Composition of partially purified NADPH oxidase from pig neutrophils.

The superoxide (O2.-)-forming enzyme NADPH oxidase from pig neutrophils was solubilized and partially purified by gel-filtration chromatography. The purification procedure allowed the separation of NADPH oxidase activity from NADH-dependent cytochrome c reductase and 2,6-dichlorophenol-indophenol reductase activities. O2.-forming activity was co-purified with cytochrome b-245 and was associated with phospholipids. However, active fractions endowed with cytochrome b were devoid of ubiquinone and contained only little FAD. The cytochrome b/FAD ratio was 1.13:1 in the crude solubilized extract and increased to 18.95:1 in the partially purified preparations. Most of FAD was associated with fractions containing NADH-dependent oxidoreductases. These results are consistent with the postulated role of cytochrome b in O2.-formation by neutrophil NADPH oxidase, but raise doubts about the participation of flavoproteins in this enzyme activity.     

NADPH binding component of neutrophil superoxide-generating oxidase

The 2',3'-dialdehyde derivative of NADPH was used as an affinity labeling reagent of a solubilized NADPH-dependent superoxide-generating oxidase preparation of pig neutrophils. The analogue served as both an electron donor and a competitive inhibitor of the NADPH oxidase against NADPH. The apparent Michaelis constant (Km) for the derivative (31 microM) was essentially the same as that for NADPH (33 microM). The activity of the superoxide formation in the presence of 2',3'-dialdehyde NADPH was about a half of that in the presence of NADPH. Incubation of the enzyme with the derivative inactivated the superoxide-generating activity and the inactivation was prevented by the addition of NADPH. We performed the labeling of the oxidase preparation with 2',3'-dialdehyde NADPH and sodium cyanoboro[3H]hydride, based on the above results. A protein of 66,000 daltons was selectively labeled among more than 20 bands in sodium dodecyl sulfate-polyacrylamide gel electrophoresis which were visualized with Coomassie Brilliant Blue. The protein was not labeled when the oxidase preparation was pretreated with p-chloromercuribenzoate or it was labeled in the presence of excess NADPH. The protein is suggested to be the NADPH binding component of the neutrophil superoxide-generating oxidase system.     

Electron transfer reactions in the NADPH oxidase system of neutrophils--involvement of an NADPH-cytochrome c reductase in the oxidase system.

Membrane-bound NADPH oxidase of pig blood neutrophils was solubilized with heptylthioglucoside in a high yield. The solubilized preparation from myristate-stimulated cells (sample S) showed high O2- generating activity, and the preparation from resting cells (sample R) had no activity, but the two samples had equal amounts of flavins and cytochrome b-558 (cyt b-558). The electron transfer reactions to exogenous cytochrome c (cyt c) or cyt b-558 in samples S and R were examined. Under anaerobic conditions, NADPH-dependent cyt c reductase activity appeared higher in sample S than in sample R, and the addition of FMN and FAD greatly enhanced the reductase activity of sample S, but not that of sample R. No marked difference between the reductase activities of samples S and R was seen with NADH. Photoreduction of the NADPH oxidase system was examined in the absence of NADPH under anaerobic conditions by monitoring the reduction rates of exogenous cyt c using a flashlight with cut-off filters between 400 and 500 nm. Cyt c reduction was much higher in sample S than in sample R on photoexcitation at about 450 nm. Photoreduction was carried out with a band-pass filter for selective irradiation at 450 nm. Marked reduction of exogenous cyt c was observed only in sample S: the small reduction of cyt c by sample R was independent of the light wavelength and was equal to the blank level. In contrast, no difference in the reduction of cyt b-558 by the two samples was found by either NADPH or photoreduction. Under aerobic conditions, no direct reduction of either cyt c or cyt b-558 was observed. These results suggest that an NADPH-cyt c reductase (a membrane-bound flavoprotein) is involved in the NADPH oxidase system of stimulated neutrophils.     

Properties of the NADPH dehydrogenase component of the oxidase complex from rabbit peritoneal neutrophils: reconstitution of an oxidase activity with the dehydrogenase component and a membrane extract

A flavin-linked NADPH cytochrome c oxido-reductase of molecular mass 77-kDa was extracted from membranes of rabbit peritoneal neutrophils and purified in the presence of Triton X-100. The redox properties of this enzyme were examined. By some criteria including its high sensitivity to mersalyl, and its relatively high specificity for NADPH compared to NADH, the rabbit neutrophil NADPH cytochrome c reductase resembled NADPH-cytochrome P-450 reductase. Limited proteolysis generated water soluble fragments, with molecular masses of 67-kDa and 57-kDa, which were still endowed with a substantial reductase activity. When added to a lysate of neutrophil membranes in octylglucoside, in the presence of an oxidase activation medium consisting of rabbit neutrophil cytosol, GTP-gamma-S, arachidonic acid and Mg2+, the purified reductase enhanced the production of O2-., suggesting that it forms part of the O2-. generating oxidase.     

Butylated hydroxyanisole-stimulated NADPH oxidase activity in rat liver microsomal fractions

NADPH-dependent oxygen utilization by liver microsomal fractions was stimulated by the addition of increasing concentrations of butylated hydroxyanisole concomitant with the inhibition of benzphetamine N-demethylase activity. The apparent conversion of monooxygenase activity to an oxidase-like activity in the presence of the antioxidant was correlated with the partial recovery of the reducing equivalents from NADPH in the form of increased hydrogen peroxide production. The progress curve of liver microsomal NADPH oxidase activity in the presence of butylated hydroxyanisole displayed a lag phase indicative of the formation of a metabolite capable of uncoupling the monooxygenase activity. Ethyl acetate extracts of microsomal reaction mixtures obtained in the presence of butylated hydroxyanisole, oxygen, and NADPH stimulated the NADPH oxidase activity of either liver microsomes or purified NADPH-cytochrome c (P-450) reductase. Using high performance liquid chromatography, gas chromatography, and mass spectrometry techniques, two metabolites of butylated hydroxyanisole, namely t-butylhydroquinone and t-butylquinone, were identified. The quinone metabolite and/or its 1-electron reduction product interact with the flavoprotein reductase to directly link the enzyme to the reduction of oxygen which results in an inhibition of the catalytic activity of the cytochrome P-450-dependent monooxygenase.     

Characterization of multiple active forms of the NADPH dehydrogenase component of the oxidase complex from rabbit peritoneal neutrophils by photolabeling with an arylazido derivative of NADP+

A NADPH cytochrome c oxidoreductase purified from membranes of rabbit peritoneal neutrophil was shown to behave as the NADPH dehydrogenase component of the O2- generating oxidase complex. A photoactivable derivative of NADP+, azido nitrophenyl-gamma-aminobutyryl NADP+ (NAP4-NADP+), was synthesized in its labeled [3H] form and used to photolabel the NADPH cytochrome c reductase at different stages of the purification procedure. Control assays performed in dim light indicated that the reduced form of NADP4-NADP+ generated by reduction with glucose-6-phosphate and glucose-6-phosphate dehydrogenase was oxidized at virtually the same rate as NADPH. Upon photoirradiation of the purified reductase in the presence of [3H]NAP4-NADP+ and subsequent separation of the photolabeled species by sodium dodecyl sulfate polyacrylamide gel electrophoresis, radioactivity was found to be present predominantly in a protein band with a molecular mass of 77-kDa and accessorily in bands of 67-kDa and 57-kDa. Evidence is provided that the 67-kDa and 57-kDa proteins arose from the 77-kDa protein by proteolysis. Despite removal of part of the sequence, the proteolyzed proteins were still active in catalyzing electron transport from NADPH to cytochrome c and in binding the photoactivable derivative of NADP+.     

Mechanism of hydrogen peroxide formation catalyzed by NADPH oxidase in thyroid plasma membrane

The thyroid plasma membrane contains a Ca2(+)-regulated NADPH-dependent H2O2 generating system which provides H2O2 for the thyroid peroxidase-catalyzed biosynthesis of thyroid hormones. The plasma membrane fraction contains a Ca2(+)-independent cytochrome c reductase activity which is not inhibited by superoxide dismutase. But it is not known whether H2O2 is produced directly from molecular oxygen (O2) or formed via dismutation of super-oxide anion (O2-). Indirect evidence from electron scavenger studies indicate that the H2O2 generating system does not liberate O2-, but studies using the modified peroxidase, diacetyldeuteroheme horseradish peroxidase, to detect O2- indicate that H2O2 is provided via the dismutation of O2-. The present results provide indirect evidence that the cytochrome c reductase activity is not a component of the NADPH-dependent H2O2 generator, since it was removed by washing the plasma membranes with 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonic acid without affecting H2O2 generation. Spectral studies with diacetyldeuteroheme-substituted horseradish peroxidase showed that the thyroid NADPH-dependent H2O2 generator does not catalyze superoxide anion formation. The O2- adduct compound (compound III) was formed but was completely inhibited by catalase, indicating that the initial product was H2O2. The rate of NADPH oxidation also increased in the presence of diacetylheme peroxidase. This increase was blocked by catalase and was greatly enhanced by superoxide dismutase. The O2- adduct compound (compound III) was produced in the presence of NADPH when glucose-glucose oxidase (which does not produce O2-) was used as the H2O2 generator. NADPH oxidation occurred simultaneously and was enhanced by superoxide dismutase. We conclude that O2- formation occurs in the presence of an H2O2 generator, diacetylheme peroxidase and NADPH, but that it is not the primary product of the H2O2 generator. We suggest that O2- formation results from oxidation of NADPH, catalyzed by the diacetylheme peroxidase compound I, producing NADP degree, which in turn reacts with O2 to give O2-.     

Mixed function oxidases in sterol metabolism. Separate routes for electron transfer from NADH and NADPH.

Oxidative deformylation of 4-hydroxy[14C]methylene-5alpha-cholest-7-en-3-one and oxidative demethylation of [30,31-14C]4,4-dimethyl-5alpha-cholest-7-en-3beta-ol by rat liver microsomes have been compared with regard to the manner in which electrons are introduced from both NADH and NADPH. Evidence suggests that NADH and NADPH support oxidation of both substrates via separate routes of electron transfer. Thus, 10 micron cytochrome c will inhibit NADPH-supported oxidation to 40 to 50% of control activity leaving NADH-supported oxidation unaffected. Also, treatment of microsomes with subtilisin diminishes NADPH-supported oxidation to 10 to 30% of control activity for either substrate to 70 to 90% of control activity while NADH-supported oxidative activity is virtually unaffected. Studies on the oxidase activities and NADPH-cytochrome c reductase as well as NADH-ferricyanide reductase have shown marked differences in activity in the presence of inhibitors. Thus, 9 mM 2'-AMP inhibits NADPH-cytochrome c reductase to 10 to 20% of control activity while NADPH-supported oxidative demethyl ation and deformylation are essentially unchanged. Mersalyl at 15 to 25 nmol/mg of microsomal protein inhibits both reductases to 20 to 40% of control activity; oxidative demethylation is unaffected and oxidative deformylation stimulated slightly when NADPH is used. Finally, antibody to NADPH-cytochrome c reductase inhibits oxidase activity for either substrate to 70 to 90% of control activity while reductase activity is inhibited to 10 to 30% of control activity.     

The membrane-associated component of the amphiphile-activated, cytosol-dependent superoxide-forming NADPH oxidase of macrophages is identical to cytochrome b559.

The superoxide (O2-) forming NADPH oxidase complex of resting phagocytes can be activated in a cell-free system by certain anionic amphiphiles, such as sodium dodecyl sulfate (SDS). For O2- production to occur, the participation of both membrane-associated and cytosol-derived components is required. The purpose of this investigation was to isolate and characterize the membrane component of NADPH oxidase. For this purpose, guinea pig macrophage membranes were extracted with 1 M NaCl, solubilized by 40 mM octyl glucoside, and subjected to a purification sequence consisting of absorption with DEAE-Sepharose, affinity chromatography on heparin-agarose, and chromatography on hydroxylapatite. At each purification step, fractions were assayed for their ability to support SDS-elicited, cytosol-dependent O2- production, following incorporation in liposomes of phosphatidylcholine. We found that membrane oxidase activity copurified strictly with cytochrome b559. Peak hydroxylapatite fractions exhibited specific O2(-)-forming activity in the range of 81-115 mumol of O2-/mg protein/min and a specific cytochrome b559 content of 7-14 nmol of cytochrome b559/mg protein. SDS-polyacrylamide gel electrophoresis analysis of the peak oxidase activity fractions, derived by hydroxylapatite chromatography, revealed essentially two bands that were identified as the beta (54-60 kDa) and alpha (21/22 kDa) subunits of guinea pig cytochrome b559. The relation of the two polypeptides to cytochrome b559 was established by correlation with a spectral signal characteristic of cytochrome b559, immunoblotting with antibodies against defined human cytochrome b559 beta and alpha chain peptides, cross-linking studies, and deglycosylation experiments. Hydroxylapatite-purified membrane oxidase preparations did not contain FAD and were free of cytochrome c reductase activity. Purified membrane oxidase preparations were also capable of cooperating with purified cytosolic components in SDS-elicited cell-free O2- production. We conclude that the membrane-associated component of the O2- generating NADPH oxidase is identical to cytochrome b559.     

NADPH dehydrogenase activity of p67PHOX, a cytosolic subunit of the leukocyte NADPH oxidase

The leukocyte NADPH oxidase catalyzes the one-electron reduction of oxygen to O2- at the expense of NADPH. It is a multicomponent enzyme comprising a membrane-bound flavocytochrome (cytochrome b558) and at least four cytosolic components: p47PHOX, p67PHOX, p40PHOX, and Rac, a small GTPase. All the oxidase components except p40PHOX are required for enzyme activity. Many aspects of their function, however, are unclear. Using the electron acceptor ferricyanide, we found that recombinant p67PHOX from baculovirus-infected Sf9 cells could mediate the dehydrogenation of NADPH. NADPH dehydrogenation was not dependent on FAD and was insensitive to superoxide dismutase. Several control experiments showed that NADPH dehydrogenation was accomplished by p67PHOX, not by a trace contaminant in the p67PHOX preparation. The NADPH dehydrogenase activity of p67PHOX was proportional to enzyme concentration, and showed saturation kinetics with NADPH (Km 92 +/- 5 microM), but was inhibited at high concentrations of ferricyanide. NADH was also used as a substrate by p67PHOX (Km 123 +/- 38 microM). Taken together, these results show that p67PHOX is able to mediate pyridine nucleotide dehydrogenation. These findings raise the possibility that p67PHOX might participate directly in electron transfer between NADPH and the oxidase flavin.     

2,6-Dichlorophenolindophenol-reducing activity of phagocytosis-associated NADPH oxidase

The 2,6-dichlorophenolindophenol (DCIP)-reducing activity of the phagocytosis-associated NADPH oxidase was investigated using homogenates and a membrane fraction (F2) of elicited guinea pig peritoneal macrophages stimulated by phorbol myristate acetate. Essentially all of the stimulation-specific DCIP reduction under aerobic conditions could be inhibited when high concentrations of superoxide dismutase (SOD), about 10 times those usually used to inhibit the superoxide (O-2)-mediated cytochrome c reduction, were used. SOD inhibited the DCIP reduction by chemically generated O2- in the same manner as the stimulation-specific DCIP reduction by the macrophage F2, and the concentration of SOD necessary for 50% inhibition was about 10 times that for the reduction of cytochrome c. Under anaerobic conditions, however, the NADPH oxidase could reduce DCIP, though the rate was slow because we could not use a sufficiently high DCIP concentration. The observations indicate that the NADPH oxidase preferentially reduces oxygen under aerobic conditions, though the oxidase can reduce DCIP in the anaerobic state.     

Reconstitution of the partially purified membrane component of the superoxide-generating NADPH oxidase of pig neutrophils with phospholipid

The NADPH-dependent superoxide-generating oxidase of pig neutrophils is activated by sodium dodecyl sulfate in a cell-free system. The activation requires both membrane and cytosolic components. The membrane component was effectively extracted with 0.75% octyl glucoside and the extract was fractionated by wheat-germ-agglutinin-agarose column chromatography. The chromatography resulted in loss of the O2--generating activity in the cell-free system. The activity, however, was restored by the reconstitution with the fraction which passed through the column (fraction A) and the one eluted with N-acetylglucosamine (fraction B) using an octyl glucose dilution procedure: both fractions were pre-mixed in the presence of 0.75% octyl glucoside and diluted by putting the mixture into the detergent-free assay mixture. The latter fraction was copurified with cytochrome b558, the content of which is 2.12 +/- 0.53 nmol/mg protein (mean +/- SD, n = 5). The potency of fraction B in the reconstitution of the O2--generating activity was lost by heat treatment and decreased by protease treatment, whereas that of fraction A was not affected. Fraction A in the reconstitution of the O2--generating activity was replaced by lipid extracted from fraction A, furthermore, by exogenous phospholipid, azolectin. The O2--generating activity reconstituted with azolectin and the partially purified component in fraction B was dependent on SDS, cytosol and the concentrations of azolectin and FAD. The activity was sensitive to p-chloromercuribenzoate but not to azide. The maximal activity was obtained at pH 7.0-7.5. The Km values for NADPH and NADH were 0.024 mM and 0.57 mM, respectively. These properties were consistent with those of the NADPH oxidase responsible for the respiratory burst. The activity in the reconstitution system was 20.5 +/- 3.5 mumol O2-.min-1.mg-1 membrane-derived protein (mean +/- SD, n = 5) which shows that the membrane component was purified about 100-fold. These findings indicate that cytochrome b558 is probably a membrane component of the O2--generating NADPH oxidase and its activation in the cell-free system requires the reconstitution with phospholipids.     

Activation of NADPH oxidase in human neutrophils permeabilized with Staphylococcus aureus alpha-toxin. A lower Km when the enzyme is activated in situ.

The NADPH oxidase is a multicomponent enzyme system that produces the reduced oxygen species essential for bacterial killing by polymorphonuclear leukocytes (PMN). Study of the oxidase has typically been carried out in cell-free systems in which Km values of 20-150 microM NADPH have been reported. However, when compared with affinities reported for other flavoprotein dehydrogenases and when considering the cellular concentration of NADPH/NADP+ of approximately 35 microM, the reported affinity of the oxidase for NADPH appears low. To investigate this apparent discrepancy we have studied the kinetics of NADPH oxidase activation in situ in human PMN permeabilized with Staphylococcus aureus alpha-toxin. alpha-Toxin permeabilization of human PMN did not initiate NADPH oxidase activation at physiologic concentrations of NADPH. If permeabilized cells were stimulated with 1 microM formyl-methionyl-leucyl-phenylalanine, 10 microM guanosine 5'-O-(3-thiotriphosphate), 0.5 mM Ca2+, 5 micrograms/ml cytochalasin B in the presence of varying concentrations of NADPH, we were able to demonstrate activation of the oxidase complex as shown by superoxide dismutase-inhibitable reduction of cytochrome c. In this system we determined that the Km for oxidase activation was 4-7 microM NADPH, a 4-10-fold decrease from reported values. The oxidase was the enzyme being studied as shown by the absence of enzymatic activity in patients with chronic granulomatous disease. In addition, if the enzyme was initially activated in permeabilized cells, the cells homogenized, and the Km for the oxidase determined in a cell-free system, the observed Km reverted to previously reported values (36 microM). These results indicate that NADPH oxidase, studied in situ, has a significantly higher substrate affinity than that observed in isolated membranes and, moreover, indicate that substrate affinity is optimal for catalysis at reported concentrations of cytosolic NADPH.     

Reconstitution of superoxide-forming NADPH oxidase activity with cytochrome b558 purified from porcine neutrophils. Requirement of a membrane-bound flavin enzyme for reconstitution of activity.

Cytochrome b558 of pig blood neutrophils was purified from the membranes of resting cells to examine its ability to reconstitute superoxide (O2-)-forming NADPH oxidase activity in a cell-free assay system containing cytosol and fatty acid. The membrane-associated cytochrome b558 was solubilized with a detergent, n-heptyl beta-thioglucoside, and purified by DEAE-Sepharose, heparin-Sepharose, and Mono Q column chromatography. The final preparation of cytochrome containing 11.5 nmol of protoheme/mg of protein gave bands of the large and small subunits on immunoblotted gel. The cell-free system with the purified cytochrome alone as a membrane component showed little O2(-)-generating activity in the absence of exogenous FAD. However, the system showed high O2(-)-generating activity of 31.8 mol/s/mol of cytochrome b558 (52.5% of the original O2(-)-generating activity of the solubilized membranes) in the presence of a nitro blue tetrazolium (NBT) reductase fraction that was separated from the cytochrome b fraction by heparin-Sepharose chromatography. Heat treatment of the NBT reductase fraction resulted in loss of the O2(-)-generating activity in the reconstituted system. The O2(-)-forming activity of the reconstituted system was markedly decreased by removal of FAD from the NBT reductase fraction and was restored by readdition of FAD to the FAD-depleted reductase. The reconstituted system containing purified cytochrome b558 plus the NBT reductase showed approximately 100 times higher O2(-)-generating activity than a system containing rabbit liver NADPH-cytochrome P-450 reductase instead. These results suggest that both the FAD-dependent NBT reductase and cytochrome b558 are required as membrane redox components for O2(-)-forming NADPH oxidase activity. The present data are discussed in comparison with previously reported results on reconstituted systems containing added free FAD.     

NADPH oxidase of guinea-pig macrophages catalyses the reduction of ubiquinone-1 under anaerobic conditions.

The stimulation-specific NADPH-dependent reduction of ubiquinone-1 (Q-1) in guinea-pig macrophages was studied. The activity was due neither to any modified product of the phagocytosis-specific NADPH oxidase nor to non-specific diaphorases of the cells, since the activity was measured in sonicated or detergent-disrupted cells by subtracting the activity in the resting cells from that in cells activated by phorbol 12-myristate 13-acetate. The activity was not mediated by superoxide anions, since strict anaerobic conditions were employed. The anaerobic reduction of Q-1 was NADPH-specific, like superoxide formation under aerobic conditions, and its maximal velocity was also essentially the same as that of superoxide formation. The oxidase does not directly reduce Q-1 under aerobic conditions [Nakamura, Murakami, Umei & Minakami (1985) FEBS Lett. 186, 215-218], and the electron transfer from NADPH to cytochrome c by the oxidase under aerobic conditions was not enhanced by the addition of Q-1. The observations indicate that the phagocytosis-specific NADPH oxidase reduces Q-1 and that oxygen competes with the reduction of Q-1. Q-1 seems to accept electrons not from the intermediary electron carriers of the oxidase but from the terminal oxygen-reducing site of the enzyme.     

Purification and characterization of a membrane-bound NADPH-cytochrome c reductase capable of catalyzing menadione-dependent O2- formation in guinea pig polymorphonuclear leukocytes

A membrane-bound NADPH-cytochrome c reductase, which is capable of forming the superoxide anion (O2-) in the presence of menadione, was highly purified from membrane fractions of disrupted guinea pig polymorphonuclear leukocytes by solubilization with 0.2% Triton X-100 and chromatographies on Sephacryl S-300 and 2',5'-ADP-agarose. The overall purification from the membrane fraction was over 110-fold, with a yield of about 6%. The purified preparation did not contain two other pyridine nucleotide-oxidizing enzymes: NADH- and NAD(P)H-oxidizing enzymes (J. Biochem. 94, 931-936, 1983). Besides cytochrome c, the purified enzyme was able to reduce menadione, Nitroblue tetrazolium (NBT) and 2,6-dichlorophenolindophenol. The reduction of menadione alone resulted in the formation of O2-. The purified enzyme preparation contained FAD. When assayed by measuring O2--generation in the presence of menadione, the enzyme showed an optimum pH at 7.0-7.4, and Km values for NADPH, NADH, and menadione were 25, 230, and 5.3 microM, respectively. The enzyme activity was not inhibited by NaN3 or dicumarol, but was by N-ethylmaleimide, EDTA, and quercetin; these inhibition profiles agree with those observed for the NADPH oxidase in the membrane fraction of phorbol-myristate acetate-stimulated leukocytes. Furthermore, when compared by means of the NBT-staining method combined with disc gel electrophoresis, the purified enzyme was electrophoretically indistinguishable from the NADPH-NBT reductase in the plasma membrane as well as phagosomes of the leukocytes. These results suggest that the purified NADPH-cytochrome c reductase is the putative flavoprotein of the NADPH oxidase system responsible for the respiratory burst.     

Binding of FAD to cytochrome b558 is facilitated during activation of the phagocyte NADPH oxidase, leading to superoxide production

The superoxide-producing phagocyte NADPH oxidase can be reconstituted in a cell-free system. The activity of NADPH oxidase is dependent on FAD, but the physiological status of FAD in the oxidase is not fully elucidated. To clarify the role of FAD in NADPH oxidase, FAD-free full-length recombinant p47(phox), p67(phox), p40(phox), and Rac were prepared, and the activity was reconstituted with these proteins and purified cytochrome b(558) (cyt b(558)) with different amounts of FAD. A remarkably high activity, over 100 micromol/s/micromol heme, was obtained in the oxidase with purified cyt b(558), ternary complex (p47-p67-p40(phox)), and Rac. From titration with FAD of the activity of NADPH oxidase reconstituted with purified FAD-devoid cyt b, the dissociation constant K(d) of FAD in cyt b(558) of reconstituted oxidase was estimated as nearly 1 nm. We also examined addition of FAD on the assembly process in reconstituted oxidase. The activity was remarkably enhanced when FAD was present during assembly process, and the efficacy of incorporating FAD into the vacant FAD site in purified cyt b(558) increased, compared when FAD was added after assembly processes. The absorption spectra of reconstituted oxidase under anaerobiosis showed that incorporation of FAD into cyt b(558) recovered electron flow from NADPH to heme. From both K(d) values of FAD and the amount of incorporated FAD in cyt b(558) of reconstituted oxidase, in combination with spectra, we propose the model in which the K(d) values of FAD in cyt b(558) is changeable after activation and FAD binding works as a switch to regulate electron transfer in NADPH oxidase.     

Use of an affinity label to probe the function of the NADPH binding component of the respiratory burst oxidase of human neutrophils

The respiratory burst oxidase of neutrophils can be activated in a cell-free system in which solubilized membranes, cytosol, and Mg2+ are required and in which sodium dodecyl sulfate is used to convert the dormant oxidase to an active form. The 2',3'-dialdehyde analog of NADPH was used as an affinity label for the cytosolic NADPH binding component of the respiratory burst oxidase from human neutrophils. When treated with this affinity label in the presence of sodium cyanoborohydride to reduce Schiff bases, neutrophil cytosol was shown to lose at least 90% of its activity in the cell-free system. In contrast to normal cytosol, treated cytosol had lost its ability to abolish the lag time required for activation of the oxidase, suggesting that the treated cytosol was no longer able to participate in the rate-limiting activation step. Furthermore, the treated cytosol had lost its ability to convert the oxidase from a form with a high Km to a form with a low Km for NADPH. The ability of dialdehyde-treated cytosol to activate the oxidase could be restored by untreated cytosol with a concentration dependence suggesting that only one kinetically active component of the oxidase was inhibited by treatment with the NADPH analog. Like the dialdehyde-treated cytosol, cytosols from patients with chronic granulomatous disease caused by a deficiency in a cytosolic Mr = 47,000 protein (pp47) fail to participate in the rate-limiting activation step (Curnutte, J. T., Scott, P. J., and Babior, B. M. (1989) J. Clin. Invest. 83, 1236-1240). These chronic granulomatous disease cytosols were nevertheless able to restore limited activity to the dialdehyde-inactivated cytosol in a cell-free activation system. These results are consistent with a model in which (a) the NADPH binding subunit of the oxidase exists in a very slowly dissociating complex with one or more additional cytosolic components, including pp47, and (b) the NADPH binding component of the oxidase controls the affinity of the enzyme for NADPH, either directly or through the binding of additional cytosolic factors.     

Human neutrophil cytosolic activation factor of the NADPH oxidase. Characterization of activation kinetics

The kinetics of sodium dodecyl sulfate-induced activation of respiratory burst oxidase (NADPH oxidase) in a fully soluble cell-free system from resting (control) or phorbol myristate acetate (PMA)-stimulated human neutrophils were investigated. In a cell-free system containing solubilized membranes and cytosol fractions (cytosol) derived from control neutrophils (control cell-free system), the values of Km and Vmax for NADPH of the NADPH oxidase from control neutrophils continuously increased with increasing concentrations of cytosol, but with increasing concentrations of solubilized membranes from the control neutrophils, Km values continuously decreased, suggesting cytosolic activation factor-dependent continuous changes in the affinity of NADPH oxidase to NADPH. In a cell-free system containing solubilized membranes and cytosol prepared from PMA-stimulated neutrophils, NADPH oxidase was not activated after the addition of NADPH. However, cytosol from control neutrophils activated the NADPH oxidase of PMA-stimulated neutrophils in a cell-free system. Cytosol from PMA-stimulated neutrophils did not activate the control neutrophil oxidase, although it contained no inhibitors of NADPH oxidase activation. The results suggest that, in PMA-stimulated neutrophils, cytosolic activation factors may be consumed or exhausted with an increasing period of time after the stimulation of neutrophils, and that the affinity of PMA-stimulated neutrophil NADPH oxidase to NADPH may almost be the same as that of control neutrophil oxidase. It was concluded that the affinity of NADPH oxidase to NADPH was closely associated with interaction between solubilized membranes and cytosolic activation factors, as indicated by the concentration ratio.     

The effect of o-diphenols upon the microsomal NADPH and NADH oxidase activities

Catechol and catecholamines have been assayed upon the microsomal NADPH and NADH oxidase activities. Epinephrine shows a catalytic effect on the NADPH oxidation characterized by a small lag. The two to threefold increase in rate can be suppressed by Superoxide dismutase if the enzyme is added before the reaction begins. The catalytic effect is ascribed to a quinone formed by two electron oxidation of epinephrine by the Superoxide ion. The quinone, which is not catalytically active in the NADH chain, appears to mediate electrons between the NADPH-cytochrome c reductase and oxygen. The four electron oxidation product adrenochrome is also active upon the NADPH chain but inactive upon the NADH chain.Epinephrine did not change the menadione-stimulated NADPH oxidase activity. Presumably, during this and the NADH oxidase activities, two electrons are simultaneously transferred to the oxygen molecule.Catechol and catecholamines doubled the rate of autoxidation of NADH in the presence of catalytic amounts of NADH-cytochrome b₅ reductase and cytochrome b₅, a result which suggests Superoxide ion formation in the autoxidation of the cytochrome.Epinephrine does not act upon the desaturation of endogenous substrate or upon endogenous lipid peroxidation.