Arginine and lysine residues as NADH-binding sites in NADH-nitrate reductase from spinach.

Chemical modifications of spinach leaf nitrate reductase, and its 28,000 M(r) fragment with phenylglyoxal, 2,3-butanedione and pyridoxal phosphate reduce the catalytic activity of the enzyme. The kinetics of the modification indicate a rapid inactivation followed by a slower rate of inactivation. NADH-nitrate reductase, NADH-cytochrome c reductase and NADH-ferricyanide reductase activities of the nitrate reductase complex are inactivated at a faster rate when compared to the loss of FMNH2-nitrate reductase and reduced methyl viologen (MVH)-nitrate reductase activities. NADH protects the inactivation of NADH-ferricyanide reductase activity of the 28,000 M(r) fragment of nitrate reductase. These data suggest that nitrate reductase contains active sites of arginine and lysine residues that are involved in the NADH binding site of the enzyme.     

Nitrate reductase-deficient mutants in barley: enzyme stability and peptide mapping

Thermal stability and pH optima of NADH-nitrate reductase-associated cytochrome c reductase and FMNH₂-nitrate reductase from wild type, cv Steptoe or Winer, and mutants nar 1d, nar 1g, nar 1h, Xno 18 and Xno 19 were compared to determine if structural differences in the nitrate reductase protein could be detected. Also, the nitrate reductase-associated cytochrome c reductase from nar 1d was purified and compared with the wild type by peptide mapping. The pH optimum for FMNH₂-nitrate reductase from Steptoe and nar 1h, and for NADH-cytochrome c reductase from Steptoe, nar 1d, nar 1g and nar 2a was 7.5. Thermal stabilities of the nitrate reductase-associated activities (FMNH₂-nitrate reductase or NADH-cytochrome c reductase) from nar mutants were less than the Steptoe wild type, while Xno mutants were equal to the Winer wild type. Cleveland peptide maps of nar 1d NADH-cytochrome c reductase and Steptoe nitrate reductase were identicalwhen digested with endoprotease lys-C but were distinctly different in one peptide when digested with Staphylococcus aureus endoprotease V8. These results provide evidence that nar 1 gene codes for the nitrate reductase polypeptide.     

Comparative studies on the induction and inactivation of nitrate reductase in corn roots and leaves

A comparison of induction and inactivation of nitrate reductase and two of its component activities, namely FMNH₂-nitrate reductase and NO₃⁻-induced NADH-cytochrome c reductase, was made in roots and leaves of corn (Zea mays L. var. W64A × 182E). The three activities were induced in parallel in both tissues when NO₃⁻ was supplied. WO₄⁼ suppressed the induction of NADH- and FMNH₂-nitrate reductase activities in root tips and leaves. The NO₃⁻-induced NADH-cytochrome c reductase activity showed a normal increase in roots treated with WO₄⁼. In leaves, on the other hand, there was a marked superinduction of the NO₃⁻-induced NADH-cytochrome c reductase in the presence of WO₄⁼.     

Some characteristics of nitrate reductase from higher plants

With respect to cofactor requirements, NADH, and FMNH₂ were equally effective as electron donors for nitrate reductase obtained from leaves of maize, marrow, and spinach, when the cofactors were supplied in optimal concentrations. The concentration of FMNH₂ required to obtain half-maximal activity was from 40- to 100-fold higher than for NADH. For maximal activity with the corn enzyme, 0.8 millimolar FMNH₂ was required. In contrast, NADPH was functional only when supplied with NADP:reductase and exogenous FMN (enzymatic generation of FMNH₂).

All attempts to separate the NADH₂- and FMNH₂-dependent nitrate reductase activities were unsuccessful and regardless of cofactor used equal activities were obtained, if cofactor concentration was optimal. Unity of NADH to FMNH₂ activities were obtained during: A) purification procedures (4 step, 30-fold); B) induction of nitrate reductase in corn seedlings with nitrate; and C) inactivation of nitrate reductase in intact or excised corn seedlings. The NADH- and FMNH₂-dependent activities were not additive.

A half-life for nitrate reductase of approximately 4 hours was estimated from the inactivation studies with excised corn seedlings. Similar half-life values were obtained when seedlings were incubated at 35° in a medium containing nitrate and cycloheximide (to inhibit protein synthesis), or when both nitrate and cycloheximide were omitted.

In those instances where NADH activity but not FMNH₂ activity was lost due to treatment (temperature, removal of sulfhydryl agents, addition of p-chloromercuribenzoate), the loss could be explained by inactivation of the sulfhydryl group (s) required for NADH activity. This was verified by reactivation with exogenous cysteine.

Based on these current findings, and previous work, it is concluded that nitrate reductase is a single moiety with the ability to utilize either NADH or FMNH₂ as cofactor. However the high concentration of FMNH₂ required for optimal activity suggests that in vivo NADH is the electron donor and that nitrate reductase in higher plants should be designated NADH:nitrate reductase (E.C. 1.6.6.1).

     

Limited proteolysis of the nitrate reductase from spinach leaves

The functional structure of assimilatory NADH-nitrate reductase from spinach leaves was studied by limited proteolysis experiments. After incubation of purified nitrate reductase with trypsin, two stable products of 59 and 45 kDa were observed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The fragment of 45 kDa was purified by Blue Sepharose chromatography. NADH-ferricyanide reductase and NADH-cytochrome c reductase activities were associated with this 45-kDa fragment which contains FAD, heme, and NADH binding fragment. After incubation of purified nitrate reductase with Staphylococcus aureus V8 protease, two major peaks were observed by high performance liquid chromatography size exclusion gel filtration. FMNH2-nitrate reductase and reduced methyl viologen-nitrate reductase activities were associated with the first peak of 170 kDa which consists of two noncovalently associated (75-90-kDa) fragments. NADH-ferricyanide reductase activity, however, was associated with the second peak which consisted of FAD and NADH binding sites. Incubation of the 45-kDa fragment with S. aureus V8 protease produced two major fragments of 28 and 14 kDa which contained FAD and heme, respectively. These results indicate that the molybdenum, heme, and FAD components of spinach nitrate reductase are contained in distinct domains which are covalently linked by exposed hinge regions. The molybdenum domain appears to be important in the maintenance of subunit interactions in the enzyme complex.     

Structural and functional relationships of enzyme activities induced by nitrate in barley

1. Nitrate induces the development of NADH-nitrate reductase (EC 1.6.6.1), FMNH(2)-nitrate reductase and NADH-cytochrome c reductase activities in barley shoots. 2. Sucrose-density-gradient analysis shows one band of NADH-nitrate reductase (8S), one band of FMNH(2)-nitrate reductase activity (8S) and three bands of NADH-cytochrome c reductase activity (bottom layer, 8S and 3.7S). Both 8S and 3.7S NADH-cytochrome c reductase activities are inducible by nitrate, but the induction of the 8S band is much more marked. 3. The 8S NADH-cytochrome c reductase band co-sediments with both NADH-nitrate reductase activity and FMNH(2)-nitrate reductase activity. Nitrite reductase activity (4.6S) did not coincide with the activity of either the 8S or the 3.7S NADH-cytochrome c reductase. 4. FMNH(2)-nitrate reductase activity is more stable (t((1/2)) 12.5min) than either NADH-nitrate reductase activity (t((1/2)) 0.5min) or total NADH-cytochrome c reductase activity (t((1/2)) 1.5min) at 45 degrees C. 5. NADH-cytochrome c reductase and NADH-nitrate reductase activities are more sensitive to p-chloromercuribenzoate than is FMNH(2)-nitrate reductase activity. 6. Tungstate prevents the formation of NADH-nitrate reductase and FMNH(2)-nitrate reductase activities, but it causes superinduction of NADH-cytochrome c reductase activity. Molybdate overcomes the effects of tungstate. 7. The same three bands (bottom layer, 8S and 3.7S) of NADH-cytochrome c reductase activity are observed irrespective of whether induction is carried out in the presence or absence of tungstate, but only the activities in the 8S and 3.7S bands are increased. 8. The results support the idea that NADH-nitrate reductase, FMNH(2)-nitrate reductase and NADH-cytochrome c reductase are activities of the same enzyme complex, and that in the presence of tungstate the 8S enzyme complex is formed but is functional only with respect to NADH-cytochrome c reductase activity.     

NADH-dependent nitrate reductase from two-row barley roots: Purification, characteristics and comparison with leaf enzyme

NADH-nitrate reductase (EC 1.6.6.1) was purified 800-fold from roots of two-row barley ( Hordeum vulgare L. cv. Daisen-gold) by a combination of Blue Sepharose and zinc-chelate affinity chromatographies followed by gel filtration on TSK-gel (G3000SW). The specific activity of the purified enzyme was 6.2 μmol nitrite produced (mg protein)⁻¹ min⁻¹ at 30°C.
Besides the reduction of nitrate by NADH, the root enzyme, like leaf nitrate reductase, also catalyzed the partial activities NADH-cytochrome c reductase, NADH-ferricyanide reductase, reduced methyl viologen nitrate reductase and FMNH₂-nitrate reductase. Its molecular weight was estimated to be about 200 kDa, which is somewhat smaller than that for the leaf enzyme. A comparison of root and leaf nitrate reductases shows physiologically similar or identical properties with respect to pH optimum, requirements of electron donor, acceptor, and FAD, apparent K_m for nitrate, NADH and FAD, pH tolerance, thermal stability and response to inorganic orthophosphate. Phosphate activated root nitrate reductase at high concentration of nitrate, but was inhibitory at low concentrations, resulting in increases in apparent K_m for nitrate as well as V_max whereas it did not alter the K_m for NADH.     

Inhibition of the nitrate reductase complex from spinach by oxylamines

The nitrate reductase complex from spinach (Spinacia oleracea) was found to be inhibited by oxylamine compounds such as aminooxyacetate, hydroxylamine and O-methoxylamine. These compounds appear to interact with reduced cytochrome b₅₅₇ during catalysis of the enzyme. However, if the enzyme is maintained in a reduced state by NADH in the absence of nitrate, an additional component involved in FMNH₂-nitrate reductase is also affected by them. The binding of the oxylamines with the enzyme is non-covalent in nature as the inhibition can be reversed by treatment with 2-oxoglutarate.     

NADH-Ferricyanide Reductase of Leaf Plasma Membranes : Partial Purification and Immunological Relation to Potato Tuber Microsomal NADH-Ferricyanide Reductase and Spinach Leaf NADH-Nitrate Reductase

Plasma membranes obtained by two-phase partitioning of microsomal fractions from spinach (Spinacea oleracea L. cv Medania) and sugar beet leaves (Beta vulgaris L.) contained relatively high NADH-ferricyanide reductase and NADH-nitrate reductase (NR; EC 1.6.6.1) activities. Both of these activities were latent. To investigate whether these activities were due to the same enzyme, plasma membrane polypeptides were separated with SDS-PAGE and analyzed with immunoblotting methods. Antibodies raised against microsomal NADH-ferricyanide reductase (tentatively identified as NADH-cytochrome b₅ reductase, EC 1.6.2.2), purified from potato (Solanum tuberosum L. cv Bintje) tuber microsomes, displayed one single band at 43 kilodaltons when reacted with spinach plasma membranes, whereas lgG produced against NR from spinach leaves gave a major band at 110 kilodaltons together with a few fainter bands of lower molecular mass. Immunoblotting analysis using inside-out and right-side-out plasma membrane vesicles strongly indicated that NR was not an integral protein but probably trapped inside the plasma membrane vesicles during homogenization. Proteins from spinach plasma membranes were solubilized with the zwitterionic detergent 3-[(3-cholamidopropyl) dimethylammonio] 1-propane-sulfonate and separated on a Mono Q anion exchange column at pH 5.6 with fast protein liquid chromatography. One major peak of NADH-ferricyanide reductase activity was found after separation. The peak fraction was enriched about 70-fold in this activity compared to the plasma membrane. When the peak fractions were analyzed with SDS-PAGE the NADH-ferricyanide reductase activity strongly correlated with a 43 kilodalton polypeptide which reacted with the antibodies against potato microsomal NADH-ferricyanide reductase. Thus, our data indicate that most, if not all, of the truly membrane-bound NADH-ferricyanide reductase activity of leaf plasma membranes is due to an enzyme very similar to potato tuber microsomal NADH-ferricyanide reductase (NADH-cytochrome b₅ reductase).     

Differential effect of tungsten on the development of endogenous and nitrate-induced nitrate reductase activities in soybean leaves

The effect of tungsten on the development of endogenous and nitrate-induced NADH- and FMNH₂-linked nitrate reductase activities in primary leaves of 10-day-old soybean (Glycine max [L.] Merr.) seedlings was studied. The seedlings were grown with or without exogenous nitrate. High levels of endogenous nitrate reductase activities developed in leaves of seedlings grown without nitrate. However, no endogenous nitrite reductase activity was detected in such seedlings. The FMNH₂-linked nitrate reductase activity was about 40% of NADH-linked activity. Tungsten had little or no effect on the development of endogenous NADH- and FMNH₂-linked nitrate reductase activities, respectively. By contrast, in nitrate-grown seedlings, tungsten only inhibited the nitrate-induced portion of NADH-linked nitrate reductase activity, whereas the FMNH₂-linked activity was inhibited completely. Tungsten had no effect on the development of nitrate-induced nitrite reductase activity. The complete inhibition of FMNH₂-linked nitrate reductase activity by tungsten in nitrate-grown plants was apparently an artifact caused by the reduction of nitrite by nitrite reductase in the assay system. The results suggest that in soybean leaves either the endogenous nitrate reductase does not require molybdenum or the molybdenum present in the seed is preferentially utilized by the enzyme complex as compared to nitrate-induced nitrate reductase.     

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.     

Activation of nitrate reductase by extracts from corn scutella

NADH-nitrate reductase (NR) from the primary leaves and root tips of corn seedlings (var. W64A × W182E) were activated by extracts from corn scutella. The activator extracted in potassium phosphate buffer (pH 7.5) or 80% (v/v) ethanol and fractionated by Dowex 1 (acetate) and Dowex 50 (H⁺) resins was recovered in the cationic fraction. The activator was not detected in extracts from shoots, roots, or endosperm of the seedlings. It activated the nitrate-induced cytochrome c reductase of NR complex but had slight inhibitory effects on the activities of FMNH₂-NR and reduced methylviologen-NR. In addition the activator inhibited the activities of purified NR-inactivating proteins from corn roots (var. Wf9 × 38-11) and rice cell cultures.     

Nitrate reductase from Spinacea oleracea. Reversible inactivation by NAD(P)H and by thiols

The enzymatic complex nitrate reductase from Spinacea oleracea is inactivated by NADH or NADPH and by simple thiols. The inactivation affects FNH₂-nitrate reductase but not NADH-diaphorase. Reactivation can be achieved by addition of ferricyanide. The extent of inactivation by dithioerythritol is increased by NAD⁺, but not by NADP⁺. Nitrate protects against inactivation by NADH or NADPH, and abolishes the effect of NAD⁺ on the inactivation by dithioerythritol. The NAD(P)H-inactivation of nitrate reductase requires that the diaphorase moiety of the complex be functional. However, there is no proportionality between NADH-diaphorase or NADH-nitrate reductase activities and the susceptibility of the enzymatic preparation to NADH or NADPH. It seems likely that the nitrate reductase complex contains a specific regulatory site, different from the catalytic site, the reduction of which is accompanied by the production of an inactive form of the complex.     

Activation of nitrate reductase from rice seedlings by NADH

Rice leaf nitrate reductase was specifically activated by preincubation both at 0° and 25°, with low concentrations of NADH. The nucleotide acted as a positive effector of the enzyme after a time lag of 20 min. NADPH, FMNH₂ and NAD were without any effect.     

Spinach nitrate reductase: purification, molecular weight, and subunit composition

Nitrate reductase was purified about 3,000-fold from spinach leaves by chromatography on butyl Toyopearl 650-M, hydroxyapatite-brushite, and blue Sepharose CL-6B columns. The purified enzyme yielded a single protein band upon polyacrylamide gel electrophoresis under nondenaturing conditions. This band also gave a positive stain for reduced methylviologen-nitrate reductase activity. The specific NADH-nitrate reductase activities of the purified preparations varied from 80 to 130 units per milligram protein. Sucrose density gradient centrifugation and gel filtration experiments gave a sedimentation coefficient of 10.5 S and a Stokes radius of 6.3 nanometers, respectively. From these values, a molecular weight of 270,000 ± 40,000 was estimated for the native reductase. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the denatured enzyme yielded a subunit band having a molecular weight of 114,000 together with a very faint band possessing a somewhat smaller molecular weight. It is concluded that spinach nitrate reductase is composed of two identical subunits possessing a molecular weight of 110,000 to 120,000.     

Monoclonal antibodies to a higher-plant nitrate reductase: Differential inhibition of enzyme activities

A set of monoclonal antibodies has been raised against NADH-nitrate reductase (NR; EC 1.6.6.1) from spinach (Spinacea oleracea L.) leaves. Antibodies were screened by enzyme-linked immunosorbent assay and by their ability to inhibit various activities of the enzyme. The six monoclonals selected (AFRC MAC 74 to 79) are all gamma globulins; four (MAC 74 to 77) inhibit all terminal donating activities (NADH-NR; flavin mononucleotide, reduced form (FMNH₂)-NR; and methyl viologen, reduced form (MV)-NR) and two (MAC 78 and 79) inhibit the acceptor activities (NADH-NR, and NADH-cytochrome c reductase). MAC 74 to 77 inhibit the NADH-NR activity of crude extracts of a variety of species (mono- and dicotyledoneae) while MAC 78 and 79 are effective against spinach and marrow, but not oil-seed rape, cucumber, oats, wheat and barley.Abbreviations Cyt c Rase cytochrome c reductase - ELISA enzyme-linked immunosorbent assay - FAD(H₂) flavin adenine dinucleotide (reduced form) - FMN(H₂) flavin mononucleotide (reduced form) - McAb monoclonal antibody - MV methyl viologen reduced form - NR nitrate reductase     

Nitrate reductase in agrostemma githago comparison of the inductive effects of nitrate and cytokinin

The effect of nitrate and cytokinin on the induction of nitrate reductase (NADH-nitrate oxidoreductase, EC 1.6.6.1) in embryos of Agrostemma githago was compared. Increased enzyme levels in response to treatment with the cytokinin benzyladenine were not correlated with a general stimulation of protein synthesis or a general reduction of protein breakdown. Actinomycin D did not inhibit the formation of nitrate reductase in response to nitrate or the cytokinin. Cycloheximide and puromycin inhibited the induction by the hormone to the same extent as, or even more than, the incorporation of [¹⁴C]leucine into protein. Induction of nitrate reductase by nitrate was much less susceptible to inhibition by cycloheximide and puromycin than induction of the enzyme by benzyladenine. When induction of nitrate reductase was carried out in the presence of ²H₂O, isopycnic equilibrium centrifugation in CsCl showed that incorporation of ²H into the enzyme had occured. The increase in the buoyant density of nitrate reductase was the same whether the enzyme was induced by nitrate or by benzyladenine, indicating that at least part of the nitrate reductase molecule was newly synthesized in both instances.     

Flavine nucleotide nitrate reductase from broad bean leaves

Hydrosulfite-reduced FMN served as an electron donor for nitratereductase purified from broad bean leaves. FMN was successfullyreplaced with BV. The flavine nucleotide nitrate reductase hadits pH optima at about 7.8 with phosphate buffer and at about7.4 with Tris-HCl buffer. The Km's for nitrate and FMN were3.7 ? 10^–4 M and 3.7 ? 10^–5 M, respectively. NADH₂: nitrate reductase activity was completely inhibited by0.1 mM p-CMB, whereas FMNH₂: nitrate reductase activity wasnot. Inhibited activity was restored by the addition of cysteine.A sulfhydryl enzyme is involved in the NADH₂: nitrate reductasesystem but not in the FMNH₂ : nitrate reductase system. NADH₂and FMNH₂ probably feed electrons into the electron transportchain at different sites. The nitrate reductase preparationhad an NADH₂-specific diaphorase activity which was almost completelyinhibited by 0.1 mM p-CMB. The NADH₂-specific diaphorase mayform the sulfhydryl enzyme which mediates electron transferbetween NADH₂ and nitrate. (Received May 6, 1969; )     

Purification and Characterization of EDTA Monooxygenase from the EDTA-Degrading Bacterium BNC1

The synthetic chelating agent EDTA can mobilize radionuclides and heavy metals in the environment. Biodegradation of EDTA should reduce this mobilization. Although several bacteria have been reported to mineralize EDTA, little is known about the biochemistry of EDTA degradation. Understanding the biochemistry will facilitate the removal of EDTA from the environment. EDTA-degrading activities were detected in cell extracts of bacterium BNC1 when flavin mononucleotide (FMN), NADH, and O₂ were present. The degradative enzyme system was separated into two different enzymes, EDTA monooxygenase and an FMN reductase. EDTA monooxygenase oxidized EDTA to glyoxylate and ethylenediaminetriacetate (ED3A), with the coconsumption of FMNH₂ and O₂. The FMN reductase provided EDTA monooxygenase with FMNH₂ by reducing FMN with NADH. The FMN reductase was successfully substituted in the assay mixture by other FMN reductases. EDTA monooxygenase was purified to greater than 95% homogeneity and had a single polypeptide with a molecular weight of 45,000. The enzyme oxidized both EDTA complexed with various metal ions and uncomplexed EDTA. The optimal conditions for activity were pH 7.8 and 35°C. K_ms were 34.1 μM for uncomplexed EDTA and 8.5 μM for MgEDTA²⁻; this difference in K_m indicates that the enzyme has greater affinity for MgEDTA²⁻. The enzyme also catalyzed the release of glyoxylate from nitrilotriacetate and diethylenetriaminepentaacetate. EDTA monooxygenase belongs to a small group of FMNH₂-utilizing monooxygenases that attack carbon-nitrogen, carbon-sulfur, and carbon-carbon double bonds.     

NADH-Nitrate Reductase Inhibitor from Soybean Leaves

A NADH-nitrate reductase inhibitor has been isolated from young soybean (Glycine max L. Merr. Var. Amsoy) leaves that had been in the dark for 54 hours. The presence of the inhibitor was first suggested by the absence of nitrate reductase activity in the homogenate until the inhibitor was removed by diethylaminoethyl (DEAE)-cellulose chromatography. The inhibitor inactivated the enzyme in homogenates of leaves harvested in the light. Nitrate reductases in single whole cells isolated through a sucrose gradient were equally active from leaves grown in light or darkness, but were inhibited by addition of the active inhibitor.

The NADH-nitrate reductase inhibitor was purified 2,500-fold to an electrophoretic homogeneous protein by a procedure involving DEAE- cellulose chromatography, Sephadex G-100 filtration, and ammonium sulfate precipitation followed by dialysis. The assay was based on nitrate reductase inhibition. A rapid partial isolation procedure was also developed to separate nitrate reductase from the inhibitor by DEAE-cellulose chromatography and elution with KNO₃. The inhibitor was a heat-labile protein of about 31,000 molecular weight with two identical subunits. After electrophoresis on polyacrylamide gel two adjacent bands of protein were present; an active form and an inactive form that developed on standing. The active factor inhibited leaf NADH-nitrate reductase but not NADPH-nitrate reductase, the bacterial nitrate reductase or other enzymes tested. The site of inhibition was probably at the reduced flavin adenine dinucleotide-NR reaction, since it did not block the partial reaction of NADH-cytochrome c reductase. The inhibitor did not appear to be a protease. Some form of association of the active inhibitor with nitrate reductase was indicated by a change of inhibitor mobility through Sephadex G-75 in the presence of the enzyme. The inhibition of nitrate reductase was noncompetitive with nitrate but caused a decrease in V_max.

The isolated inhibitor was inactivated in the light, but after 24 hours in the dark full inhibitory activity returned. Equal amounts of inhibitor were present in leaves harvested from light or darkness, except that the inhibitor was at first inactive when rapidly isolated from leaves in light. Photoinactivation of yellow impure inhibitor required no additional components, but inactivation of the purified colorless inhibitor required the addition of flavin.

Preliminary evidence and a procedure are given for partial isolation of a component by DEAE-cellulose chromatography that stimulated nitrate reductase. The data suggest that light-dark changes in nitrate reductase activity are regulated by specific protein inhibitors and stimulators.