Purification of Squash NADH:Nitrate Reductase by Zinc Chelate Affinity Chromatography

NADH:nitrate reductase (EC 1.6.6.1) was isolated and purified from the green cotyledons of 5-day-old squash seedlings (Cucurbita maxima L.). The 10-hour purification procedure consisted of two steps: direct application of crude enzyme to blue Sepharose and specific elution with NADH followed by direct application of this effluent to a Zn²⁺ column with elution by decreasing the pH of the phosphate buffer from 7.0 to 6.2. The high specific activity (100 micromoles per minute per milligram protein) and high recovery (15-25%) of electrophoretically homogeneous nitrate reductase show that the enzyme was not damaged by exposure to the bound zinc. With this procedure, homogeneous nitrate reductase can be obtained in yields of 0.5 milligram per kilogram cotyledons.     

Immunological approach to structural comparisons of assimilatory nitrate reductases

Homogeneous squash cotyledon reduced nicotinamide-adenine dinucleotide (NADH):nitrate reductase (NR) was isolated using blue-Sepharose and polyacrylamide gel electrophoresis. Gel slices containing NR were pulverized and injected into a previously unimmunized rabbit. This process was repeated weekly and antiserum to NR was obtained after four weeks. Analysis of the antiserum by Ouchterlony double diffusion using a blue-Sepharose preparation of NR resulted in a single precipitin band while immunoelectrophoresis revealed two minor contaminants. The antiserum was found to inhibit the NR reaction and the partial reactions to different degrees. When the NADH:NR and the reduced methyl viologen:NR activities were inhibited 90% by specifically diluted antiserum, the reduction of cytochrome c was inhibited 50%, and the reduction of ferricyanide was inhibited only 30%. Antiserum was also used to compare the cross reactivities of NR from squash cotyledons, spinach, corn, and soybean leaves, Chlorella vulgaris, and Neurospora crassa. These tests revealed a high degree of similarity between NADH:NR from the squash and spinach, while NADH:NR from corn and soybean and the NAD(P)H:NR from soybean were less closely related to the squash NADH:NR. The green algal (C. vulgaris) NADH:NR and the fungal (N. crassa) NADPH:NR were very low in cross reactivity and are apparently quite different from squash NADH:NR in antigenicity. Antiserum to N. crassa NADPH:NR failed to give a positive Ouchterlony result with higher plant or C. vulgaris NADH:NR, but this antiserum did inhibit the activity of squash NR. Thus, it can be concluded from these immunological comparisons that all seven forms of assimilatory NR studied here have antigenic determinants in common and are probably derived from a common ancestor. Although these assimilatory NR have similar catalytic characteristics, they appear to have diverged to a great degree in their structural features.     

Development of NAD(P)H: and NADH:Nitrate Reductase Activities in Soybean Cotyledons

The cotyledons of soybean begin to develop photosynthetic capacity shortly after emergence. The cotyledons develop nitrate reductase (NR) activity in parallel with an increase in chlorophyll and a decrease in protein. In crude extracts of 5- to 8-day-old cotyledons, NR activity is greatest with NADH as electron donor. In extracts of older cotyledons, NR activity is greatest with NADPH. Blue-Sepharose was used to purify and separate the NR activities into two fractions. When the blue-Sepharose was eluted with NADPH, NR activity was obtained which was most active with NADPH as electron donor. Assays of the NADPH-eluted NR with different concentrations of nitrate revealed that the highest activity was obtained in 80 millimolar KNO₃. Thus, this fraction has properties similar to the low nitrate affinity NAD(P)H:NR of soybean leaves. When 5- to 8-day-old cotyledons were extracted and purified, further elution of the blue-Sepharose with KNO₃, subsequent to the NADPH elution, yielded an NR fraction most active with NADH. Assays of this fraction with different nitrate concentrations revealed that this NR had a higher nitrate affinity and was similar to the NADH:NR of soybean leaves. The KNO₃-eluted NR fraction which was purified from the extracts of 9- to 14-day-old cotyledons, was most active with NADPH. The analysis of these fractions prepared from the extracts of older cotyledons indicated that residual NAD(P)H:NR contaminated the NADH:NR. Despite this complication, the pattern of development of the purified NR fractions was consistent with the changes observed in the crude extract NR activities. It was concluded that NADH:NR was most active in young cotyledons and that as the cotyledons aged the NAD(P)H:NR became more active.     

Purification of Two Nitrate Reductases from Xanthomonas maltophilia Grown in Aerobic Cultures

Xanthomonas maltophilia ATCC 17666 is an obligate aerobe that accumulates nitrite when grown on nitrate. Spectra of membranes from nitrate-grown cells exhibited b-type cytochrome peaks and A_615-630 indicative of d-type cytochrome but no absorption peaks corresponding to c-type cytochromes. The nitrate reductase (NR) activity was located in the membrane fraction. Triton X-100-extracted reduced methyl viologen-NRs were purified on DE-52, hydroxylapatite, and Sephacryl S-300 columns to specific activities of 52 to 67 μmol of nitrite formed per min per mg of protein. The cytochrome-containing NR_I separated on sodium dodecyl sulfate-polyacrylamide gel electrophoresis into a 135-kDa α-subunit, a 64-kDa β-subunit, and a 23-kDa γ-subunit with relative band intensities indicative of a 1:1:1 α/β/γ subunit ratio and a M_r of 222,000. The electronic spectrum of dithionite-reduced purified NR displayed peaks at 425, 528, and 558 nm, indicative of the presence of a cytochrome b, an interpretation consistent with the pyridine hemochrome spectrum formed. The cytochrome b of the NR was reduced under anaerobic conditions by menadiol and oxidized by nitrate with the production of nitrite. This NR contained 0.96 Mo, 12.5 nonheme iron, and 1 heme per 222 kDa: molybdopterin was detected with the Neurospora crassa nit-1 assay. A smaller reduced methyl viologen-NR (169 kDa), present in various concentrations in the Triton X-100 preparations, lacked a cytochrome spectrum and did not oxidize menadiol. The characteristics of the NRs and the absence of c-type cytochromes provide insights into why X. maltophilia accumulates nitrite.     

Purification and Characterization of the Pea Chloroplast Pyruvate Dehydrogenase Complex : A Source of Acetyl-CoA and NADH for Fatty Acid Biosynthesis

The pyruvate dehydrogenase complex has been purified 76-fold, to a specific activity of 0.6 μmoles per minute per milligram protein, beginning with isolated pea (Pisum sativum L. var Little Marvel) chloroplasts. Purification was accomplished by rate zonal sedimentation, polyethyleneglycol precipitation, and ethyl-agarose affinity chromatography. Characterization of the substrates as pyruvate, NAD⁺, and coenzyme-A and the products as NADH, CO₂, and acetyl-CoA, in a 1:1:1 stoichiometry unequivocally established that activity was the result of the pyruvate dehydrogenase complex. Immunochemical analysis demonstrated significant differences in structure and organization between the chloroplast pyruvate dehydrogenase complex and the more thoroughly characterized mitochondrial complex. Chloroplast complex has a higher magnesium requirement and a more alkaline pH optimum than mitochondrial complex, and these properties are consistent with light-mediated regulation in vivo. The chloroplast pyruvate dehydrogenase complex is not, however, regulated by ATP-dependent inactivation. The properties and subcellular localization of the chloroplast pyruvate dehydrogenase complex are consistent with its role of providing acetyl-CoA and NADH for fatty acid synthesis.     

beta-Oxidation and Glyoxylate Cycle Coupled to NADH: Cytochrome c and Ferricyanide Reductases in Glyoxysomes

Glyoxysomes isolated from castor bean (Ricinus communis L., var Hale) endosperm had NADH:ferricyanide reductase and NADH:cytochrome c reductase activities averaging 720 and 140 nanomole electrons/per minute per milligram glyoxysomal protein, respectively. These redox activities were greater than could be attributed to contamination of the glyoxysomal fractions in which 1.4% of the protein was mitochondrial and 5% endoplasmic reticulum. The NADH:ferricyanide reductase activity in the glyoxysomes was greater than the palmitoyl-coenzyme A (CoA) oxidation activity which generated NADH at a rate of 340 nanomole electrons per minute per milligram glyoxysomal protein. Palmitoyl-CoA oxidation could be coupled to ferricyanide or cytochrome c reduction. Complete oxidation of palmitoyl-CoA, yielding 14 nanomole electrons/per nanomole palmitoyl-CoA, was demonstrated with the acceptors, NAL, cytochrome c, and ferricyanide. Malate was also oxidized by glyoxysomes, if acetyl-CoA, ferricyanide, or cytochrome c was present. Glyoxysomal NADH:ferricyanide reductase activity has the capacity to support the combined rates of NADH generation by β-oxidation and the glyoxylate cycle.     

Activation of Thalassiosira pseudonana nadh: Nitrate reductase

NADH: nitrate reductase (NR) has been isolated in both active and inactive states, and both could be purified using blue-Sepharose. The state of activation of the enzyme depended on the presence or absence of agents such as cysteine or EDTA during the assay. When NR was assayed, the addition of activator before NADH led to maximum activity. Therefore, the reduced NR appeared to be inactivated during the assay in the absence of activator. Inactivation may have occurred via a mechanism similar to the inactivation of lipoamide dehydrogenase by trace metals, such as CU²⁺. The activation of NR by cysteine or EDTA was interpreted as protection of the reduced enzyme due to chelation of trace metals in the assay solution by the activators.     

Properties of Bromphenol Blue as an Electron Donor for Higher Plant NADH: Nitrate Reductase

Bromphenol blue, which was reduced with dithionite, was found to support nitrate reduction catalyzed by squash NADH:nitrate reductase at a rate about 5 times greater than NADH with freshly prepared enzyme and 10 times or more with enzyme having been frozen and thawed. Kinetic analysis of bromphenol blue as a substrate for squash nitrate reductase yielded apparent K_m values of 60 micromolar for bromphenol blue at 10 millimolar nitrate and 500 micromolar for nitrate at 0.2 millimolar bromphenol blue. With the same preparation of enzyme the apparent K_m values were 9 micromolar for NADH at 10 millimolar nitrate and 50 micromolar nitrate at 0.1 millimolar NADH. Bromphenol blue was found to be a noncompetitive inhibitor versus NADH with a K_i of 0.3 millimolar. When squash NADH:nitrate reductase activity was inactivated with p-hydroxymercuribenzoate or denatured by heating at 40°C, the bromphenol blue nitrate reductase activity was not lost. These results were taken to indicate that bromphenol blue and NADH donated electrons to nitrate reductase at different sites. When monoclonal antibodies prepared against corn and squash nitrate reductases were used to inhibit the nitrate reductase activities supported by NADH, bromphenol blue, and methyl viologen, differential inhibition was found which tended to indicate that the three electron donors were interacting with the enzyme at different sites. One monoclonal antibody prepared against squash nitrate reductase inhibited all three activities of both corn and squash nitrate reductase. It appears this antibody may bind to a highly conserved antigenic site in the nitrate binding region of the enzyme.     

Expression in Escherichia coli of Cytochrome c Reductase Activity from a Maize NADH:Nitrate Reductase Complementary DNA

A cDNA clone was isolated from a maize (Zea mays L. cv W64A×W183E) scutellum λgt11 library using maize leaf NADH:nitrate reductase Zmnr1 cDNA clone as a hybridization probe; it was designated Zmnr1S. Zmnr1S was shown to be an NADH:nitrate reductase clone by nucleotide sequencing and comparison of its deduced amino acid sequence to Zmnr1. Zmnr1S, which is 1.8 kilobases in length and contains the code for both the cytochrome b and flavin adenine dinucleotide domains of nitrate reductase, was cloned into the EcoRI site of the Escherichia coli expression vector pET5b and expressed. The cell lysate contained NADH:cytochrome c reductase activity, which is a characteristic partial activity of NADH:nitrate reductase dependent on the cytochrome b and flavin adenine dinucleotide domains. Recombinant cytochrome c reductase was purified by immunoaffinity chromatography on monoclonal antibody Zm2(69) Sepharose. The purified cytochrome c reductase, which had a major size of 43 kilodaltons, was inhibited by polyclonal antibodies for maize leaf NADH:nitrate reductase and bound these antibodies when blotted to nitrocellulose. Ultraviolet and visible spectra of oxidized and NADH-reduced recombinant cytochrome c reductase were nearly identical with those of maize leaf NADH:nitrate reductase. These two enzyme forms also had very similar kinetic properties with respect to NADH-dependent cytochrome c and ferricyanide reduction.     

Immunochemical Characterization of Nitrate Reductase Forms from Wild-Type (cv Williams) and nr(1) Mutant Soybean

Soybean (Glycine max L. Merr.) leaves contain two forms of nitrate reductase (NR)—NAD(P)H:NR and NADH:NR. Wild-type (cv Williams), nr₁ mutant and an unrelated cultivar (Prize) were grown with either no N source or with nitrate. Crude extracts were assayed for NR activities and the enzyme forms were purified on blue Sepharose. Analyses were done by polyacrylamide gel electrophoresis and `Western blotting' using antibodies specific for NR. NAD(P)H:NR was identified as the constitutive NR present in wild-type and Prize, but was absent from the mutant. All three soybean lines contained nitrate-inducible NADH:NR with highest activity at pH 7.5. The results showed that NAD(P)H:NR and constitutive NR were one in the same and confirmed the presence of NADH:NR with pH 7.5 optimum.     

The Nitric Oxide Production in the Moss Physcomitrella patens Is Mediated by Nitrate Reductase

During the last 20 years multiple roles of the nitric oxide gas (•NO) have been uncovered in plant growth, development and many physiological processes. In seed plants the enzymatic synthesis of •NO is mediated by a nitric oxide synthase (NOS)-like activity performed by a still unknown enzyme(s) and nitrate reductase (NR). In green algae the •NO production has been linked only to NR activity, although a NOS gene was reported for Ostreococcus tauri and O. lucimarinus, no other Viridiplantae species has such gene. As there is no information about •NO synthesis neither for non-vascular plants nor for non-seed vascular plants, the interesting question regarding the evolution of the enzymatic •NO production systems during land plant natural history remains open. To address this issue the endogenous •NO production by protonema was demonstrated using Electron Paramagnetic Resonance (EPR). The •NO signal was almost eliminated in plants treated with sodium tungstate, which also reduced the NR activity, demonstrating that in P. patens NR activity is the main source for •NO production. The analysis with confocal laser scanning microscopy (CLSM) confirmed endogenous NO production and showed that •NO signal is accumulated in the cytoplasm of protonema cells. The results presented here show for the first time the •NO production in a non-vascular plant and demonstrate that the NR-dependent enzymatic synthesis of •NO is common for embryophytes and green algae.     

Purification of NADH-Nitrate Reductase by Affinity Chromatography

Assimilatory nitrate reductase (NADH: nitrate oxidoreductase, EC 1.6.6.1) from Chlorella vulgaris has been purified to electrophoretic homogeneity with an overall yield of 60% by a procedure that utilizes blue dextran-agarose as an affinity column. Nitrate reductase binds to blue dextran and is not eluted in the presence of high ionic strength buffer but is rapidly eluted in the presence of μmolar concentrations of NADH.     

Monoclonal antibody-based immunoaffinity chromatography for purifying corn and squash NADH: nitrate reductases. Evidence for an interchain disulfide bond in nitrate reductase

NADH: nitrate reductase (EC 1.6.6.1) (NR) is present in small amounts in plant tissues and its polypeptide in inherently labile. Consequently, NR is difficult to purify. We have generated 20 monoclonal antibodies (McAb) for corn and squash NR and selected two for use in immunoaffinity chromatography. Squash McAb CM 15(11) and corn McAb ZM 2(69)9, which both bind corn and squash NR, were covalently coupled to Sepharose and used for purification of NR with elution of the purified enzyme by a pH 11 buffer. Although this procedure yielded highly purified NR, its activity was diminished by the pH 11 treatment. When corn leaf crude extract was applied to McAb CM 15(11)-Sepharose, NR bound and could be eluted in homogeneous form by its substrate, NADH. Corn leaf NR prepared by substrate elution retained a high level of NADH: NR activity. Immunoaffinity-purified corn and squash NR were shown to have an interchain disulfide bond as well as a reactive thiol group. These results are discussed in relation to the recently obtained sequences of NR clones and suggestions made for site-directed mutagenesis experiments to aid in identifying the cysteine residues of NR associated with these features of the enzyme.     

Nitrogen Redox Metabolism of a Heterotrophic, Nitrifying-Denitrifying Alcaligenes sp. from Soil

Metabolic characteristics of a heterotrophic, nitrifier-denitrifier Alcaligenes sp. isolated from soil were further characterized. Pyruvic oxime and hydroxylamine were oxidized to nitrite aerobically by nitrification-adapted cells with specific activities (V_max) of 0.066 and 0.003 μmol of N × min⁻¹ × mg of protein⁻¹, respectively, at 22°C. K_m values were 15 and 42 μM for pyruvic oxime and hydroxylamine, respectively. The greater pyruvic oxime oxidation activity relative to hydroxylamine oxidation activity indicates that pyruvic oxime was a specific substrate and was not oxidized appreciably via its hydrolysis product, hydroxylamine. When grown as a denitrifier on nitrate, the bacterium could not aerobically oxidize pyruvic oxime or hydroxylamine to nitrite. However, hydroxylamine was converted to nearly equimolar amounts of ammonium ion and nitrous oxide, and the nature of this reaction is discussed. Cells grown as heterotrophic nitrifiers on pyruvic oxime contained two enzymes of denitrification, nitrate reductase and nitric oxide reductase. The nitrate reductase was the dissimilatory type, as evidenced by its extreme sensitivity to inhibition by azide and by its ability to be reversibly inhibited by oxygen. Cells grown aerobically on organic carbon sources other than pyruvic oxime contained none of the denitrifying enzymes surveyed but were able to oxidize pyruvic oxime to nitrite and reduce hydroxylamine to ammonium ion.     

Partial Purification of the NADH-Nitrate Reductase Complex from Chlorella pyrenoidosa

The nitrate reductase complex from Chlorella pyrenoidosa has been purified by a procedure which includes as main steps, ammonium sulfate fractionation, polyethylene glycol treatment, and DEAE-cellulose chromatography. The Michaelis constants for NADH, FAD, and NO₃⁻ in the NADH-nitrate reductase assay are 10 μm, 2.6 μm, and 0.23 mm, respectively. Heat treatment exerts varying effects on the enzymatic activities associated with the nitrate reductase complex.     

Characterization of Nitrate Reductase from Corn Leaves (Zea mays cv W64A x W182E) : Two Molecular Forms of the Enzyme

The primary leaves from corn seedlings grown for 6 days were harvested, frozen with liquid N₂ and extracted in a Tris buffer (pH 8.5, 250 millimolar) containing 1 millimolar dithiothreitol, 10 millimolar cysteine, 1 millimolar EDTA, 20 micromolar flavin adenine dinucleotide and 10% (v/v) glycerol. Nitrate reductase (NR) in the crude extract was stable for several days at 0°C and for several months at −80°C. The enzyme was purified using (NH₄)₂SO₄ fractionation, brushite-hydroxyl-apatite chromatography and blue-sepharose affinity chromatography. The enzyme was eluted from the blue-sepharose column with a linear gradient of NADH (0-100 micromolar) or with 0.3 molar KNO₃. About 10% of the original activity was recovered with NADH (NADH-NR). It had a specific activity of about 60 to 70 units (micromoles NO₂⁻ per minute per milligram protein). A sequential elution with NADH followed by KNO₃ (0.3 molar) or KCl (0.3 molar) yielded 2 peaks. Rechromatography of each peak gave two peaks again. These results indicate that we are dealing with two forms of the same enzyme rather than two different NR proteins. The two NRs had different molecular weights as judged by chromatography on Toyopearl. The NADH-NR was more sensitive than the NO₃⁻-NR to antibody prepared against barley leaf NR. In Ouchterlony assays a single precipitin line, with completely fused boundaries, was observed.     

Purification and Properties of NADH-Dependent 5,10-Methylenetetrahydrofolate Reductase (MetF) from Escherichia coli

A K-12 strain of Escherichia coli that overproduces methylenetetrahydrofolate reductase (MetF) has been constructed, and the enzyme has been purified to apparent homogeneity. A plasmid specifying MetF with six histidine residues added to the C terminus has been used to purify histidine-tagged MetF to homogeneity in a single step by affinity chromatography on nickel-agarose, yielding a preparation with specific activity comparable to that of the unmodified enzyme. The native protein comprises four identical 33-kDa subunits, each of which contains a molecule of noncovalently bound flavin adenine dinucleotide (FAD). No additional cofactors or metals have been detected. The purified enzyme catalyzes the reduction of methylenetetrahydrofolate to methyltetrahydrofolate, using NADH as the reductant. Kinetic parameters have been determined at 15°C and pH 7.2 in a stopped-flow spectrophotometer; the K_m for NADH is 13 μM, the K_m for CH₂-H₄folate is 0.8 μM, and the turnover number under V_max conditions estimated for the reaction is 1,800 mol of NADH oxidized min⁻¹ (mol of enzyme-bound FAD)⁻¹. NADPH also serves as a reductant, but exhibits a much higher K_m. MetF also catalyzes the oxidation of methyltetrahydrofolate to methylenetetrahydrofolate in the presence of menadione, which serves as an electron acceptor. The properties of MetF from E. coli differ from those of the ferredoxin-dependent methylenetetrahydrofolate reductase isolated from the homoacetogen Clostridium formicoaceticum and more closely resemble those of the NADH-dependent enzyme from Peptostreptococcus productus and the NADPH-dependent enzymes from eukaryotes.     

Nitrate Reductase Activity in Soybeans (Glycine max [L.] Merr.): II. Energy Limitations

Growth chamber studies with soybeans (Glycine max [L.] Merr.) were designed to determine the relative limitations of NO₃⁻, NADH, and nitrate reductase (NR) per se on nitrate metabolism as affected by light and temperature. Three NR enzyme assays (+NO₃⁻in vivo, −NO₃⁻in vivo, and in vitro) were compared. NR activity decreased with all assays when plants were exposed to dark. Addition of NO₃⁻ to the in vivo NR assay medium increased activity (over that of the −NO₃⁻in vivo assay) at all sampling periods of a normal day-night sequence (14 hr-30 C day; 10 hr-20 C night), indicating that NO₃⁻ was rate-limiting. The stimulation of in vivo NR activity by NO₃⁻ was not seen in plants exposed to extended dark periods at elevated temperatures (16 hr-30 C), indicating that under those conditions, NO₃⁻ was not the limiting factor. Under the latter condition, in vitro NR activity was appreciable (19 μmol NO₂⁻ [g fresh weight, hr]⁻¹) suggesting that enzyme level per se was not the limiting factor and that reductant energy might be limiting.     

Effect of the electrochemical proton gradient and anions on the ATPase activity of soybean submitochondrial particles

Submitochondrial particles from soybean (Glycine max L. cv Jupiter) hypocotyls with an ATPase activity of 0.3 to 1.0 micromole per minute per milligram were prepared by sonication with Mg-ATP. The particles catalyzed ATP synthesis with NADH and succinate; the ratios of ATP/O with these substrates were 1.0 and 0.1, respectively. As monitored by oxonol-VI, the particles built up and maintained a membrane potential that was higher with NADH than with succinate or Mg-ATP. The ATPase activity of the particles increased two to threefold by preincubation with 50 millimolar phosphate at a temperature of 38°C. The increase in ATPase activity became higher (five to sixfold) when particles were preincubated with Mg-ATP plus phosphate. Under the latter conditions, collapse of μH by carbonyl cyanide p-trifluoromethoxyphenylhydrazone prevented the activation. An increase in ATPase activity of the particles was also observed with NADH and succinate, although activation was lower with succinate. With these substrates, phosphate did not increase ATPase activation. When particles were preincubated with Mg-ATP, anions that stimulate ATP hydrolysis (malate, malonate, and bicarbonate) had an activating effect similar to that of phosphate. The data suggest that the soybean mitochondrial ATPase can be activated by μH but that this activation is increased by the binding of certain anions to a conformation of the enzyme that appears during hydrolytic cycles.     

Effect of Inorganic Orthophosphate on in Vitro Activity of NADH-Nitrate Reductase Isolated from 2-Row Barley Leaves

Inorganic orthophosphate (25 millimolar in assay media; Pi) was found to increase in vitro activity of NADH-nitrate reductase (NR) isolated from 2-row barley (Hordeum vulgare L.) leaves with a saturating concentration of nitrate (2 millimolar) but to decrease it with low nitrate levels (<0.1 millimolar). The response to nitrate concentrations was Pi specific. The Lineweaver-Burk plot showed that Pi increases the apparent K_m for nitrate as well as V_max, whereas it does not alter the K_m for NADH significantly. These results suggest that the interaction between a molybdenum site of the enzyme and Pi results in alteration of the properties of NR molecule.