by p-fluorophenylalanine, suggesting that protein synthesis is involved. The increase in nitrate reductase activity is prevented by small quantities of ammonium; this inhibition is overcome, in part, by raising the concentration of nitrate. Although nitrate stimulates the development of nitrate reductase activity, its presence is not essential for the formation of the enzyme since this is formed when ammonium-grown cells are starved of nitrogen and when cells are grown with urea or glycine as nitrogen source. It is concluded that the formation of the enzyme is stimulated (induced) by nitrate and inhibited (repressed) by ammonium.     

Biosynthesis of membrane-bound nitrate reductase in Escherichia coli: evidence for a soluble precursor.

Membrane-bound nitrate reductase of Escherichia coli consists of three subunits designated as A, B, and C, with subunit C being the apoprotein of cytochrome b, A hemA mutant that cannot synthesize delta-aminolevulinic acid (ALA) produces a normal, stable, membrane-bound enzyme when grown with ALA. When grown without ALA, this mutant makes a reduced amount of membrane-bound enzyme that is unstable and contains no C subunit. Under the same growth conditions, this mutant accumulates a large amount of a soluble form of the enzyme in the cytoplasm. Accumulation of this cytoplasmic form begins immediately upon induction of the enzyme with nitrate. The cytoplasmic form is very similar to the soluble form of the enzyme obtained by alkaline heat extraction. It is a high-molecular-weight complex with a Strokes radius of 8.0 nm and consists of intact A and B subunits. When ALA is added to a culture growing without ALA, the cytoplasmic form of the enzyme is incorporated into the membrane in a stable form, coincident with the formation of functional cytochrome b. Reconstitution experiments indicate that subunit C is present in cultures grown without ALA but is reduced in amount or unstable. These results indicate that membrane-bound nitrate reductase is synthesized via a soluble precursor containing subunits A and B, which then binds to the membrane upon interaction with the third subunit, cytochrome b.     

Activation by monovalent cations of dissimilatory nitrate reductase in the cells of Pseudomonas denitrificans

Cellular activity of nitrate reductase in Pseudomonas denitrificans which had been grown under denitrifying conditions was increased several times upon incubation of cell suspension with monovalent cations. The enhancement of nitrate reductase activity caused by monovalent cations was ascribed to the activation of the enzyme, since the membrane fraction isolated from the cells after the cation treatment retained the elevated levels of enzyme activity. However, monovalent cations had no effect when added directly to cell-free homogenate, suggesting an important role of some definite structure of membrane in the expression of the effect of monovalent cations.     

Studies on nitrate reductase from Cyanidium caldarium

Summary A nitrate reductase from the thermophilic acidophilic alga, Cyanidium caldarium, was studied. The enzyme utilises the reduced forms of benzyl viologen and flavins as well as both NADPH₂ and NADH₂ as electron donors to reduce nitrate.Heat treatment has an activating effect on the benzyl viologen (FMNH₂, FADH₂) nitrate reductase. At 50°C the activation of the enzyme is complete in about 20 min of exposure, whereas at higher temperatures (until 75°C) it is virtually an instantaneous phenomenon. The observed increase in activity is very low in extracts from potassium nitrate grown cells, whereas it is 5 or more fold in extracts from ammonium sulphate supplied cells. The benzyl viologen nitrate reductase is stable at 60°C and is destroyed at 75°C after 3 min; the NADPH₂ nitrate reductase is destroyed at 60°C. The pH optimum for both activities was found in the range 7.8–8.2.Ammonium nitrate grown cells possess a very low level of nitrate reductase: when they are transferred to a nitrate medium a rapid synthesis of enzyme occurs. By contrast, when cells with fully induced activity are supplied with ammonia, a rapid loss of NADPH₂ and benzyl viologen nitrate reductase occurs; however, activity measured with heated extracts shows that the true level of benzyl viologen nitrate reductase is as high as before ammonium addition. It is suggested that the presence of ammonia causes a rapid inactivation but no degradation of the enzyme.Cycloheximide inhibits the formation of the enzyme; the drug is without effect on the loss of nitrate reductase activity induced by ammonium. The nitrate reductase is reactivated in vivo by the removal of the ammonium, in the absence as well as in the presence of cycloheximide.     

Constitutive and nitrate-induced,membrane-bound nitrate reductase fromBradyrhizobium japonicum

Nitrate reductase (NR) activity was detected in membranes from cells ofBradyrhizobium japonicum cultured in defined medium either with glutamate or nitrate as the only nitrogen source. With gel filtration, the relative molecular mass (Mr) of the NR in cells growth with glutamate was estimated to be about 78 kDa. The enzyme from cells grown aerobically with nitrate had an Mr of 236 kDa, the same as that of the NR from microaerobically nitrate-grown cells. When cells that had been grown with glutamate were incubated microaerobically in both the absence and the presence of nitrate, the enzyme from each source resembled that of nitrate-grown cells in having an Mr of 236 kDa. In glutamate-grown cells that were further incubated, both microaerobiosis and nitrate were required for fully expression of the activity of the enzyme.     

chlD gene function in molybdate activation of nitrate reductase.

chlD mutants of Escherichia coli lack active nitrate reductase but form normal levels of this enzyme when the medium is supplemented with 10-3 M molybdate. When chlD mutants were grown in unsupplemented medium and then incubated with molybdate in the presence of chloramphenicol, they formed about 5% the normal level of nitrate reductase. Some chlD mutants or the wild type grown in medium supplemented with tungstate accumulated an inactive protein which was electrophoretically identical to active nitrate reductase. Addition of molybdate to those cells in the presence of chloramphenicol resulted in the formation of fully induced levels of nitrate reductase. Two chlD mutants, including a deletion mutant, failed to accumulate the inactive protein and to form active enzyme under the same conditions. Insertion of 99-Mo into the enzyme protein paralleled activation; 185-W could not be demonstrated to be associated with the accumulated inactive protein. The rates of activation of nitrate reductase at varying molybdate concentrations indicated that the chlD gene product facilitates the activation of nitrate reductase at concentrations of molybdate found in normal growth media. At high concentrations, molybdate circumvented this function in chlD mutants and appeared to activate nitrate reductase by a mass action process. We conclude that the chlD gene plays two distinguishable roles in the formation of nitrate reductase in E. coli. It is involved in the accumulation of fully induced levels of the nitrate reductase protein in the cell membrane and it facilitates the insertion of molybdenum to form the active enzyme.     

Effect of nitrate,ammonia and nitrogen starvation on the regulation of nitrate reductase in Cyanidium caldarium

Summary Cells of Cyanidium caldarium grown with ammonia or ammonium nitrate as nitrogen source do not contain appreciable nitrate reductase activity. The alga develops the capacity to synthesize the enzyme when it is transferred from the ammonium medium to a nitrogen-free medium. Nitrate is not needed as an inducer and no enhancement in the rate of enzyme synthesis is observed when it is present. By contrast, whereas the synthesis of the enzyme in nitrogen-free medium proceeds at an increasing rate, in the nitrate medium it attains a stationary level after a short time.Nitrate grown cells possess variable amount of inactive nitrate reductase (from 9 to 60%) whereas in nitrogen-free medium the enzyme occurs principally in a fully active form. Addition of ammonia inactivates reversibly the preexisting enzyme. The inactive enzyme is measurable in the crude extract after activation by heating.It is suggested that in Cyanidium the inactivating effect of ammonia, which is the end product of nitrate reduction, in association with the repression of enzyme controls the level of nitrate reductase activity.     

Purification and Characterization of Nitrate Reductase from the Halotolerant Cyanobacterium <Emphasis Type="Italic">Aphanothece halophytica</Emphasis>

Summary Factors affecting the activity of nitrate reductase (E.C.1.7.7.2) from the halotolerant cyanobacterium Aphanothece halophytica were investigated. Cells grown in nitrate-containing medium exhibited higher nitrate reductase activity than cells grown in medium in which nitrate was replaced by glutamine. When ammonium was present in the medium instead of nitrate, the activity of nitrate reductase was virtually non-detectable, albeit with normal cell growth. The enzyme was localized mainly in the cytoplasm. The enzyme was purified 406-fold with a specific activity of 40.6 μmol/min/mg protein. SDS-PAGE revealed a subunit molecular mass of 58 kDa. Gel filtration experiments revealed a native molecular mass of 61 kDa. The K _m value for nitrate was 0.46 mM. Both methyl viologen and ferredoxin could serve as electron donor with K _m values of 4.3 mM and 5.2 μM, respectively. The enzyme was strongly inhibited by sulfhydryl-reactive agents and cyanide. Nitrite, the product of the enzyme reaction, showed little inhibition. Chlorate, the substrate analog, could moderately inhibit the enzyme activity. NaCl up to 200 mM stimulated the activity of the enzyme whereas enzyme inhibition was observed at ≥300 mM NaCl.     

Triadimenol Increases Nitrate Levels and Nitrate Reductase Activity in Canola Leaves

Nitrate reductase activity in the first true leaves of canola(Brassica napus L.) seedlings grown in one-quarter strengthHoagland's solution from seeds pretreated with triadimenol (0.3or 30 g (a.i.) kg^–1 of seed) was higher than controlsduring the growth period of 15 to 25 d after planting. Triadimenolalso increased chlorophyll levels, the increase being more pronouncedat its lower concentration. The treatment also increased theweight and nitrate content of the leaves. When seedlings weregrown in nutrient solution containing 1 to 20 mM nitrate, theincrease in nitrate reductase activity by triadimenol was higherat lower rather than at higher nitrate concentrations. The nitratelevels and Kjeldahl nitrogen in the triadimenol-treated leaveswas higher than the controls at concentrations of added nitrateabove 2 mM. Addition of nitrate to plants grown in ammonium,increased nitrate reductase activity more in plants grown fromtriadimenol-treated seeds than controls. However, addition of10µM triadimenol for 24 h to ammonium-grown plants hadlittle effect on enzyme activity, both in the absence as wellas the presence of nitrate. This study demonstrates that triadimenolincreases nitrate reductase activity and nitrate accumulationin the leaves and at least part of the increased enzyme activityis independent of nitrate accumulation. Key words: Triazoles, nitrate content, nitrate reductase activity     

Location of anaerobic respiratory enzyme trimethylamine N-oxide reductase in the cytoplasmic membrane ofEscherichia coli strain K10

Trimethylamine N-oxide (TMAO) reductase, which is anaerobically induced by TMAO, is a terminal enzyme in anaerobic electron transport inEscherichia coli. When the organism was anaerobically grown with TMAO, a marked increase in the specific activity of TMAO reductase was observed mainly in a cell membrane fraction and stopped after exhausting TMAO. On the other hand, activity was moderately increased in a soluble fraction of the cell even after exhaustion of TMAO. Immunoblot analysis with an antiserum against the TMAO reductase purified from the soluble fractions showed that the cells growing with TMAO contained only a membrane-bound enzyme, which has a molecular mass of 94 kDa, while a soluble enzyme with 92 kDa appeared in the stationary growth phase lacking TMAO. Experiments with right-side-out and inside-out vesicles of cytoplasmic membrane indicated that the membrane-bound enzyme faces the cytoplasm. The soluble enzyme was mainly found in the cytoplasm of the cell, but also at a negligible amount in the periplasm. The membrane-bound form of TMAO reductase functioning in anaerobic electron transport seems to be cleaved and released into the cytoplasm as soluble enzyme after exhaustion of TMAO.     

Ammonium Influence on the Growth and Nitrate Reductase Activity of Paul's Scarlet Rose Suspension Cultures

Suspension cultures of Paul's Scarlet rose were grown in two defined media which differed only in their inorganic nitrogen content. Both possessed equal amounts of NO(3) (+) (24 mm), but differed in that NH(4) (+) (0.91 mm) was present in control medium; whereas, no NH(4) (+) was present in the test medium. A comparison of fresh weight increases over a 14-day growth period showed that NH(4) (+) caused a 2-fold stimulation in growth and governed the pattern of development.Ammonium also caused a 2-fold increase in nitrate reductase activity but had little influence on the activity of representative enzymes from the Embden-Meyerhof pathway or citric acid cycle. Thus NH(4) (+) enhanced the nitrate reductase activity which was correlated with increased growth.Ammonium had no influence on the in vitro activity of nitrate reductase which suggested that the stimulatory influence was due to an increased synthesis of the enzyme. The enhanced synthesis did not appear to be due to an increased availability of NO(3) (+) since the uptake of NO(3) (+) by intact cells was not influenced by the presence of NH(4) (+) during the period of most rapid increase in nitrate reductase activity.     

Differential cytochrome content and reductase activity in Geospirillum barnesii strain SeS3

The protein composition, cytochrome content, and reductase activity in the dissimilatory selenate-reducing bacterium Geospirillum barnesii strain SeS3, grown with thiosulfate, nitrate, selenate, or fumarate as the terminal electron acceptor, was investigated. Comparison of seven high-molecular-mass membrane proteins (105.3, 90.3, 82.6, 70.2, 67.4, 61.1, and 57.3 kDa) by SDS-PAGE showed that their detection was dependent on the terminal electron acceptor used. Membrane fractions from cells grown on thiosulfate contained a 70.2-kDa c-type cytochrome with absorbance maxima at 552, 522, and 421 nm. A 61.1-kDa c-type cytochrome with absorption maxima at 552, 523, and 423 nm was seen in membrane fractions from cells grown on nitrate. No c-type cytochromes were detected in membrane fractions of either selenate- or fumarate-grown cells. Difference spectra, however, revealed the presence of a cytochrome b ₅₅₄ (absorption maxima at 554, 523, and 422 nm) in membrane fractions from selenate-grown cells and a cytochrome b ₅₅₆ (absorption maxima at 556, 520, and 416 nm) in membrane fractions from fumarate-grown cells. Analysis of reductase activity in the different membrane fractions showed variability in substrate specificity. However, enzyme activity was greatest for the substrate on which the cells had been grown (e.g., membranes from nitrate-grown cells exhibited the greatest activity with nitrate). These results show that protein composition, cytochrome content, and reductase activity are dependent on the terminal electron acceptor used for growth. Received: 21 August 1996 / Accepted: 24 October 1996     

Membrane and cytoplasmic nitrate reductase of Staphylococcus aureus and application of crossed immunoelectrophoresis.

Specific antiserum to the membrane nitrate reductase of Staphylococcus aureus was derived from immunoprecipitates on crossed immunoelectrophoresis plates. Analysis of the cytoplasmic and membrane forms of the enzyme in cells grown with nitrate and azide indicated their identity, and in each case, the major subunit, Mr 140,000, was converted by trypsin to a polypeptide, Mr 112,000, without loss of enzyme activity or immunological reactivity.     

Role of molybdenum in nitrate reduction by chlorella

Molybdenum is absolutely required for the nitrate-reducing activity of the nicotinamide adenine dinucleotide nitrate reductase complex isolated from Chlorella fusca. The whole enzyme nicotinamide adenine dinucleotide nitrate reductase is formed by cells grown in the absence of added molybdate, but only its first activity (nicotinamide adenine dinucleotide diaphorase) is functional. The second activity of the complex, which subsequently participates also in the enzymatic transfer of electrons from nicotinamide adenine dinucleotide to nitrate (FNH₂-nitrate reductase), depends on the presence of molybdenum. Neither molybdate nor nitrate is required for nitrate reductase synthesis de novo, but ammonia acts as a nutritional repressor of the complete enzyme complex. Under conditions which exclude de novo synthesis of nitrate reductase, the addition of molybdate to molybdenum-deficient cells clearly increases the activity level of this enzyme, thus suggesting in vivo incorporation of the trace metal into the pre-existing inactive apoenzyme.     

Cytochrome spectrum of an obligate anaerobe, Eubacterium lentum.

An obligately anaerobic bacterium, Eubacterium lentum, was shown to contain cytochromes a, b, and c and a carbon monoxide-binding pigment. Extracts of cells grown with hemin gave a typical absorption spectrum for cytochrome c with maxima at 424, 525, and 553 nm. Extracts from cells grown in the absence of hemin also had an absorption peak corresponding to cytochrome b (562 nm) in their reduced versus oxidized spectrum. Extraction of hemes and formation of pyridine hemochromes allowed quantitation of protoheme IX and heme c. Large amounts of cytochrome c masked the presence of cytochrome b in cells grown in medium containing hemin. When cells were grown in the presence of 50 mM nitrate, cytochrome A (606 nm) was detected. In anaerobic extracts of cells grown either with or without nitrate, cytochromes b and c were reduced by formate and oxidized by NO3. Cytochrome a appeared to be partially oxidized by NO3 and completely oxidized by air.     

Effects of vanadium and tungsten on the nitrogen-fixing cyanobacteriumNostoc linckia

The effects of vanadium and tungsten on growth of the heterocystous cyanobacteriumNostoc linckia (Roth.) Born. and the activity of its nitrogenase and nitrate reductase were studied. While vanadate stimulated the growth of molybdate-limited cells and also their acetylene-reducing ability, it did not stimulate nitrate reductase activity. Tungstate inhibited growth in molybdate-limited cells and also their acetylene reducing and nitrate reductase activities. Acetylene reduction response of cells grown in a tungstate-containing medium indicated certain difference between the modes of action of vanadium and molybdenum. Tungstate caused a slight increase in heterocyst frequency both in nitrogen-fixing and nitrate-grown material. Cyanophycin granules and polyhedral bodies disappeared in molybdate-deficient cells in which thick deposition of polyglucan-like granules occurred throughout the breakdown of cytoplasm and the thylakoids.     

Identification of Escherichia coli nitrate reductase as an antigen for a monoclonal antibody with previously unknown specificity

The immunoaffinity chromatography of total membrane proteins from Escherichia coli helped determine the specificity of the monoclonal antibody 3A6 that was obtained upon immunization of mice with nicotinamide nucleotide transhydrogenase preparations and reacted with an unknown E. coli antigen. Proteins with apparent molecular masses of 150, 45, and 20 kDa were isolated and identified by N-terminal sequencing as the subunits of nitrate reductase. This conclusion was confirmed by immunoblotting with the 3A6 antibody of the proteins from the E. coli cells grown upon induction of nitrate reductase. It was shown that the 3A6 antibody specifically recognizes the alpha subunit of nitrate reductase, and the formation of the enzyme-antibody complex does not result in a loss of the enzyme catalytic activity.     

Effects of Molybdate and Selenite on Formate and Nitrate Metabolism in Escherichia coli

The effects of adding molybdate and selenite to a glucose-minimal salts medium on the formation of enzymes involved in the anaerobic metabolism of formate and nitrate in Escherichia coli have been studied. When cells were grown anaerobically in the presence of nitrate, molybdate stimulated the formation of nitrate reductase and a b-type cytochrome, resulting in cells that had the capacity for active nitrate reduction in the absence of formate dehydrogenase. Under the same conditions, selenite in addition to molybdate was required for forming the enzyme system which permits formate to serve as an effective electron donor for nitrate reduction. When cells were grown anaerobically on a glucose-minimal salts medium without nitrate, active hydrogen production from formate as well as formate dehydrogenase activity depended on the presence of both selenite and molybdate. The effects of these metals on the formation of formate dehydrogenase was blocked by chloramphenicol, suggesting that protein synthesis is required for the increases observed. It is proposed that the same formate dehydrogenase is involved in nitrate reduction, hydrogen production, and in aerobic formate oxidation.