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.     

Salmonella evasion of the NADPH phagocyte oxidase.

The bacteria-phagocyte interaction is of central importance in Salmonella pathogenesis. Immediately following phagocytosis, the NADPH phagocyte oxidase complex assembles in vesicles and produces highly toxic reactive oxygen species that play a major role in initial Salmonella killing by phagocytes. However, Salmonella has evolved a number of strategies to reduce the efficacy of oxygen-dependent phagocyte antimicrobial systems. Some of these strategies, such as superoxide dismutases, hydroperoxidases, oxidoreductases, scavengers and repair systems are common to most aerobic bacteria. In addition, Salmonella has acquired, by horizontal gene transfer, a type III secretory system encoded by Salmonella pathogenicity island 2 that interferes with the trafficking of vesicles containing functional NADPH phagocyte oxidase to the phagosome, thereby enhancing the survival of Salmonella within macrophages.     

Assembly of the phagocyte NADPH oxidase

Stimulated phagocytes undergo a burst in respiration whereby molecular oxygen is converted to superoxide anion through the action of an NADPH-dependent oxidase. The multicomponent phagocyte oxidase is unassembled and inactive in resting cells but assembles at the plasma or phagosomal membrane upon phagocyte activation. Oxidase components include flavocytochrome b₅₅₈, an integral membrane heterodimer comprised of gp91phox and p22phox, and three cytosolic proteins, p47phox, p67phox, and Rac1 or Rac2, depending on the species and phagocytic cell. In a sense, the phagocyte oxidase is spatially regulated, with critical elements segregated in the membrane and cytosol but ready to undergo nearly immediate assembly and activation in response to stimulation. To achieve such spatial regulation, the individual components in the resting phagocyte adopt conformations that mask potentially interactive structural domains that might mediate productive intermolecular associations and oxidase assembly. In response to stimulation, post-translational modifications of the oxidase components release these constraints and thereby render potential interfaces accessible and interactive, resulting in translocation of the cytosolic elements to the membrane where the functional oxidase is assembled and active. This review summarizes data on the structural features of the phagocyte oxidase components and on the agonist-dependent conformational rearrangements that contribute to oxidase assembly and activation.     

Cytochrome b558-negative, autosomal recessive chronic granulomatous disease: two new mutations in the cytochrome b558 light chain of the NADPH oxidase (p22-phox).

Chronic granulomatous disease (CGD) is characterized by the failure of activated phagocytes to generate superoxide. Defects in at least four different genes lead to CGD. Patients with the X-linked form of CGD have mutations in the gene for the beta-subunit of cytochrome b558 (gp91-phox). Patients with a rare autosomal recessive form of CGD have mutations in the gene for the alpha-subunit of this cytochrome (p22-phox). Usually, this leads to the absence of cytochrome b558 in the phagocytes (A22(0) CGD). We studied the molecular defect in five European patients from three unrelated families with this type of CGD. P22-phox mRNA was reverse-transcribed, and the coding region was amplified by PCR in one fragment and sequenced. Three patients from one family, with parents that were first cousins, were homozygous for a single base substitution (G-297-->A) resulting in a nonconservative amino acid change (Arg-90-->Gln). This mutation was previously found in a compound heterozygote A22(0) CGD patient. Another patient, also from first-cousin parents, was homozygous for an A-309-->G mutation in the open reading frame that predicts a nonconservative amino acid replacement (His-94-->Arg). The fifth patient was also born from a first-cousin marriage and was shown to be homozygous for the absence of exon 4 from the cDNA. In this patient, a G-->A substitution was found at position 1 of intron 4 in the genomic DNA. Therefore, the absence of exon 4 in the cDNA of this patient is due to a splicing error.(ABSTRACT TRUNCATED AT 250 WORDS)     

NADPH oxidase of Epstein-Barr-virus immortalized B lymphocytes. Effect of cytochrome b(558) glycosylation.

The phagocyte NADPH oxidase is known to be expressed in Epstein-Barr virus (EBV) immortalized B lymphocytes. But even if its molecular composition and its catalytic mechanisms are similar, the activity measured in B cells is very low compared to that of neutrophils. This could be explained by the low expression of cytochrome b558, the membrane redox component, but also by a defect in the activation process. This work is focused on gp91-phox glycosylation in B lymphocytes to assess its role in the complex assembly upon activation. Atomic force microscopy (AFM) combined with immunochemical approaches were used to investigate the effect of the glycosylation on the structure of cytochrome b558 inserted into liposomes, on the reconstituted oxidase activity in vitro, and to directly monitor interaction forces between specific antibodies and the hemoprotein in its native or deglycosylated state. The results show that in EBV-B cells, gp91-phox glycosylation is higher than in neutrophils. The interaction force measured between the monoclonal antibody 11C12, known to inhibit O(-2) production in B lymphocytes, and the hemoprotein is increased after deglycosylation. This suggested that the epitope region recognized by this antibody is partly hidden in B cells, and that this region could be involved in the conformational change that occurs in the hemoprotein during the complex assembly. The high glycosylation of gp91-phox in B cells associated with the lipidic environment could lead to additional structural constraints in the membrane-bound hemoprotein that partly blocked the hemoprotein in its inactive state.     

Functional expression of NADPH oxidase components (alpha- and beta-subunits of cytochrome b558 and 45-kDa flavoprotein) by intrinsic human glomerular mesangial cells.

Recently, we have shown that human glomerular mesangial cells (HMCs) release oxygen radicals from the plasma membrane in response to cytokines. Now we have used diphenylene iodonium, a covalent binding inhibitor of activated 45-kDa flavoprotein, in neutrophils radiolabeled with 125I and could identify a 45-kDa protein band in a separated HMC plasma membrane fraction. Low temperature difference spectroscopy showed a peak absorbance at 428 and 558 nm. Direct potentiometry of HMC membranes (-340 to -160 mV) showed the presence of a low potential cytochrome (76 pmol/mg to HMC membrane protein) identified as cytochrome b558. In slot blots, mouse monoclonal antibody (mAb) 7D5, specific for the extracellular domain of the alpha-subunit, showed a positive reaction with HMCs. In Western blots, mAb 449, directed against the cytoplasmic epitope of the alpha-subunit, identified a 23-kDa protein; and mAb 48, raised against the large (beta) subunit of cytochrome b558 of human neutrophils (Verhoeven, A. J., Bolscher, B. G. J. M., Meerhof, L. J., van Zwieten, R., Keijer, J., Weening, R. S., and Roos, D. (1989) Blood 73, 1686-1694), detected a smear between 75 and 100 kDa in denatured HMC membrane protein. These data determined with HMCs, suggest for the first time the expression of three essential components of NADPH:O2- oxidoreductase in mesenchymal cells.     

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.     

Molecular interface of S100A8 with cytochrome b558 and NADPH oxidase activation

S100A8 and S100A9 are two calcium binding Myeloid Related Proteins, and important mediators of inflammatory diseases. They were recently introduced as partners for phagocyte NADPH oxidase regulation. However, the precise mechanism of their interaction remains elusive. We had for aim (i) to evaluate the impact of S100 proteins on NADPH oxidase activity; (ii) to characterize molecular interaction of either S100A8, S100A9, or S100A8/S100A9 heterocomplex with cytochrome b(558); and (iii) to determine the S100A8 consensus site involved in cytochrome b(558)/S100 interface. Recombinant full length or S100A9-A8 truncated chimera proteins and ExoS-S100 fusion proteins were expressed in E. coli and in P. aeruginosa respectively. Our results showed that S100A8 is the functional partner for NADPH oxidase activation contrary to S100A9, however, the loading with calcium and a combination with phosphorylated S100A9 are essential in vivo. Endogenous S100A9 and S100A8 colocalize in differentiated and PMA stimulated PLB985 cells, with Nox2/gp91(phox) and p22(phox). Recombinant S100A8, loaded with calcium and fused with the first 129 or 54 N-terminal amino acid residues of the P. aeruginosa ExoS toxin, induced a similar oxidase activation in vitro, to the one observed with S100A8 in the presence of S100A9 in vivo. This suggests that S100A8 is the essential component of the S100A9/S100A8 heterocomplex for oxidase activation. In this context, recombinant full-length rS100A9-A8 and rS100A9-A8 truncated 90 chimera proteins as opposed to rS100A9-A8 truncated 86 and rS100A9-A8 truncated 57 chimeras, activate the NADPH oxidase function of purified cytochrome b(558) suggesting that the C-terminal region of S100A8 is directly involved in the molecular interface with the hemoprotein. The data point to four strategic (87)HEES(90) amino acid residues of the S100A8 C-terminal sequence that are involved directly in the molecular interaction with cytochrome b(558) and then in the phagocyte NADPH oxidase activation.     

Noxa1 is a central component of the smooth muscle NADPH oxidase in mice

NADPH oxidase is the most important source of oxygen-derived radicals (ROS) in the vascular wall. In vascular smooth muscle cells (VSMC), NADPH oxidase is characterized by the expression of the membrane subunit Nox1, which is activated by cytoplasmic proteins binding to its activation domain. We set out to identify the cytoplasmic protein involved in NADPH oxidase activation in mouse VSMC. Western blot analysis revealed that human endothelial cells and leukocytes but not VSMC from the aorta of the rat and the mouse express the classic NADPH oxidase activator p67phox. In mouse VSMC, however, the p67phox homologue Noxa1 was detected. Using antibodies generated against mouse Noxa1, the protein was observed in the cytosolic fraction of mouse VSMC with a molecular weight of about 51 kDa. Immunohistochemistry revealed that Noxa1 is expressed in the smooth muscle layer but not in endothelium or the adventitia of the mouse carotid artery. Fluorescent fusion proteins of Noxa1 were observed to be expressed in the cytoplasm of VSMC and coexpression of the NADPH oxidase organizer Noxo1 targeted the complex to membrane. An antisense plasmid of Noxa1 attenuated the endogenous Noxa1 protein expression in VSMC. This plasmid attenuated the ROS formation in mouse VSMC as detected using L012 chemiluminescence and prevented the agonist-induced ROS production in response to basic fibroblast growth factor and epidermal growth factor. In conclusion, these data indicate that Noxa1 replaces p67phox in VSMC and plays a central role in the activation of the NADPH oxidase in the vascular wall.     

BcNoxD,a putative ER protein,is a new component of the NADPH oxidase complex in Botrytis cinerea

NADPH oxidases (Nox) are major enzymatic producer of reactive oxygen species (ROS). In fungi these multi‐enzyme complexes are involved in sexual differentiation and pathogenicity. However, in contrast to mammalian systems, the composition and recruitment of the fungal Nox complexes are unresolved. Here we introduce a new Nox component, the membrane protein NoxD in the grey mold fungus Botrytis cinerea. It has high homology to the ER protein Pro41 from Sordaria macrospora, similar functions to the catalytic Nox subunit BcNoxA in differentiation and pathogenicity, and shows similarities to phagocytic p22phox. BcNoxA and BcNoxD interact with each other. Both proteins are involved in pathogenicity, fusion of conidial anastomosis tubes (CAT) and formation of sclerotia and conidia. These data support our earlier view based on localization studies, for an ER‐related function of the Nox complex. We present the first evidence that some functions of the BcNoxA complex are indeed linked to the ER, while others clearly require export from the ER.     

Targeting of Rac1 to the phagocyte membrane is sufficient for the induction of NADPH oxidase assembly

The superoxide (O(2))-generating NADPH oxidase complex of phagocytes consists of a membrane-associated flavocytochrome (cytochrome b(559)) and four cytosolic proteins, p47(phox), p67(phox), p40(phox), and the small GTPase Rac (Rac1 or -2). NADPH oxidase activation (O(2) production) is elicited as the consequence of assembly of some or all cytosolic components with cytochrome b(559). This process can be reproduced in an in vitro system consisting of phagocyte membranes, p47(phox), p67(phox), and Rac, activated by an anionic amphiphile. We now show that post-translationally processed (prenylated) Rac1 initiates NADPH oxidase assembly, expressed in O(2) production, in a cell-free system containing phagocyte membrane vesicles and p67(phox), in the absence of an activating amphiphile and of p47(phox). Prenylated Cdc42Hs, a GTPase closely related to Rac, is inactive under the same conditions. Results obtained with phagocyte membrane vesicles can be reproduced fully by replacing these with partially purified cytochrome b(559), incorporated in phosphatidylcholine vesicles. Prenylated, but not nonprenylated, Rac1 binds spontaneously to phagocyte membrane vesicles and also to artificial, protein-free, phosphatidylcholine vesicles, a process counteracted by GDP dissociation inhibitor for Rho. Binding of prenylated Rac1 to membrane vesicles is accompanied by the recruitment of p67(phox) to the same location and the formation of an assembled NADPH oxidase complex, producing O(2) upon the addition of NADPH. Amphiphile and p47(phox)-independent NADPH oxidase activation by prenylated Rac1 is inhibited by Rho GDP dissociation inhibitor and by phosphatidylcholine vesicles, both competing with membrane for prenylated Rac1. We conclude that, in vitro, targeting of Rac to the phagocyte membrane is sufficient for the induction of NADPH oxidase assembly, suggesting that the principal or, possibly, the only role of Rac is to recruit cytosolic p67(phox) to the membrane environment, to be followed by the interaction of p67(phox) with cytochrome b(559).     

P67-phox-mediated NADPH oxidase assembly: imaging of cytochrome b558 liposomes by atomic force microscopy

NADPH oxidase activity depends on the assembly of the cytosolic activating factors, p67-phox, p47-phox, p40-phox, and Rac with cytochrome b(558). The transition from an inactive to an active oxidase complex induces the transfer of electrons from NADPH to oxygen through cytochrome b(558). The assembly of oxidase complex was studied in vitro after reconstitution in a heterologous cell-free assay by using true noncontact mode atomic force microscopy. Cytochrome b(558) was purified from neutrophils and Epstein-Barr virus-immortalized B lymphocytes and incorporated into liposomes. The effect of protein glycosylation on liposome size and oxidase activity was investigated. The liposomes containing the native hemoprotein purified from neutrophils had a diameter of 146 nm, whereas after deglycosylation, the diameter was reduced to 68 nm, although oxidase activity was similar in both cases. Native cytochrome b(558) was used after purification in reconstitution experiments to investigate the topography of NADPH oxidase once it was assembled. For the first time, atomic force microscopy illustrated conformational changes of cytochrome b(558) during the transition from the inactive to the active state of oxidase; height measurements allow the determination of a size of 4 nm for the assembled complex. In the processes that were studied, p67-phox displayed a critical function; it was shown to be involved in both assembly and activation of oxidase complex while p47-phox proceeded as a positive effector and increased the affinity of p67-phox with cytochrome b(558), and p40-phox stabilizes the resting state. The results suggest that although an oligomeric structure of oxidase machinery has not been demonstrated, allosteric regulation mechanisms may be proposed.     

The heme component of the neutrophil NADPH oxidase complex is a target for aryliodonium compounds

The redox core of the neutrophil NADPH oxidase complex is a membrane-bound flavocytochrome b in which FAD and heme b are the two prosthetic redox groups. Both FAD and heme b are able to react with diphenylene iodonium (DPI) and iodonium biphenyl (IBP), two inhibitors of NADPH oxidase activity. In this study, we show that the iodonium modification of heme b contributes predominantly to the inhibition of NADPH oxidase. This conclusion is based on the finding that both iodonium compounds decreased the absorbance of the Soret peak of flavocytochrome b in neutrophil membranes incubated with NADPH, and that this decrease was strictly correlated with the loss of oxidase activity. Furthermore, the heme component of purified flavocytochrome b reduced to no more than 95% by a limited amount of sodium dithionite could be oxidized by DPI or IBP. Butylisocyanide which binds to heme iron precludes heme b oxidation. In activated neutrophil membranes, competitive inhibition of O2 uptake by DPI or IBP occurred transiently and was followed by a noncompetitive inhibition. These results, together with those of EPR spectroscopy experiments, lead us to postulate that DPI or IBP first captures an electron from the reduced heme iron of flavocytochrome b to generate a free radical. Then, the binding of this radical to the proximate environment of the heme iron, most probably on the porphyrin ring, results in inhibition of oxidase activity. In the presence of an excess of sodium dithionite, DPI and IBP produced a biphasic decrease of the Soret band of flavocytochrome b, with a break in the dose effect curve occurring at 50% of the absorbance loss. This was consistent with the presence of two hemes in flavocytochrome b that differ by their sensitivity to DPI or IBP.     

Anionic lipid-induced conformational changes in human phagocyte flavocytochrome b precede assembly and activation of the NADPH oxidase complex

Phagocyte NADPH oxidases generate superoxide at high rates in defense against infectious agents, a process regulated by second messenger anionic lipids using incompletely understood mechanisms. We reconstituted the catalytic core of the human neutrophil NADPH oxidase, flavocytochrome b (Cyt b) in 99% phosphatidylcholine vesicles in order to correlate anionic lipid-dependent conformational changes in membrane-bound Cyt b and oxidase activity. The anionic lipid 10:0 phosphatidic acid (10:0 PA) specifically induced conformational changes in Cyt b as measured by a combination of fluorescence resonance energy transfer methods and size exclusion chromatography. The fluorescence lifetime of a complex between Cyt b and Cascade Blue-derivatized anti-p22(phox) antibody (CCB-CS9), increased after exposure to 10:PA by ～50% of the change observed when the complex is dissociated, indicating a structural rearrangement of p22(phox) and/or the Cyt b heme prosthetic groups. Half of the quenching relaxation occurred at 10:0 PA concentrations permissive to less than 10% full NADPH oxidase activity, but saturated near the saturation in activity in a matched cell-free oxidase assay. We conclude that anionic lipids modulate the conformation of Cyt b in the membrane and suggest they may serve to modulate the structure of Cyt b as a control mechanism for the NADPH oxidase.     

Isolation of the respiratory burst oxidase: The role of a flavoprotein component

The article reviews the enzymatic and electron transfer properties of a low-potential FAD-dependent flavoprotein that is a component of the NADPH-dependent O ₂ ^– · -generating respiratory burst oxidase of phagocytes. Current methods available for isolation of the respiratory burst oxidase and the flavo-protein component of the complex are also reviewed. These studies and data obtained from affinity-labeling of respiratory burst oxidase components, suggest that the flavoprotein has a molecular weight of 65–67 kD. The prevailing evidence suggests that the flavoprotein functions as a dehydrogenase/electron transferase and can directly catalyse NADPH-dependent O ₂ ^– · formation when isolated. However, in neutrophil plasma membranes, the prevailing evidence suggests that the flavoprotein functions primarily to transfer electrons from NADPH to cytochromeb _–245 and that this latter redox component is the catalytic side of O ₂ ^– · formation. A working model for the arrangement of the flavorprotein and cytochromeb _–245 components of the respiratory burst oxidase in neutrophil membranes is proposed.     

Changing the conformation state of cytochrome b558 initiates NADPH oxidase activation: MRP8/MRP14 regulation

Phagocyte NADPH oxidase generates O2. for defense mechanisms and cellular signaling. Myeloid-related proteins MRP8 and MRP14 of the S100 family are EF-hand calcium-binding proteins. MRP8 and MRP14 were co-isolated from neutrophils on an anti-p47phox matrix with oxidase cytosolic factors and identified by mass spectrometry. MRP8 and MRP14 are absent from Epstein-Barr virus-immortalized B lymphocytes, and, coincidentally, these cells display weak oxidase activity compared with neutrophils. MRP8/MRP14 that was purified from neutrophils enhanced oxidase turnover of B cells in vitro, suggesting that MRP8/MRP14 is involved in the activation process. This was confirmed ex vivo by co-transfection of Epstein-Barr virus-transformed B lymphocytes with genes encoding MRP8 and MRP14. In a semi-recombinant cell-free assay, recombinant MRP8/MRP14 increased the affinity of p67phox for cytochrome b558 synergistically with p47phox. Moreover, MRP8/MRP14 initiated oxidase activation on its own, through a calcium-dependent specific interaction with cytochrome b558 as shown by atomic force microscopy and a structure-function relationship investigation. The data suggest that the change of conformation in cytochrome b558, which initiates the electron transfer, can be mediated by effectors other than oxidase cytosolic factors p67phox and p47phox. Moreover, MRP8/MRP14 dimer behaves as a positive mediator of phagocyte NADPH oxidase regulation.     

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.