Purified cytochrome b from human granulocyte plasma membrane is comprised of two polypeptides with relative molecular weights of 91,000 and 22,000

Differential characterization of neutrophil cytochrome p30 and cytochrome b-558 by low-temperature absorption and resonance Raman spectroscopies

Cytochrome p30, a novel hemoprotein isolated from rabbit peritoneal neutrophils [Escriou, V., Laporte, F., Garin, J., Brandolin, G. & Vignais, P. V. (1994) J. Biol. Chem. 269, 14007-14014] has been characterized by low-temperature (77 K) absorption and resonance Raman spectroscopies. The spectral data have been compared with those obtained with neutrophil cytochrome b-558. At room temperature, the absorption difference spectra (reduced minus oxidized) of cytochrome p30 and cytochrome b-558 could not been distinguished from each other. However, at 77 K, significant differences were observed. In particular, the alpha band of cytochrome p30 was split whereas that of cytochrome b-558 was symmetrical, but particularly broad. The resonance Raman spectra of cytochrome p30 provided evidence for the presence of two hemes both in the ferric and ferrous states. One of them was a six-coordinated low-spin heme either oxidized or reduced whereas the other one was a high-spin heme, five-coordinated in the reduced state and six-coordinated in the oxidized state. It is probable that two histidine residues constitute the axial ligands of the six-coordinated low-spin heme of cytochrome p30. The resonance Raman spectra of cytochrome b-558 allowed the detection of a six-coordinated low-spin heme, similar to that found in cytochrome p30. The component typical of the high-spin heme of cytochrome p30 was however absent in the spectra of oxidized and reduced cytochrome b-558.

Stoichiometry of the subunits of flavocytochrome b558 of the NADPH oxidase of phagocytes

Flavocytochrome b558, the membrane-spanning component of the NADPH oxidase system of phagocytic cells, is composed of two subunits, p22phox and gp91phox (where phox stands for phagocyte oxidase). The stoichiometry of the subunits has been determined for purified flavocytochrome b556 by: (1) densitometry of Coomassie Blue-stained proteins separated by SDS/PAGE, (2) aromatic absorbance at 280 mm by the subunits after separation by gel filtration under denaturing conditions, (3) crosslinking studies with bis[sulphosuccinimidyl]suberate, where the molecular mass of the cross-linked complex was determined by Western blotting, and (4) radiolabelling of pure flavocytochrome b556 on lysine residues with 125I-labelled Bolton-Hunter reagent (N-succinimidyl-3-(4-hydroxy-5-[125I]iodophenyl)propionate), followed by SDS/PAGE and determination of the radioactivity on each subunit. The ratio of p22phox to gp91phox in the purified flavocytochrome b556 was related back to that in the neutrophil membrane by quantitative Western and dot-blotting to ensure that the stoichiometry was maintained during purification. These measurements showed that the two subunits were present in neutrophil membranes in a molar ratio of 1:1.

Interactions between the components of the human NADPH oxidase: intrigues in the phox family

The human NADPH oxidase is a very intriguing enzyme; although its catalytic unit is retained within cytochrome b558, various additional proteins are required for activity of the NADPH oxidase. In the past few years substantial progress has been made to elucidate the protein-protein interactions and the activation events involved. The following facts have become evident: (1) activation of rac and subsequent interaction with p67-phox is crucial for the interaction of p67-phox with cytochrome b558, and probably with gp91-phox; (2) p47-phox interacts with p22-phox, and phosphorylation of 379Ser of p47-phox is obligatory for this event; (3) p47-phox and p67-phox regulate each other's translocation in a positive sense (see also reference 71). To put it differently: it is vital to gain insight in the intrigues within the phox family and associated characters to fully understand NADPH oxidase activation.

NADPH oxidase

Superoxide is instrumental in the killing of microorganisms by phagocytic cells. It is generated by the NADPH oxidase system, a membrane-bound electron transport complex which pumps electrons from NADPH in the cytoplasm across the wall of the phagocytic vacuole to molecular oxygen. Superoxide deficiency results in the genetically inherited condition Chronic Granulomatous Disease (CGD), in which the patient is abnormally susceptible to infection. In recent years many of the underlying genetic defects in CGD have been identified and are providing important insights into the structure and mechanism of the NADPH oxidase complex.

Characterization of peptide diffusion into electropermeabilized neutrophils

The superoxide (O2-)-generating NADPH oxidase of human neutrophils consists of membrane-bound and cytosolic proteins that assemble in the plasma membrane of activated cells. To date, most of our understanding of the assembly of the NADPH oxidase has been obtained through the use of a cell-free assay, and a number of peptides that mimic regions of NADPH oxidase proteins have been shown to block oxidase assembly using this assay. However, the cell-free assay provides an incomplete representation of the assembly and regulation of the NADPH oxidase in vivo, and it has become necessary to develop methods for introducing biomolecules, such as peptides, into intact neutrophils where their effects can be investigated. One such method is electropermeabilization. Although this method has been used previously with human neutrophils, it has not been well characterized. We report here a detailed characterization of the electropermeabilized neutrophil assay system, including optimal conditions for membrane electropermeabilization with maximal retention of functional capacity, optimal conditions for analyzing the effects of experimental peptides, quantification of internalized peptide concentration, and molecular size limits for diffusion of molecules into these cells. Our results demonstrate that optimal neutrophil permeabilization (98-100%) can be achieved using significantly lower electrical fields than previously reported, resulting in the retention of higher levels of O2(-)-generating activity. We also found that biomolecules as large as 2.3 kDa readily diffuse into permeabilized cells. Analysis of flavocytochrome b peptides that were shown previously to inhibit NADPH oxidase activity in a cell-free assay demonstrated that these peptides also blocked O2- production in electropermeabilized human neutrophils; although at higher effective concentrations than in the cell-free system. Thus, electropermeabilized neutrophils provide a model system for evaluating the effects of peptides and other pharmacological agents in intact cells which closely mimic neutrophils in vivo.

p22phox is a critical component of the superoxide-generating NADH/NADPH oxidase system and regulates angiotensin II-induced hypertrophy in vascular smooth muscle cells

Superoxide anion formation is vital to the microbicidal activity of phagocytes. Recently, however, there is accumulating evidence that it is also involved in cell growth in vascular smooth muscle cells (VSMCs). We have shown that the hypertrophic agent angiotensin II stimulates superoxide production by activating the membrane-bound NADH/NADPH oxidase and that inhibition of this oxidase attenuates vascular hypertrophy. However, the molecular identity of this oxidase in VSMCs is unknown. We have recently cloned the cytochrome b558 alpha-subunit, p22(phox) (one of the key electron transfer elements of the NADPH oxidase in phagocytes), from a rat VSMC cDNA library, but its role in VSMC oxidase activity remains unclarified. Here we report that the complete inhibition of p22(phox) mRNA expression by stable transfection of antisense p22(phox) cDNA into VSMCs results in a decrease in cytochrome b content, which is accompanied by a significant inhibition of angiotensin II-stimulated NADH/NADPH-dependent superoxide production, subsequent hydrogen peroxide production, and [3H]leucine incorporation. We provide the first evidence that p22(phox) is a critical component of superoxide-generating vascular NADH/NADPH oxidase and suggest a central role for this oxidase system in vascular hypertrophy.

The cytosolic subunit p67phox contains an NADPH-binding site that participates in catalysis by the leukocyte NADPH oxidase

The NADPH-dependent respiratory burst oxidase of human neutrophils catalyzes the reduction of oxygen to superoxide using NADPH as the electron donor and is essential for normal host defenses. To gain insight into the function of the various oxidase subunits that are required for the full expression of catalytic activity, we studied the interactions between the 2',3'-dialdehyde derivative of NADPH (NADPH dialdehyde) and neutrophil cytosol. NADPH dialdehyde treatment of cytosol resulted in the loss of the ability of the cytosol to participate in cell-free oxidase activation; this inactivation was blocked by NADPH but not by NAD, NADP, or GTP. Partial purification of neutrophil cytosol yielded a single peak which could restore the activity lost in cytosol treated with NADPH dialdehyde. This peak contained p67phox but not p47phox or Rac2. Purified recombinant p67phox was similarly able to restore the activity lost in NADPH dialdehyde-treated cytosol and bound [32P]NADPH dialdehyde in a specific fashion. The activity of recombinant p67phox in cell-free oxidase assays was lost on treatment with NADPH dialdehyde. Together, these data suggest p67phox contains the catalytic NADPH-binding site of the leukocyte NADPH oxidase.

CCAAT displacement protein competes with multiple transcriptional activators for binding to four sites in the proximal gp91phox promoter

CCAAT displacement protein (CDP) competes with transcriptional activating proteins for binding to each of four elements within the myeloid-specific gp91(phox) promoter. CDP exhibits the strongest affinity for a site centered at -110 base pairs (bp) of the promoter and progressively weaker affinities for three more distal binding sites. CDP binding to each site is down-regulated during terminal phagocytic differentiation, coincident with induction of gp91(phox) expression. Deletion of the high affinity CDP-binding site at -110 bp leads to inappropriate gp91(phox) promoter activity in HeLa, K562, and HEL cells. An overlapping binding site for the CCAAT box-binding factor CP1 is required for derepressed promoter activity in HeLa and K562 cells, but is dispensable in HEL cells, indicating that different cell types require distinct cis-elements for gp91(phox) promoter activity. Derepressed gp91(phox) promoter activity is further increased upon removal of a second CDP-binding site centered at -150 bp, revealing that CDP represses gp91(phox) expression via multiple cis-elements. We present a model in which restriction of gp91(phox) expression to mature myeloid cells involves competition between transcriptional activators and repressors for binding to multiple sites within the promoter.

Assembly of the human neutrophil NADPH oxidase involves binding of p67phox and flavocytochrome b to a common functional domain in p47phox

The human neutrophil NADPH oxidase is a multi-component complex composed of membrane-bound and cytosolic proteins. During activation, cytosolic proteins p47(phox), p67(phox), Rac2, and possibly p40(phox) translocate to the plasma membrane and associate with flavocytochrome b to form the active superoxide-generating system. To further investigate the role of p67(phox) in this complex assembly process, experiments were performed to identify possible regions of interaction between p67(phox) and other NADPH oxidase proteins. Using random sequence peptide phage-display library analysis of p67(phox), we identified a novel region in p47(phox) encompassing residues 323-332 and a previously identified SH3 binding domain encompassing p47(phox) residues 361-370 as p67(phox) binding sites. Synthetic peptides mimicking p47(phox) residues 323-332 inhibited the p47(phox)-p67(phox) binding interaction in an affinity binding assay; however, peptides mimicking flanking regions were inactive. Surprisingly, this same region of p47(phox) was found previously to represent a site of binding interaction for flavocytochrome b (DeLeo, F. R., Nauseef, W. M., Jesaitis, A. J., Burritt, J. B., Clark, R. A., and Quinn, M. T.(1995) J. Biol. Chem. 270, 26246-26251), and this observation was confirmed in the present report using two different in vitro assays that were not evaluated previously. Using affinity binding assays, we also found that p67(phox) and flavocytochrome b competed for binding to p47(phox)after activation, suggesting that prior to full NADPH oxidase assembly the 323-332 region of p47(phox) is associated with p67(phox) and at some point in the activation process is transferred to flavocytochrome b. Thus, taken together our data demonstrate that both p67(phox) and flavocytochrome b utilize a common binding site in p47(phox), presumably at distinct stages during the activation process, and this p47(phox) region plays a key role in regulating NADPH oxidase assembly.

Fixation traps formyl peptide receptors in high and low affinity forms that can be regulated by GTP[S] in the absence of ligand

The formyl peptide receptor on human neutrophils recognizes bacterial, N-formylated peptides and initiates a cascade of intracellular signals via a pertussis toxin sensitive Gi protein. We used fluorescence techniques to investigate the interactions of ligand (L), receptor (R), and G proteins (G), the ternary complex, in both live and fixed human neutrophils. By lightly fixing permeabilized neutrophils with a procedure that retained ligand binding, we were able to "capture' R and G in different configurations in the absence of ligand. Fixed receptors were trapped in a high affinity form (attributed to LRG) that could not be rapidly converted to low affinity by the addition of GTP[S]. Adding saturating nucleotide prior to fixation trapped receptors in a low affinity form (attributed to LR). The low affinity receptors retained the sensitivity of the native receptors to the presence of NA+. The distribution between high and low affinity receptors was modulated by GTP[S] in a dose dependent manner. The ability to redistribute low and high affinity receptor forms prior to fixation was unique to GTP[S], as compared to other non-activating nucleotides, suggesting that GTP[S] can regulate the distribution between R and RG. We suggest that precoupled receptors that give rise to high affinity ligand binding are likely to exist in native membranes in human neutrophils.

Spectroscopic identification of the heme axial ligation of cytochrome b558 in the NADPH oxidase of porcine neutrophils

The combination of electron paramagnetic resonance (EPR), near-infrared magnetic circular dichroism (NIR-MCD) and resonance Raman (RR) spectroscopies at cryogenic temperatures has been used to identify the axial heme ligation of the low spin cytochrome b558 component of NADPH oxidase from porcine blood neutrophils. The EPR and NIR-MCD results indicate the presence of two distinct forms in frozen solution; one with a low field g-value at 3.23 and porphyrin(pi)-to-Fe(III) charge transfer maximum at 1660 nm and the other a low field g-value at 3.00 and porphyrin(pi)-to-Fe(III) charge transfer maximum at 1510 nm. On the basis of these properties and the RR studies, both are attributed to forms of cytochrome b558 with bis-histidine axial ligation. The origin of the observed heterogeneity, the location and identity of the specific histidines involved in ligating the heme, and the role of the heme prosthetic group in O2- production are discussed in light of these results.

NADPH oxidase and the respiratory burst

Phagocytic cells possess an electron-transport system which accepts electrons from NADPH in the cytosol to reduce oxygen to the superoxide radical in the vacuolar lumen. The superoxide is instrumental in killing ingested microorganisms. Patients suffering from chronic granulomatous disease (CGD), in which this system is failing, are abnormally susceptible to infectious diseases. Studying CGD patients' neutrophils has been enormously helpful in identifying the components of the superoxide-generating system, known as the NADPH oxidase. This review will describe the components of the electron-transport chain involved in the oxidase and the factors needed for its regulation.

Characterization of neutrophil NADPH oxidase activity reconstituted in a cell-free assay using specific monoclonal antibodies raised against cytochrome b558

The immunochemical characterization of NADPH oxidase activity of cytochrome b558 purified from human neutrophils was determined after reconstitution in a cell-free assay using the native hemoprotein and recombinant purified cytosolic activating factors. The oxidase activity showed a strict dependence on the heme content at each step of the hemoprotein purification process. The immunochemical properties of the reconstituted oxidase made use of monoclonal antibodies raised against membrane-bound and octyl-glucoside-extracted cytochrome b. From nine specific monoclonal antibodies reacting with gp91-phox cytochrome b558, two were selected, both of which were found to bind to the beta subunit of cytochrome b558 and to inhibit superoxide formation in the oxidase reconstituted cell-free assay. The extent of inhibition was dependent on the phospholipid environment. Neutrophil membrane extracts from X-linked chronic granulomatous disease patients did not produce O2- in the reconstituted system and did not bind to the antibodies.

A domain of p47phox that interacts with human neutrophil flavocytochrome b558

The NADPH-dependent oxidase of human neutrophils is a multicomponent system including cytosolic and membrane proteins. Activation requires translocation of cytosolic proteins p47phox, p67phox, and Rac2 to the plasma membrane and association with the membrane flavocytochrome b to assemble a functioning oxidase. We report the location of a region in p47phox that mediates its interaction with flavocytochrome b. From a random peptide phage display library, we used biopanning with purified flavocytochrome b to select phage peptides that mimicked potential p47phox binding residues. Using this approach, we identified a region of p47phox from residue 323 to 342 as a site of interaction with flavocytochrome b. Synthetic peptides 315SRKRLSQDAYRRNS328, 323AYRRNSVRFL332, and 334QRRRQARPGPQSPG347 inhibited superoxide (O2-.) production in the broken cell system with IC50 of 18, 57, and 15 microM, respectively. 323AYRRNSVRFL332 and its derivative peptides inhibited phosphorylation of p47phox. However, the functional importance of this peptide was independent of its effects on phosphorylation, since 323AYRRNAVRFL332 inhibited O2-. production, but had no effect on phosphorylation. None of the peptides blocked O2-. production when added after enzyme activation, suggesting that they inhibited the assembly, rather than the activity, of the oxidase. Furthermore these peptides inhibited membrane association of p47phox in the broken cell translocation assay and O2-. production by electropermeabilized neutrophils, thereby supporting the interpretation that this region of p47phox interacts with flavocytochrome b.

Cytochrome b-558 alpha-subunit cloning and expression in rat aortic smooth muscle cells

Recent studies have shown that the NADPH oxidase participates in the generation of superoxide anion in non-phagocytic cells. Here we report the isolation and nucleotide sequence of a cDNA for the cytochrome b-558 alpha-subunit of the NADPH oxidase in rat vascular smooth muscle cells (VSMCs). The coding region of the cDNA was 93% homologous to mouse and 81% to human in nucleotide sequence and 96% homologous to mouse and 89% to human in the deduced amino acid sequence. Our results provide a tool with which to explore the mechanism of superoxide anion generation in rat VSMCs and other non-phagocytic cells.

Heparin is an adhesive ligand for the leukocyte integrin Mac-1 (CD11b/CD1)

Previous studies have demonstrated that the leukocyte integrin Mac-1 adheres to several cell surface and soluble ligands including intercellular adhesion molecule-1, fibrinogen, iC3b, and factor X. However, experiments with Mac-1-expressing transfectants, purified Mac-1, and mAbs to Mac-1 indicate the existence of additional ligands. In this paper, we demonstrate a direct interaction between Mac-1 and heparan sulfate glycans. Heparin affinity resins immunoprecipitate Mac-1, and neutrophils and transfectant cells that express Mac-1 bind to heparin and heparan sulfate, but not to other sulfated glycosaminoglycans. Inhibition studies with mAbs and chemically modified forms of heparin suggest the I domain as a recognition site on Mac-1 for heparin, and suggest that either N- or O-sulfation is sufficient for heparin to bind efficiently to Mac-1. Under conditions of continuous flow in which heparins and E-selectin are cosubstrates, neutrophils tether to E-selectin and form firm adhesions through a Mac-1-heparin interaction.

Cytochrome b-245 of the neutrophil superoxide-generating system contains two nonidentical hemes. Potentiometric studies of a mutant form of gp91phox

Analysis of potentiometric titrations of the cytochrome b-245 from a X+ chronic granulomatous disease patient with an Arg54 --> Ser mutation in gp91phox indicates that the mutant form of the cytochrome contains two nonidentical hemes with midpoint potentials of Em7 = -220 and Em7 = -300 mV. In the light of this information, reanalysis of redox titrations of wild-type cytochrome b-245 implies that it probably also contains two separate heme centers with midpoint potentials of Em7 = -225 and Em7 = -265 mV. The effect of the Arg54 --> Ser substitution is to reduce the midpoint potential of one of the heme centers by approximately 35 mV and suggests possible interaction between Arg54 and a heme propionate side chain.

Mapping sites of interaction of p47-phox and flavocytochrome b with random-sequence peptide phage display libraries

During assembly of the phagocyte NADPH oxidase, cytosolic p47-phox translocates to the plasma membrane and binds to flavocytochrome b, and binding domains for p47-phox have been identified on the C-terminal tails of both flavocytochrome b subunits. In the present report, we further examine the interaction of these two oxidase components by using random-sequence peptide phage display library analysis. Screening p47-phox with the peptide libraries identified five potential sites of interaction with flavocytochrome b, including three previously reported regions of interaction and two additional regions of interaction of p47-phox with gp91-phox and p22-phox. The additional sites were mapped to a domain on the first predicted cytosolic loop of gp91-phox encompassing residues S86TRVRRQL93 and to a domain near the cytosolic C-terminal tail of gp91-phox encompassing residues F450EWFADLL457. The mapping also confirmed a previously reported binding domain on gp91-phox (E554SGPRGVHFIF564) and putative Src homology 3 domain binding sites on p22-phox (P156PRPP160 and G177GPPGGP183). To demonstrate that the additional regions identified were biologically significant, peptides mimicking the gp91-phox sequences F77LRGSSACCSTRVRRQL93 and E451WFADLLQLLESQ463 were synthesized and assayed for their ability to inhibit NADPH oxidase activity. These peptides had EC50 values of 1 microM and 230 microM, respectively, and inhibited activation when added prior to assembly but did not affect activity of the preassembled oxidase. Our data demonstrate the usefulness of phage display library analysis for the identification of biologically relevant sites of protein-protein interaction and show that the binding of p47-phox to flavocytochrome b involves multiple binding sites along the C-terminal tails of both gp91- and p22-phox and other regions of gp91-phox nearer to the N terminus.

Topological mapping of neutrophil cytochrome b epitopes with phage-display libraries

Cytochrome b of human neutrophils is the central component of the microbicidal NADPH-oxidase system. However, the folding topology of this integral membrane protein remains undetermined. Two random-sequence bacteriophage peptide libraries were used to map structural features of cytochrome b by determining the epitopes of monoclonal antibodies (mAbs) 44.1 and 54.1, specific for the p22phox and gp91phox cytochrome b chains, respectively. The unique peptides of phage selected by mAb affinity purification were deduced from the phage DNA sequences. Phage selected by mAb 44.1 displayed the consensus peptide sequence GGPQVXPI, which is nearly identical to 181GGPQVNPI18 of p22phox. Phage selected by mAb 54.1 displayed the consensus sequence PKXAVDGP, which resembles 382PKIAVDGP389 of gp91phox. Western blotting demonstrated specific binding of each mAb to the respective cytochrome b subunit and selected phage peptides. In flow cytometric analysis, mAb 44.1 bound only permeabilized neutrophils, while 54.1 did not bind intact or permeabilized cells. However, mAb 54.1 immunosedimented detergent-solubilized cytochrome b in sucrose gradients. These results suggest the 181GGPQVNPI188 segment of p22phox is accessible on its intracellular surface, but the 382PKIAVDGP389 region on gp91phox is not accessible to antibody, and probably not on the protein surface.

A variant X-linked chronic granulomatous disease patient (X91+) with partially functional cytochrome b

Genetic analysis of a patient with the variant cytochrome b-245-positive form of chronic granulomatous disease revealed a missense mutation resulting in a Arg54-->Ser substitution in the gp91phox subunit of cytochrome b-245. As a consequence, although no O2- is made, NADPH oxidase-associated FAD accepts electrons from NADPH in the cell-free activation system and becomes reduced. The reduced flavin exhibits normal levels of iodonitrotetrazolium violet diaphorase activity, and the patient's neutrophils exhibit high levels of intracellular oxidant production and show a low level of NBT staining in the NBT slide test. Thus, this mutation appears to render the heme center of NADPH oxidase present but nonfunctional, while leaving the flavin center fully functional.

The NADPH oxidase complex of phagocytic leukocytes: a biochemical and cytochemical view

The NADPH oxidase complex catalyzes the formation of superoxide (O2.-) in phagocytic leukocytes. This paper reviews recent advances in our understanding of this enzyme system. Recent studies have defined conditions for reconstitution of this enzymatic activity with purified proteins in a cell-free system. The role of the individual proteins that make up the active complex, their regulation and the effects of mutations in these proteins are discussed. While these studies represent major achievements, it is clear from cytochemical investigations that additional levels of complexity exist in the modulation of the NADPH oxidase complex in vivo. A major role for cytochemical analysis in understanding the cell biological aspects of the generation of reactive oxygen species is discussed.

Modulation of the heme environment of neutrophil cytochrome b558 to a "cytochrome P450-like" structure by pyridine

The effect of pyridine on the heme environment of cytochrome b558 was studied using ESR and optical absorption spectroscopy in relation to the O2(-)-generating activity in the NADPH oxidase system of stimulated pig neutrophils. As the concentration of pyridine increased, the absorption maxima of the alpha- and gamma-bands of cytochrome b558 shifted which correlated with a concomitant decrease in O2(-)-generating activity. In addition, the g = 3.2 signal of cytochrome b558 decreased with the concomitant appearance of a new ESR spectrum that strikingly resembled that of cytochrome P450. The results suggest that pyridine induces a structural modification in the heme environment of cytochrome b558 by shifting the 5th heme ligand (histidine) to a nearby thiolate group without direct binding of pyridine to the heme. The existence of a reactive thiolate near the heme iron was confirmed by pretreatment of blocked cytochrome b558 with p-chloromercuribenzoate, which completely inhibited the formation of the cytochrome P450-like ESR spectrum. The results provide further evidence that a low-spin heme iron of cytochrome b558 with a g-value of 3.2 is essential to the O2(-)-forming reaction of the NADPH oxidase system. From sequence alignments of cytochrome P450 with those of large and small subunits of cytochrome b558, the heme in cytochrome b558 appears to be specifically associated with the large subunit.

Interleukin-4 suppresses the expression of macrophage NADPH oxidase heavy chain subunit (gp91-phox)

The production of superoxide anion by NADPH oxidase is a principal nonspecific bactericidal activity of macrophages and neutrophils in host defense. However, exuberant production of superoxide anion also damages host tissues. Cloning and DNA sequencing of the 91 kDa subunit (gp91-phox) open reading frame indicated a high degree of sequence conservation, greater than 90% in nucleotide and amino acid sequences, between the porcine and human cDNAs. We show in pigs that interleukin-4 (IL-4), a T lymphocyte cytokine which plays a major role in mediating antibody responses to pathogens, suppresses superoxide anion production in macrophages by specifically reducing the level of mRNA encoding gp91-phox. Messenger RNA levels are suppressed approx. 70% within 4 h and persist for 24 h without any change in the rate of mRNA turnover. Nuclear run-on analysis showed that IL-4 did not alter the rate of gp91-phox gene transcription under conditions in which IL-1 beta transcription was inhibited. These results indicate that IL-4 suppresses the inflammatory response of macrophages by mechanisms that include post-transcriptional regulation of the 91 kDa catalytic subunit of NADPH oxidase, and transcriptional regulation of inflammatory cytokine expression.

Low NADPH oxidase activity in Epstein-Barr-virus-immortalized B-lymphocytes is due to a post-transcriptional block in expression of cytochrome b558

The NADPH oxidase of phagocytes is known to be expressed in Epstein-Barr-virus-transformed B-lymphocytes, albeit at levels only approx. 5% of those found in neutrophils. We have investigated the basis of this low level of expression and find that all four specific components of the NADPH oxidase are expressed in B-lymphocytes, but only p47-phox protein attains levels equivalent with those found in neutrophils. This component was shown to phosphorylate and translocate to the membrane normally on activation. The other cytosolic component, p67-phox, did show a deficit, and by supplementing a B-cell cytosol extract with recombinant p67-phox, this was shown to account for the somewhat reduced activity of B-cell cytosol in a cell-free oxidase system. The cell-free analysis also clearly located the major deficiency in superoxide-generating capacity of B-lymphocytes to the membrane. Western blotting of membrane proteins revealed major reductions in the amount of cytochrome b558. Analysis of the levels of mRNA for both subunits of cytochrome b558, however, showed levels greater than expected. Significantly more mRNA for gp91-phox was present in B-cells than in undifferentiated HL60 cells, although it was not quite as abundant as in differentiated HL60 cells, which are capable of producing large amounts of superoxide. We conclude that the failure of B-lymphocytes to generate amounts of superoxide equivalent to those generated by neutrophils is primarily due to a post-transcriptionally determined block to the accumulation of cytochrome b558.

Mouse model of X-linked chronic granulomatous disease, an inherited defect in phagocyte superoxide production

Chronic granulomatous disease (CGD) is a recessive disorder characterized by a defective phagocyte respiratory burst oxidase, life-threatening pyogenic infections and inflammatory granulomas. Gene targeting was used to generate mice with a null allele of the gene involved in X-linked CGD, which encodes the 91 kD subunit of the oxidase cytochrome b. Affected hemizygous male mice lacked phagocyte superoxide production, manifested an increased susceptibility to infection with Staphylococcus aureus and Aspergillus fumigatus and had an altered inflammatory response in thioglycollate peritonitis. This animal model should aid in developing new treatments for CGD and in evaluating the role of phagocyte-derived oxidants in inflammation.

Purification of human neutrophil NADPH oxidase cytochrome b-558 and association with Rap 1A

The availability of sufficient quantities of highly purified phagocyte cytochrome b-558 has been necessary for many of the biochemical and immunological analyses of this important NADPH oxidase component, and it was only through the analysis of highly purified cytochrome b that the subunit composition was elucidated and the small subunit (p22-phox) was cloned and sequenced. In addition, the association of the small GTP-binding protein Rap1A with cytochrome b-558 was discovered through the analysis of purified cytochrome b. The procedures described here provide an easy, efficient, and highly reproducible method for the purification of cytochrome b as well as cytochrome b-Rap1A complexes. The ability to purify cytochrome b and cytochrome b-Rap1A complexes will also allow further analysis of the structure of this novel plasma membrane redox protein and the role of its association with low molecular weight GTP-binding proteins in the structure and regulation of the phagocyte NADPH oxidase.

The regulation of superoxide production by the NADPH oxidase of neutrophils and other mammalian cells

Superoxide is produced by a NADPH oxidase of phagocytic cells and contributes to their microbicidal activities. The oxidase is activated when receptors in the neutrophil plasma membrane bind to the target microbe. These receptors recognise antibodies and complement fragments which coat the target cell. The oxidase electron transport chain, located in the plasma membrane, comprises a low potential cytochrome b heterodimer (gp 91-phox and p22-phox) associated with FAD. It is non-functional until at least three proteins, p67-phox, p47-phox and p21rac (and possibly others), move from the cytosol to dock on the cytochrome b. The docking involves the interaction of SH3 domains on p47-phox or p67-phox with a proline-rich sequence on the small subunit of the cytochrome b. These SH3 domains may become exposed following phosphorylation of p47-phox by protein kinase C or, in model systems, by addition of arachidonic acid to reconstitution mixtures. Following the docking process the electron-transporting component is able to transfer electrons from NADPH to oxygen. This electrogenic event is charge-compensated by the opening of a proton channel. Components of the oxidase are expressed in non-phagocytes, where their function is uncertain but could be related to some signal function of superoxide.

Activation of the respiratory burst oxidase

The respiratory burst oxidase of phagocytes and B lymphocytes catalyzes the reduction of oxygen by NADPH to form O2-, the precursor of a group of reactive oxidants that are employed by phagocytes as microbicidal agents. The enzyme is active in stimulated cells but dominant in resting cells. It molecular weight guanine nucleotide-binding protein. The components p22phox and gp91phox from cytochrome b558, a flavohemoprotein that resides in the cortical cytoskeleton and in the membranes of the specific granules. The other components are found in the cytosol of resting cells, but migrate to the cortical cytoskeleton when the neutrophils are activated, where they assemble the active oxidase. Migration to the cortical cytoskeleton is caused in part by the appearance of a membrane binding site on one or more of the cytosolic subunits, possibly due to the phosphorylation of p47phox that takes place during cell activation.

The functional expression of p47-phox and p67-phox may contribute to the generation of superoxide by an NADPH oxidase-like system in human fibroblasts

Recent evidence suggests that a number of non-phagocytic cell types may contain a superoxide generating NADPH oxidase. Studies to data on cultured human fibroblasts have primarily concerned the identification of cytochrome b558, whilst expression of other NADPH oxidase components have not been addressed. In this study we have investigated the expression of NADPH oxidase with particular reference to the cytosolic factors p47-phox and p67-phox. Reverse transcriptase-polymerase chain reaction (RT-PCR) showed that human fibroblasts express mRNA for p47-phox, p67-phox and p22-phox. Expression of the gp91-phox transcript was not detected, indicating that human fibroblasts may possess an NADPH oxidase isoenzyme. Western blot analysis of human fibroblast cytosol, using an anti-p47-phox antibody (JW-1), identified a 47 kDa protein. Cell-free reconstitution assays showed that fibroblast cytosol could initiate superoxide generation when mixed with either human fibroblast membranes (0.16 nmol superoxide/min/microgram membrane protein), or resting human neutrophil membranes (0.20 nmol superoxide/min/microgram membrane protein). These data indicate that the expression of p47-phox and p67-phox by human fibroblasts may contribute to the cells' generation of superoxide.

Characterization of complex formation between Gi2 and octyl glucoside solubilized neutrophil N-formyl peptide chemoattractant receptor by sedimentation velocity

The reversible formation of complexes between N-formyl peptide chemoattractant receptor (FPR) and Gi2 protein was analyzed by velocity sedimentation in linear sucrose density gradients. FPR complexed with heterotrimeric Gi2, sediments at different rate than uncomplexed FPR and the two forms have apparent sedimentation coefficients of 7S and 4S, respectively. The biochemical variables important for the reconstitution of the 7S complex from the 4S receptor and Gi2 were studied. The formation of 7S was saturable with Gi2 and addition of excess Gi did not cause oligomerization. The reconstituted 7S complex was stable under a variety of conditions including octyl glucoside concentrations below and above the critical micellar concentration. The optimum pH for the reconstitution is between 7 and 9, where the 4S and 7S species sedimented reproducibly, at distinct positions in the gradient. Below pH 6 both the 4S and the 7S species appear to undergo denaturation and form precipitates. Magnesium ions have no significant effect on the sedimentation of either forms of FPR. Reconstitution was stable up to a NaCl concentration of 0.2 M. At 1 M NaCl reconstitution was inhibited and at 3 M salt FPR aggregated. Since guanine nucleotides GTP, GTP gamma S, GDP beta S selectively dissociated the 7S complex in a concentration-dependent manner and adenine nucleotides had no effect, we conclude that the FPR-Gi2 system displays a vacant guanyl nucleotide binding site, the hallmark of a functional guanine nucleotide exchange complex. Moreover, our results indicate that the reconstitution of FPR-Gi2 complexes is reproducible at physiologically relevant conditions, shows selectivity, specificity, and biochemically functional properties consistent with a specific and functional interaction between solubilized FPR and G protein.

The interaction of N-formyl peptide chemoattractant receptors with the membrane skeleton is energy-dependent

Desensitization of N-formyl peptide chemoattractant receptors (FPR) in human neutrophils is thought to be achieved by lateral segregation of receptors and G proteins within the plane of the plasma membrane resulting in an interruption of the signalling cascade. Direct coupling of FPR to membrane skeletal actin appears to be the basis of this process; however, the molecular mechanism is unknown. In this study we investigated the effect of energy depletion on formation of FPR-membrane skeleton complexes. In addition the effect of the protein kinase C inhibitor stauroporine and the phosphatase inhibitor okadaic acid on coupling of FPR to the membrane skeleton was studied. Human neutrophils were desensitized using the photoreactive agonist N-formyl-met-leu-phe-lys-N'-[125I]2(p-azidosalicylamido)ethyl-1,3' - dithiopropionate (fMLFK-[125I]ASD) after ATP depletion with NaF or after incubation with the respective inhibitors. The interaction of FPR with the membrane skeleton was studied by sedimentation of the membrane skeleton-associated receptors in sucrose density gradients. Energy depletion of the cells markedly inhibited the formation of FPR-membrane skeleton complexes. This does not appear to be related to inhibition of protein phosphorylation due to ATP depletion because inhibition of protein kinases and phosphatases had no significant effect on coupling of FPR to the membrane skeleton. We conclude, therefore, that coupling of FPR to the membrane skeleton is an energy-dependent process which does not appear to require modification of the receptor protein by phosphorylation.

Cloning and expression of the gene encoding the porcine NADPH oxidase light-chain subunit (p22-phox)

In previous studies, we showed that interleukin-4 (IL-4) suppressed porcine (p) macrophage superoxide production and that the mechanism of suppression involved down-regulation of the superoxide-generating enzyme NADPH oxidase heavy-chain 91-kDa subunit mRNA (gp91-phox) expression. In order to examine the effect of IL-4 on expression of the gene encoding the porcine NADPH oxidase light-chain 22-kDa subunit (p22-phox), we cloned the p22-phox cDNA from a macrophage library. The p22-phox cDNA is 786 bp in length and contains a 576-bp open reading frame which predicts a primary translation product of 192 amino acids (aa). Comparison of the porcine and human 22-phox cDNAs showed a high degree of similarity between the two species in their nucleotide (85%) and deduced aa (83%) sequences. as well as in their hydropathy profiles. Notable features, including a high proline content and an iron-coordinating His94, are conserved in both the porcine and human 22-Phox. A single species of mRNA of about 1 kb was detected in macrophages. The mRNA levels remained unchanged in cells treated with lipopolysaccharide (LPS) or with IL-4 at various concentrations from 0-50 ng/ml. Prolonged treatment with LPS or IL-4 did not enhance the effect of these substances on p22-phox mRNA expression. The effect of IL-4 on p22-phox mRNA expression was also compared with another immunosuppressive cytokine, transforming growth factor-beta 1 (TGF beta 1). No change in mRNA expression was found in the cells with or without TGF beta 1 treatment. The results indicated that the heavy and light chains of NADPH oxidase are independently regulated by IL-4 in macrophages.

Physical coupling of N-formyl peptide chemoattractant receptors to G protein is unaffected by desensitization

Desensitization of N-formyl peptide chemoattractant receptors (FPR) in human neutrophils results in association of these receptors to the membrane skeleton. This is thought to be the critical event in the lateral segregation of receptors and guanyl nucleotide-binding proteins (G proteins) within the plane of the plasma membrane resulting in an interruption of the signaling cascade. In this study we probed the interaction of FPR with G protein in human neutrophils that were desensitized to various degrees. Human neutrophils were desensitized using the photoreactive agonist N-formyl-met-leu-phe-lys-N epsilon-[125I]2(p-azidosalicylamino)ethyl-1,3'- dithiopropionate (fMLFK-[125I]ASD). The interaction of FPR with protein was studied via a reconstitution assay and subsequent analysis of FPR-G protein complexes in sucrose density gradients. FPR-G protein complexes were reconstituted with solubilized FPR from partially and fully desensitized neutrophils with increasing concentrations of Gi purified from bovine brain. The respective EC50 values for reconstitution were similar to that determined for FPR from unstimulated neutrophils (Bommakanti RK et al., J Biol Chem 267: 7576-7581, 1992). We conclude, therefore, that the affinity of the interaction of FPR with G protein is not affected by desensitization, consistent with the model of lateral segregation of FPR and G protein as a mechanism of desensitization.

Myeloid haemopoietic cells of patients with chronic granulomatous disease are relatively resistant to TNF

Generation of superoxide may be a key step in the cytotoxicity mediated by tumour necrosis factor (TNF); cells that cannot produce oxygen radicals might be resistant to TNF. Myeloid haemopoietic cells from patients with chronic granulomatous disease (CGD) cannot produce a large burst of oxygen radicals; therefore we examined the ability of TNF to inhibit clonal growth of myeloid haemopoietic cells from patients and carriers with several types of CGD. Mononuclear light-density cells from the peripheral blood of 13 CGD patients (11 patients with defects of gp91-phox and two with p47-phox), five gp91-phox carriers and 10 normal volunteers were cultured with the appropriate growth factor and TNF in methylcellulose. As expected, TNF (0.001-100 ng/ml) inhibited colony formation of myeloid cells of normal volunteers in a dose-dependent manner. In contrast, clonal growth of myeloid cells of CGD patients was resistant to inhibition by TNF < or = 100 ng/ml. As expected, the effects of TNF on erythroid clonogenic cells, which are not capable of producing an oxygen burst, and the action of TGF-beta on clonal growth of myeloid cells, were similar in both the individuals with CGD and the normal volunteers. In X chromosome-linked female carriers of CGD (gp91-phox deficiency), TNF showed an intermediate cytotoxicity on clonal growth of myeloid cells, and analysis of NBT reduction demonstrated that the colonies derived from myeloid cells deficient in gp91-phox were resistant to TNF and those derived from the myeloid cells expressing gp91-phox were inhibited in their proliferation by TNF. This study shows for the first time that myeloid haemopoietic cells from patients with CGD are relatively resistant to the growth-inhibiting effects of high concentrations of TNF.

Mutations in the promoter region of the gene for gp91-phox in X-linked chronic granulomatous disease with decreased expression of cytochrome b558

We examined the molecular defect in two kindreds with "variant" X-linked chronic granulomatous disease (CGD). Western blots of neutrophil extracts showed decreased immunoreactive cytochrome b558 components gp91-phox and p22-phox. Analysis of mRNA demonstrated reduced gp91-phox transcripts, with relative preservation of an alternative mRNA species created by transcription initiation in the third exon of the gene. Single strand conformation polymorphism analysis of the 5' flanking region of the patients' gp91-phox genes revealed an electrophoretic abnormality not detected in 40 other gp91-phox genes. Genomic sequencing demonstrated a single base change associated with CGD in each kindred: in one, adenine to cytosine at base pair-57 and in the other, thymidine to cytosine at -55. These mutations are located between the "CCAAT" and "TATA" box consensus sequences involved in eukaryotic gene transcription. Gel shift assays revealed two specific DNA-protein complexes formed between phagocyte nuclear extracts and an oligonucleotide probe representing bases -31 to -68 of the gp91-phox promoter region; the faster-migrating complex could not be formed with oligonucleotides containing either of the promoter mutations. Thus, these promoter region mutations appear to be causally related to the loss of association of a DNA-binding protein and lead to diminished gp91-phox expression, abnormal transcription initiation, and the development of CGD.

NADPH-oxidase expression and in situ production of superoxide by osteoclasts actively resorbing bone

Recent reports have suggested that production of superoxide or other reactive oxygen species by activated osteoclasts may play a role in the complex process of bone resorption; however, the enzyme responsible for production of superoxide by osteoclasts has not been characterized. To determine if osteoclasts express NADPH-oxidase, a superoxide-generating enzyme found in phagocytic leukocytes, immunohistochemical studies were performed on tibia from 1-5-d-old rats using mAbs 449 and 48 and an antiserum specific for p47-phox. These antibodies recognize epitopes on the alpha and beta subunits of cytochrome b558, respectively, and the p47 cytosolic component of NADPH-oxidase. We found that osteoclasts attached to bone surfaces in tibia expressed all three components, as did mature polymorphonuclear and some mononuclear leukocytes in the bone marrow. In many adherent osteoclasts, the cytochrome b558 subunits were localized to the ruffled-border and bone interfaces. Studies were also performed on mature rat tibia that had undergone controlled fracture. By two weeks the healing fractures develop a callus rich in actively resorbing osteoclasts. Osteoclasts within the calluses, and attached to bone surface, also expressed the cytochrome b558 proteins. In addition to demonstrating the expression of NADPH-oxidase, the active production of superoxide by osteoclasts was also demonstrated in situ in freshly isolated tibia using 3,3'-diaminobenzidine (DAB)-Mn2+, a histochemical method specific for superoxide localization. Osteoclasts attached to bone surfaces contained deposits of oxidized DAB which were observed by light microscopy. Nonstimulated polymorphonuclear and mononuclear leukocytes in the bone marrow did not contain DAB deposits unless stimulated with phorbol myristate acetate, a known activator of NADPH-oxidase. These findings indicate that osteoclasts contain NADPH-oxidase, and during the process of resorbing bone, are actively producing superoxide.

Mechanisms for the activation/electron transfer of neutrophil NADPH-oxidase complex and molecular pathology of chronic granulomatous disease

Professional phagocytes, neutrophils, possess a unique membrane-associated NADPH-oxidase system, dormant in resting cells, which becomes activated upon exposure to the appropriate stimuli and catalyzes the one-electron reduction of molecular oxygen to superoxide, O2-. Oxidase activation involves the assembly, in the plasma membrane, of membrane-bound and cytosolic constituents of the oxidase system, which are disassembled in the resting state. The oxidase system consists of two plasma membrane-bound components; low-potential cytochrome b558, which is composed of two subunits of 22-kDa, and 91-kDa, and a possible flavoprotein related to the electron transport between NADPH and cytochrome b558. Recent reports have indicated that FAD-binding sites of the oxidase are contained in cytochrome b558. At least two cytosolic components, 67-kDa protein and a phosphorylated 47-kDa protein, are known to translocate to the plasma membrane, ensuring assembly of an active O2(-)-generating NADPH-oxidase system. It is the purpose of this review to focus on recent data concerning electron transfer mechanisms of the activated neutrophil NADPH-oxidase complex and molecular pathology of chronic granulomatous disease.

Activation factors of neutrophil NADPH oxidase complex

Professional phagocytes, neutrophils, possess a unique membrane-associated NADPH oxidase system, dormant in resting cells, which becomes activated upon exposure to the appropriate stimuli and catalyzes the one-electron reduction of molecular oxygen to superoxide, O2-. Oxidase activation involves the assembly, in the plasma membrane, of membrane-bound and cytosolic constituents of the oxidase system, which are disassembled in the resting state. The oxidase system consists of two plasma membrane-bound components; low-potential cytochrome b558, which is composed of two subunits of 22 kDa and 91 kDa, and a flavoprotein related to the electron transport between NADPH and heme-binding domains of the oxidase. Recent reports have indicated that FAD-binding sites of the oxidase are contained in cytochrome b558 (flavocytochrome b558). At least two cytosolic components, 67 kDa protein and a phosphorylated 47 kDa protein, are known to translocate to the plasma membrane, ensuring assembly of an active O2(-)-generating NADPH oxidase system. More recently, the membrane (Raps) and cytosolic (Racs) GTP-binding proteins have been established as essential to oxidase assembly. It is the purpose of this review to focus on recent data concerning the regulatory mechanisms which lead to organization and activation of the neutrophil NADPH oxidase system.

Gene targeting of X chromosome-linked chronic granulomatous disease locus in a human myeloid leukemia cell line and rescue by expression of recombinant gp91phox

The X chromosome-linked chronic granulomatous disease (X-CGD) locus, which encodes the gp91phox subunit of the phagocyte respiratory-burst oxidase cytochrome b, was disrupted by homologous recombination in the PLB-985 human myeloid cell line to develop an in vitro model of X-CGD. Superoxide formation was absent in targeted cells after differentiation to granulocytes but was rescued by stable transfection and expression of wild-type gp91phox cDNA. The targeted cell line should be useful in experiments aimed at defining functional regions within gp91phox by expression of mutant gp91phox cDNAs, complementing studies of naturally occurring mutations in X-CGD. In addition, the mutant line provides a model system in which to establish an experimental basis for the treatment of X-CGD patients with gene replacement therapy. Rescued clones containing even modest amounts of recombinant gp91phox had respiratory-burst activity comparable to the wild-type PLB-985 line, suggesting that functional correction of X-CGD neutrophils may not require high-level expression of gp91phox.

A structural model for the nucleotide binding domains of the flavocytochrome b-245 beta-chain

NADPH is a system in phagocytic cells that generates O2- and hydrogen peroxide in the endocytic vacuole, both of which are important for killing of the engulfed microbe. Dysfunction of this oxidase results in the syndrome of chronic granulomatous disease, characterized by a profound predisposition to bacterial and fungal infections. A flavocytochrome b is the site of most of the mutations causing this syndrome. The FAD and NADPH binding sites have been located on the beta subunit of this molecule, the C-terminal half of which showed weak sequence similarity to other reductases, including the ferredoxin-NADP reductase (FNR) of known structure. This enabled us to build a model of the nucleotide binding domains of the flavocytochrome using this structure as a template. The model was built initially using a novel automatic modeling method based on distance-matrix projection and then refined using energy minimization with appropriate side-chain torsional constraints. The resulting model rationalized much of the observed sequence conservation and identified a large insertion as a potential regulatory domain. It confirms the inclusion of the neutrophil flavocytochrome b-245 (Cb-245) as a member of the FNR family of reductases and strongly supports its function as the proximal electron transporting component of the NADPH oxidase.