185W-labelled nitrate reductase from Chlorella

By adding ¹⁸⁵W-tungstate to a Chlorella culture, it has beenpossible to incorporate this metal into the nitrate reductasecomplex. The W-labelled enzyme was completely inactive as nitratereductase, but maintained unaffected its diaphorase activity.In vivo incorporation of tungsten into the enzyme was competitivelyhindered by molybdenum. ¹ This work was supported by a grant from the Instituto de EstudiosNucleares, J.E.N., Spain. (Received July 6, 1971; )     

Physical studies on assimilatory nitrate reductase from Chlorella vulgaris.

Assimilatory nitrate reductase (EC 1.6.6.1 NADH:nitrate oxidoreductase) from Chlorella vulgaris purified by affinity chromatography was found to be homogeneous as judged by electrophoresis on sodium dodecyl sulfate-polyacrylamide gel and by analytical ultracentrifugal techniques. The molecular weight of the intact enzyme and that of the enzyme dissociated in 6 M GuHCl, determined by sedimentation equilibrium studies, were 280,000 +/- 10,000 and 90,000 +/- 5,000, respectively. Comparable values were obtained using the S20,w value and the D20,w values in Svedberg's equation. The D20,w values were determined by laser light-scattering measurements. Active enzyme centrifugation showed that the monomer is an active species. A quantitative re-evaluation of the prosthetic groups present (FAD, heme, and molybdenum) was also made and was consistent with the conclusion that the active monomer contains three subunits as previously deduced by Solomonson et al. ((1975) J. Biol. Chem. 250, 4120). Electron micrographs showed images which corresponded to three subunits, supporting the data obtained by hydrodynamic studies. The enzyme is not cigar-shaped, as previously surmised, but has a roughly globular structure.     

Evidence for a plasma-membrane-bound nitrate reductase involved in nitrate uptake of Chlorella sorokiniana

Anti-nitrate-reductase (NR) immunoglobulin-G (IgG) fragments inhibited nitrate uptake into Chlorella cells but had no affect on nitrite uptake. Intact anti-NR serum and preimmune IgG fragments had no affect on nitrate uptake. Membrane-associated NR was detected in plasma-membrane (PM) fractions isolated by aqueous two-phase partitioning. The PM-associated NR was not removed by sonicating PM vesicles in 500 mM NaCl and 1 mM ethylenediaminetetraacetic acid and represented up to 0.8% of the total Chlorella NR activity. The PM NR was solubilized by Triton X-100 and inactivated by Chlorella NR antiserum. Plasma-membrane NR was present in ammonium-grown Chlorella cells that completely lacked soluble NR activity. The subunit sizes of the PM and soluble NRs were 60 and 95 kDa, respectively, as determined by sodium-dodecyl-sulfate electrophoresis and western blotting.Abbreviations EDTA ethylenediaminetetraacetic acid - FAD flavine-adenine dinucleotide - IgG immunoglobulin G - NR nitrate reductase - PM plasma membrane - TX-100 Triton X-100     

The effect of vanadium on nitrate reductase of Chlorella vulgaris

Added vanadate ions inhibit purified nitrate reductase from Chlorella vulgaris by reacting with the enzyme in a manner rather similar to that of HCN. Thus vanadate, like HCN, forms an inactive complex with the reduced enzyme, and this inactivated enzyme can be reactivated rapidly by adding ferricyanide. The inactive vanadate enzyme complex is less stable than the inactive HCN complex, and the two can be distinguished by the fact that EDTA causes a partial reactivation of the former, but not of the latter. Vanadate can also cause an increase in HCN formation by intact Chlorella vulgaris cells. When these cells were incubated with vanadate, their nitrate reductase was reversibly inactivated, and all of this inactive enzyme could be shown to be the HCN complex rather than the vanadate complex. When HCN and vanadate are both present, the HCN-inactivated enzyme, being more stable, will be formed in preference to the vanadate-inactivated enzyme.Abbreviation EDTA ethylenediamine tetraacetate     

Spectroscopic, thermodynamic and kinetic properties of Candida nitratophila nitrate reductase.

HL-60 cells possess a 60 kDa Ca2(+)-binding protein that is contained in a discrete subcellular compartment, referred to as calciosomes. Subcellular fractionation studies have suggested that, in HL-60 cells, this intracellular compartment is an Ins(1,4,5)P3-sensitive Ca2+ store. In order to investigate the structural relationship of the 60 kDa Ca2(+)-binding protein of HL-60 cells to other Ca2(+)-binding proteins, we have purified the protein by ammonium sulphate extraction, acid precipitation, and DEAE-cellulose and phenyl-Sepharose column chromatography. The N-terminal sequence of the protein shows 93% identity with rabbit muscle calreticulin, a recently cloned sarcoplasmic reticulum Ca2(+)-binding protein. No amino acid sequence similarity with calsequestrin was found, although the purified protein cross-reacted with anti-calsequestrin antibodies. The calreticulin-related protein of HL-60 cells might play a role as an intravesicular Ca2(+)-binding protein of an Ins(1,4,5)P3-sensitive Ca2+ store.     

Reversible inactivation of nitrate reductase in Chlorella vulgaris in vivo

Summary The NADH-nitrate oxidoreductase of Chlorella vulgaris has an inactive form which has previously been shown to be a cyanide complex of the reduced enzyme. This inactive enzyme can be reactivated by treatment with ferricyanide in vitro. In the present study, the activation state of the enzyme was determined after different prior in vivo programs involving environmental variations. Oxygen, nitrate, light and CO₂ all affect the in vivo inactivation of the enzyme in an interdependent manner. In general, the inactivation is stimulated by O₂ and inhibited by nitrate and CO₂. Light may stimulate or inhibit, depending on conditions. Thus, the effects of CO₂ and nitrate (inhibition of reversible inactivation) are clearly manifested only in the light. In contrast, light stimulates the inactivation in the presence of oxygen and the absence of CO₂ and nitrate. Since the inactivation of the enzyme requires HCN and NADH, and it is improbable that O₂ stimulates NADH formation, it is reasonable to conclude that HCN is formed as the result of an oxidation reaction (which is stimulated by light). The formation of HCN is probably stimulated by Mn²⁺, since the formation of reversibly-inactivated enzyme is impaired in Mn²⁺-deficient cells. The prevention of enzyme inactivation by nitrate in vivo is in keeping with previous in vitro results showing that nitrate prevents inactivation by maintaining the enzyme in the oxidized form. A stimulation of nitrate uptake by CO₂ and light could account for the effect of CO₂ (prevention of inactivation) which is seen mainly in the presence of nitrate and light. Ammonia added in the presence of nitrate has the same effect on the enzyme as removing nitrate (promotion of reversible inactivation). Ammonia added in the absence of nitrate has little extra effect. It is therefore likely that ammonia acts by preventing nitrate uptake. The uncoupler, carbonylcyanide-m-chloro-phenylhydrazone, causes enzyme inactivation because it acts as a good HCN precursor, particularly in the light. Nitrite, arsenate and dinitrophenol cause an enzyme inactivation which can not be reversed by ferricyanide in crude extracts. This suggests that there are at least two different ways in which the enzyme can be inactivated rather rapidly in vivo.     

Reversible inactivation by NADH and ADP on Chlorella fusca nitrate reductase

The active form of $\text{Chlorella fusca}$ nitrate reductase can be reversibly converted into its inactive form by reduction with NADH in the presence of ADP. Under the experimental conditions used, no inactivation occurs when nitrate is simultaneously present or when the nucleotides act isolately, the inactivating effect being maximal at a concentration of ADP (0.3 mM) equimolecular with that of NADH. The inactive enzyme thus attained can be completely reactivated by reoxidation with ferricyanide. The redox state of the pyridine nucleotide and the phosphorylation degree of the adenine nucleotide are critical for the inactivation process to ensue, since neither NAD⁺ nor AMP or ATP do exert any effect. ADP is also a powerful, although rather unspecific, protector against thermal inactivation of the NADH-diaphorase moiety of the NADH-nitrate reductase complex.     

Activation,synthesis and turnover of nitrate reductase controlled by nitrate and ammonium in Chlorella vulgaris

Cells of Anacystis nidulans grown at 25 or 30°C were examined both by thin-section and freeze-fracture electron microscopy. Cells grown at either temperature appeared similar when fixed at the growth temperature prior to observation. When cells were chilled to near 0°C for 30 min prior to fixation, those previously grown at 25° appeared unchanged as judged by thin sectioning while those grown at 39° showed considerable morphological alteration. Freeze fracture showed particle aggregation (more pronounced in 39°-grown cells) indicating lipid-phase separation in cells chilled prior to fixation. The phase separation was totally reversed by rewarming the chilled, 25°-grown cells to their growth temperature but was only partially reversed by rewarming chilled, 39°-grown cells. These results correlate with other effects of chilling seen in Anacystis cells grown at different temperatures.     

Assimilatory nitrate reductase from Chlorella. Effect of ionic strength and pH on catalytic activity

Initial velocity studies of Chlorella nitrate reductase showed that increased ionic strength stimulated NADH:nitrate reductase activity by increasing both Vmax and Km for nitrate. Examination of the effect of ionic strength on the various partial activities of nitrate reductase revealed that while NADH:ferricyanide and reduced methyl viologen:nitrate reductase activities were unaffected by ionic strength, NADH:cytochrome c and reduced flavin:nitrate reductase activities were inhibited and stimulated by increased ionic strength, respectively. Comparison of the rates for the partial activities indicated electron transfer from heme to molybdenum to be the rate-limiting step in enzyme turnover. The pH optimum for NADH:nitrate reductase activity was found to be 7.9 while values for the partial activities ranged from 5.5 to 8.1. Phosphate was found to stimulate both NADH:nitrate and reduced methyl viologen:nitrate reductase activities indicating the molybdenum center as the site of interaction.     

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.     

The respiratory nitrate reductase from Paracoccus denitrificans. Molecular characterisation and kinetic properties

The respiratory nitrate reductase from Paracoccus denitrificans has been purified in the non-ionic detergent Nonidet P-40. The enzyme comprises three polypeptides, alpha, beta and gamma with estimated relative molecular masses of 127 000, 61 000 and 21 000. Duroquinol or reduced-viologen compounds acted as the reducing substrates. The nitrate reductase contained a b-type cytochrome that was reduced by duroquinol and oxidised by nitrate. A preparation of the enzyme that lacked both detectable b-type cytochrome and the gamma subunit was obtained from a trailing peak of nitrate reductase activity collected from a gel filtration column. Absence of the gamma subunit correlated with failure to use duroquinol as reductant; activity with reduced viologens was retained. It is concluded that in the plasma membrane of P. denitrificans the gamma subunit catalyses electron transfer to the alpha and beta subunits of nitrate reductase from ubiquinol which acts as a branch point in the respiratory chain. A new assay was introduced for both nitrate and quinol-nitrate oxidoreductase activity. Diaphorase was used to couple the oxidation of NADH to the production of duroquinol which acted as electron donor to nitrate reductase. Under anaerobic conditions absorbance changes at 340 nm were sensitive to nitrate concentrations in the low micromolar range. This coupled assay was used to determine that the purified enzyme had Km(NO-3) of 13 microM and a Km of 470 microM for ClO-3, an alternative substrate. With viologen substrates Km(NO-3) of 283 microM and Km(ClO-3) of 470 microM were determined; the enzymes possessed a considerably higher Vmax with either NO-3 or ClO-3 than was found when duroquinol was substrate. Azide was a competitive inhibitor of nitrate reduction in either assay system (Ki = 0.55 microM) but 2-n-heptyl-4-hydroxyquinoline N-oxide was effective only with the complete three-subunit enzyme and duroquinol as substrate, consistent with a site of action for this inhibitor on the b-type cytochrome. The low Km for nitrate observed in the duriquinol assay is comparable with the apparent Km(NO-3) recently reported for intact cells of P. denitrificans [Parsonage, D., Greenfield, A. J. & Ferguson, S. J. (1985) Biochim. Biophys. Acta 807, 81-95]. This similarity is discussed in terms of a possible requirement for a nitrate transport system. The nitrate reductase system from P. denitrificans is compared with that from Escherichia coli.     

Pyridine nucleotide specificity and other properties of purified nitrate reductase from Chlorella variegata

Nitrate reductase (NR) (EC 1.6.6.2) from Chlorella variegata 211/10d has been purified by blue sepharose affinity chromatography. The enzyme can utilise NADH or NADPH for nitrate reduction with apparent K _m values of 11.5 M and 14.5 M, respectively. Apparent K _m values for nitrate are 0.13 mM (NADH-NR) and 0.14 mM (NADPH-NR). The diaphorase activity of the enzyme is inhibited strongly by parachloromercuribenzoic acid; NADH or NADPH protects the enzyme against this inhibition. NR proper activity of the enzyme is partially inactive after extraction and may be activated after the addition of ferricyanide. The addition of NAD(P)H and cyanide causes a reversible inactivation of the NR proper activity although preincubation with either NADH or NADH and ADP has no significant effect.Abbreviations NR Nitrate reductase - FAD Flavin-adenine dinucleotide - FMN Riboflavin 5-phosphate - p-CMB para-Chloromercuribenzoic - BV Benzyl viologen     

Kinetics of some electron-transfer reactions in biological Photosystems II. Study of intramolecular electron-transfer rates between ferredoxin-NADP reductase, NADP radical and oxidized ferredoxin

It has been shown by the pulse radiolysis technique that radiation-generated NADP free radicals (NADP·) first combine with ferredoxin-NADP reductase and then transfer the odd electron by a fast intramolecular process to the enzyme flavin moiety yielding the semiquinone (ferredoxin-NADP reductase, FNR-FADH·). The corresponding first-order rate constant k₁₅ varies with ionic strength from 2.6·10³ s⁻¹ at I = 0.66 M to 2.3·10⁴ s⁻¹ at I = 0.005 M In the presence of ferredoxin-NADP reductase-bound oxidized ferredoxin, the electron cascades, thus further reducing the ferredoxin. The transfer of the electron from the flavin semiquinone (ferredoxin-NADP reductase, FNR-FADH·) to the bound oxidized ferredoxin proceeds at a rate of k₁₈ = 2.36 s⁻¹. This process approaches an equilibrium condition which is in favor of the reverse reaction suggesting that k₋₁₈ > k₁₈.     

Pre-steady-state kinetic analysis of recombinant Arabidopsis NADH:nitrate reductase: rate-limiting processes in catalysis

Recombinant Arabidopsis NADH:nitrate reductase was expressed in Pichia pastoris using fermentation. Large enzyme quantities were purified for pre-steady-state kinetic analysis, which had not been done before with any eukaryotic nitrate reductase. Basic biochemical properties of recombinant nitrate reductase were similar to natural enzyme forms. Molybdenum content was lower than expected, which was compensated for by activity calculation on molybdenum basis. Stopped-flow rapid-scan spectrophotometry showed that the enzyme FAD and heme were rapidly reduced by NADH with and without nitrate present. NADPH reduced FAD at less than one-tenth of NADH rate. Reaction of NADH-reduced enzyme with nitrate yielded rapid initial oxidation of heme with slower oxidation of flavin. Rapid-reaction freeze-quench EPR spectra revealed molybdenum was maintained in a partially reduced state during turnover. Rapid-reaction chemical quench for quantifying nitrite production showed that the rate of nitrate reduction was initially greater than the steady-state rate, but rapidly decreased to near steady-state turnover rate. However, rates of internal electron transfer and nitrate reduction were similar in magnitude with no one step in the catalytic process appearing to be much slower than the others. This leads to the conclusion that the catalytic rate is determined by a combination of rates with no overall rate-limiting individual process.     

Purification and steady-state kinetic analysis of yeast thiosulfate reductase.

Thiosulfate reductase has been purified approximately 70-fold from an extract of bakers' yeast. An enzyme with a molecular weight of 17,000, a Stokes radius of 19 Å, and a pI of 5.1 was obtained. Initial velocity and inhibition studies indicate that the substrates add in a random fashion. Further evidence suggests that the rapid-equilibrium assumption is not totally applicable. The enzyme has two distinct but closely situated substrate binding sites—one for compounds with an RSO₃^? structure and one for the sulfhydryl substrate.