Mapping of functional domains in the p22(phox) subunit of flavocytochrome b(559) participating in the assembly of the NADPH oxidase complex by "peptide walking".

The superoxide-generating NADPH oxidase complex of phagocytes consists of a membranal heterodimeric flavocytochrome (cytochrome b(559)), composed of gp91(phox) and p22(phox) subunits, and four cytosolic proteins, p47(phox), p67(phox), p40(phox), and the small GTPase Rac (1 or 2). All redox stations involved in electron transport from NADPH to oxygen are located in gp91(phox). NADPH oxidase activation is the consequence of assembly of cytochrome b(559) with cytosolic proteins, a process reproducible in a cell-free system, consisting of phagocyte membranes, and recombinant cytosolic components, activated by an anionic amphiphile. p22(phox) is believed to act as a linker between the cytosolic components and gp91(phox). We applied "peptide walking" to mapping of domains in p22(phox) participating in NADPH oxidase assembly. Ninety one synthetic overlapping pentadecapeptides, spanning the p22(phox) sequence, were tested for the ability to inhibit NADPH oxidase activation in the cell-free system and to bind individual cytosolic NADPH oxidase components. We conclude the following. 1) The p22(phox) subunit of cytochrome b(559) serves as an anchor for both p47(phox) and p67(phox). 2) p47(phox) binds not only to the proline-rich region, located at residues 151-160 in the cytosolic C terminus of p22(phox), but also to a domain (residues 51-63) located on a loop exposed to the cytosol. 3) p67(phox) shares with p47(phox) the ability to bind to the proline-rich region (residues 151-160) and also binds to two additional domains, in the cytosolic loop (residues 81-91) and at the start of the cytosolic tail (residues 111-115). 4) The binding affinity of p67(phox) for p22(phox) peptides is lower than that of p47(phox). 5) Binding of both p47(phox) and p67(phox) to proline-rich p22(phox) peptides occurs in the absence of an anionic amphiphile. A revised membrane topology model of p22(phox) is proposed, the core of which is the presence of a functionally important cytosolic loop (residues 51-91).     

Functional epitope on human neutrophil flavocytochrome b558

mAb NL7 was raised against purified flavocytochrome b(558), important in host defense and inflammation. NL7 recognized the gp91(phox) flavocytochrome b(558) subunit by immunoblot and bound to permeabilized neutrophils and neutrophil membranes. Epitope mapping by phage display analysis indicated that NL7 binds the (498)EKDVITGLK(506) region of gp91(phox). In a cell-free assay, NL7 inhibited in vitro activation of the NADPH oxidase in a concentration-dependent manner, and had marginal effects on the oxidase substrate Michaelis constant (K(m)). mAb NL7 did not inhibit translocation of p47(phox), p67(phox), or Rac to the plasma membrane, and bound its epitope on gp91(phox) independently of cytosolic factor translocation. However, after assembly of the NADPH oxidase complex, mAb NL7 bound the epitope but did not inhibit the generation of superoxide. Three-dimensional modeling of the C-terminal domain of gp91(phox) on a corn nitrate reductase template suggests close proximity of the NL7 epitope to the proposed NADPH binding site, but significant separation from the proposed p47(phox) binding sites. We conclude that the (498)EKDVITGLK(506) segment resides on the cytosolic surface of gp91(phox) and represents a region important for oxidase function, but not substrate or cytosolic component binding.     

Deletion mutagenesis of p22phox subunit of flavocytochrome b558: identification of regions critical for gp91phox maturation and NADPH oxidase activity

The heterodimeric flavocytochrome b558, comprised of the two integral membrane proteins p22phox and gp91phox, mediates the transfer of electrons from NADPH to molecular oxygen in the phagocyte NADPH oxidase to generate the superoxide precursor of microbicidal oxidants. This study uses deletion mutagenesis to identify regions of p22phox required for maturation of gp91phox and for NADPH oxidase activity. N-terminal, C-terminal, or internal deletions of human p22phox were generated and expressed in Chinese hamster ovary cells with transgenes for gp91phox and two other NADPH oxidase subunits, p47phox, and p67phox. The results demonstrate that p22phox-dependent maturation of gp91phox carbohydrate, cell surface expression of gp91phox, and the enzymatic function of flavocytochrome b558 are closely correlated. Whereas the 5 N-terminal and 25 C-terminal amino acids are dispensable for these functions, the N-terminal 11 amino acids of p22phox are required, as is a hydrophilic region between amino acids 65 and 90. Upon deletion of 54 residues at the C terminus of p22phox (amino acids 142-195), maturation and cell surface expression of gp91phox was still preserved, although NADPH oxidase activity was absent, as expected, due to removal of a proline-rich domain between amino acids 151-160 that is required for recruitment of p47phox. Antibody binding studies indicate that the extreme N terminus of p22phox is inaccessible in the absence of cell permeabilization, supporting a model in which both the N- and C-terminal domains of p22phox extend into the cytoplasm, anchored by two membrane-embedded regions.     

Characterization of the flavoprotein domain of gp91phox which has NADPH diaphorase activity

A series of truncated forms of gp91phox were expressed in Escherichia coli in which the N-terminal hydrophobic transmembrane region was replaced with a portion of the highly soluble bacterial protein thioredoxin. TRX-gp91phox (306-569), which contains the putative FAD and NADPH binding sites, showed weak NADPH-dependent NBT (nitroblue tetrazolium) reductase activity, whereas TRX-gp91phox (304-423) and TRX-gp91phox (424-569) were inactive. Activity saturated at about a 1:1 molar ratio of FAD to TRX-gp91phox (306-569), and showed the same K(m) for NADPH as that for superoxide generating activity by the intact enzyme. Activity was not inhibited by superoxide dismutase, indicating that it was not mediated by superoxide, but was blocked by an inhibitor of the respiratory burst oxidase, diphenylene iodonium. In the presence of Rac1, the cytosolic regulatory protein p67phox stimulated the NBT reductase activity, but p47phox had no effect. Truncated p67phox containing the activation domain (residues 199-210) [C.-H. Han, J.R. Freeman, T. Lee, S.A. Motalebi, and J.D. Lambeth (1998) J. Biol. Chem. 273, 16663-16668] stimulated activity approximately 2-fold, whereas forms mutated or lacking this region failed to stimulate the activity. Our data indicate that: (i) TRX-gp91phox (306-569) contains binding sites for both pyridine and flavin nucleotides; (ii) this flavoprotein domain shows weak diaphorase activity; and (iii) the flavin-binding domain of gp91phox is the target of regulation by the activation domain of p67phox.     

Rotenone activates phagocyte NADPH oxidase by binding to its membrane subunit gp91phox

Rotenone, a widely used pesticide, reproduces parkinsonism in rodents and associates with increased risk for Parkinson disease. We previously reported that rotenone increased superoxide production by stimulating the microglial phagocyte NADPH oxidase (PHOX). This study identified a novel mechanism by which rotenone activates PHOX. Ligand-binding assay revealed that rotenone directly bound to membrane gp91(phox), the catalytic subunit of PHOX; such binding was inhibited by diphenyleneiodonium, a PHOX inhibitor with a binding site on gp91(phox). Functional studies showed that both membrane and cytosolic subunits were required for rotenone-induced superoxide production in cell-free systems, intact phagocytes, and COS7 cells transfected with membrane subunits (gp91(phox)/p22(phox)) and cytosolic subunits (p67(phox) and p47(phox)). Rotenone-elicited extracellular superoxide release in p47(phox)-deficient macrophages suggested that rotenone enabled activation of PHOX through a p47(phox)-independent mechanism. Increased membrane translocation of p67(phox), elevated binding of p67(phox) to rotenone-treated membrane fractions, and coimmunoprecipitation of p67(phox) and gp91(phox) in rotenone-treated wild-type and p47(phox)-deficient macrophages indicated that p67(phox) played a critical role in rotenone-induced PHOX activation via its direct interaction with gp91(phox). Rac1, a Rho-like small GTPase, enhanced p67(phox)-gp91(phox) interaction; Rac1 inhibition decreased rotenone-elicited superoxide release. In conclusion, rotenone directly interacted with gp91(phox); such an interaction triggered membrane translocation of p67(phox), leading to PHOX activation and superoxide production.     

翘嘴鳜NADPH氧化酶2个催化亚基cDNA的克隆和表达特征

吞噬细胞NADPH氧化酶能生成用于清除病原微生物的活性氧(reactive oxygen species, ROS),在机体的防御体系中起着非常重要的作用.本文利用RT-PCR结合RACE-PCR的方法,克隆到翘嘴鳜NADPH氧化酶的催化亚基gp91phox和p22phox的cDNA全长.并研究两者在正常的翘嘴鳜和注射了柱状黄杆菌灭活菌苗（FKG4）的翘嘴鳜组织中的表达模式.结果表明,gp91phox基因cDNA序列全长2 037 nt,开放阅读框长度为1 698 nt,翻译成565个氨基酸;p22phox 基因cDNA序列全长1 296 nt,开放阅读框561 nt,翻译成186个氨基酸.将这2个亚基推导的氨基酸序列与人的对应亚基相比,相似性分别为68.7%和60.8%,且具有相似的结构域和功能域,说明翘嘴鳜与人的NADPH氧化酶具有相似的功能活性.半定量PCR分析显示,在翘嘴鳜血液、脑、心脏、肾、肝、脾、胸腺等11种组织中均能检测到gp91phox和p22phox的基因表达.经FKG4免疫后,gp91phox在翘嘴鳜血液、头肾和脾3种组织中的表达量显著上升,p22phox在头肾和脾2种组织中的表达量显著上升.由此推断,NADPH氧化酶可能参与了机体的抗菌免疫应答.     

Mutagenesis of an arginine- and lysine-rich domain in the gp91(phox) subunit of the phagocyte NADPH-oxidase flavocytochrome b558

Site-directed mutagenesis was used to generate a series of mutants harboring point or multiple substitutions within the hydrophilic, polybasic domain of gp91(phox) encompassed by residues 86-102, which was previously identified as a site of interaction with p47(phox) during phagocyte NADPH oxidase assembly. Recombinant wild-type or mutant gp91(phox) was expressed in a human myeloid leukemia cell line in which the endogenous gp91(phox) gene was disrupted by gene targeting. NADPH oxidase activity was measured in a cytochrome c reduction assay following granulocytic differentiation of cells that expressed recombinant gp91(phox). Expression of a gp91(phox) mutant in which amino acids 89-97 were replaced with nine alternate amino acids abolished NADPH oxidase activity. Expression of gp91(phox) mutants R89T, D95A, D95R, R96A, R96E, or K102T did not significantly affect NADPH oxidase activity. However, mutations of individual or paired arginine residues at positions 91 and 92 had substantial effects on superoxide generation. The R91E/R92E mutation completely abolished both NADPH oxidase activity and membrane-translocation of the cytosolic oxidase proteins p47(phox), p67(phox), Rac1, and Rac2. The phorbol 12-myristate 13-acetate-induced rate of superoxide production was reduced by approximately 75% in cells expressing R91T/R92A, R91E, or R92E gp91(phox) along with an increased lag time to the maximal rates of superoxide production relative to cells expressing wild-type gp91(phox). Taken together, these results demonstrate that Arg91 and Arg92 of gp91(phox) are essential for flavocytochrome b558 function in granulocytes and suggest that these residues participate in the interaction of gp91(phox) with the cytosolic oxidase proteins.     

Nox3 regulation by NOXO1, p47phox, and p67phox

gp91(phox) (Nox2), the catalytic subunit of the superoxide-generating respiratory burst oxidase, is regulated by subunits p47(phox) and p67(phox). Nox1, a homolog of gp91(phox), is regulated by NOXO1 and NOXA1, homologs of p47(phox) and p67(phox), respectively. For both Nox1 and gp91(phox), an organizer protein (NOXO1 or p47(phox)) cooperates with an activator protein (NOXA1 or p67(phox)) to regulate the catalytic subunit. Herein, we investigate the subunit regulation of Nox3 compared with that of other Nox enzymes. Nox3, like gp91(phox), was activated by p47(phox) plus p67(phox). Whereas gp91(phox) activity required the protein kinase C activator phorbol myristate acetate (PMA), Nox3 activity was already high without PMA, but was further stimulated approximately 30% by PMA. gp91(phox) was also activated by NOXO1/NOXA1 and required PMA for high activity. gp91(phox) regulation required an intact activation domain in the activator protein, as neither p67(phox)(V204A) nor NOXA1(V205A) were effective. In contrast, p67(phox)(V204A) was effective (along with p47(phox)) in activating Nox3. Unexpectedly, Nox3 was strongly activated by NOXO1 in the absence of NOXA1 or p67(phox). Nox3 activity was regulated by PMA only when p47(phox) but not NOXO1 was present, consistent with the phosphorylation-regulated autoinhibitory region in p47(phox) but not in NOXO1. Deletion of the autoinhibitory region from p47(phox) rendered this subunit highly active in the absence of PMA toward both gp91(phox) and Nox3, and high activity required an activator subunit. The unique regulation of Nox3 supports a model in which multiple interactions with regulatory subunits stabilize an active conformation of the catalytic subunit.     

Heme-ligating histidines in flavocytochrome b(558): identification of specific histidines in gp91(phox).

The phagocyte NADPH-dependent oxidase generates superoxide (O(2)) by reducing molecular oxygen through flavocytochrome b(558) (flavocytochrome b), a heterodimeric oxidoreductase composed of gp91(phox) and p22(phox) subunits. Although each flavocytochrome b molecule contains two heme groups, their precise distribution within the heterodimer is unknown. Among functionally and/or structurally related oxidoreductases, histidines at codons 101, 111, 115, 119, 209, 210, and 222 of gp91(phox) are conserved and potential candidates to ligate heme. We compared biochemical and functional features of normal flavocytochrome b with those in cells expressing gp91(phox) harboring amino acid substitutions at each of these histidines. Surface expression of flavocytochrome b and heterodimer formation were relatively unaffected in cells expressing gp91(phox) H111L, H119L, or H210L. These mutations also had no effect on the flavocytochrome b heme spectrum, although NADPH oxidase activity was decreased in cells expressing gp91(phox) H119L or H210L. In contrast, gp65 was not processed to gp91(phox), heterodimers did not form, and flavocytochrome b was not expressed on the surface of cells expressing gp91(phox) H101L, H115L, H115D, H209C, H209Y, H222L, H222C, or H222R. Similarly, this subset of mutants lacked detectable O(2)-generating activity, and flavocytochrome b purified from these cells contained little or no heme. These findings demonstrate that His(101), His(115), His(209), and His(222) of gp91(phox) are critical for heme binding and biosynthetic maturation of flavocytochrome b.     

PU.1 is dominant and HAF-1 supplementary for activation of the gp91(phox) promoter in human monocytic PLB-985 cells

Gp91(phox) is a key component of the phagocyte NADPH oxidase. Mutations of its promoter found in patients with chronic granulomatous disease cause deficient binding of PU.1 and HAF-1. Because the two factors bind to the same site (Pu box) of the promoter, we attempted to clarify their relative in vivo contributions to activation of the gp91(phox) promoter in monocytically differentiated PLB-985 cells using a dual luciferase reporter assay and a gel shift competition assay. We found that the activity of a series of single-point-mutated promoters increases or decreases according to an increase or decrease, respectively, in the affinity of the promoters to PU.1 but not to HAF-1. Two of 7 mutants showing weak binding affinity to PU.1 exhibited moderate promoter activity and normal binding affinity for HAF-1. These results suggest PU.1 is the dominant activator and HAF-1 is supplementary. The increased promoter activity of single-, double-, and triple-point-mutated constructs with sequences closer to that of the Ets-binding element correlates with their binding affinity to PU.1 but not to HAF-1, supporting that PU.1 is a more efficient activator than HAF-1. In contrast to co-expressed wild-type PU.1, dominant-negative PU.1 significantly inhibited the activity of a PU.1-optimised gp91(phox) promoter construct. Therefore, we conclude that PU.1 and HAF-1 binding to the Pu box is dominant and supplementary, respectively, for activation of the gp91(phox) promoter in human monocytic cells.     

The X+ chronic granulomatous disease as a fabulous model to study the NADPH oxidase complex activation

Chronic granulomatous disease (CGD) is a rare inherited disorder in which phagocytes lack NADPH oxidase activity. Patients with CGD suffer from recurrent bacterial and fungal infections because of the absence of superoxide anions (O2- degrees ) generatingsystem. The NADPH oxidase complex is composed of a membranous cytochrome b558, cytosolic proteins p67phox, p47phox, p40phox and two small GTPases Rac2 and Rap1A. Cytochrome b558 consists of two sub-units gp91phox and p22phox. The most common form of CGD is due to mutations in CYBB gene encoding gp91phox. In some rare cases, the mutated gp91phox is normally expressed but is devoided of oxidase activity. These variants called X+ CGD, have provided interesting informations about oxidase activation mechanisms. However modelization of such variants is necessary to obtain enough biological material for studies at the molecular level. A cellular model (knock-out PLB-985 cells) has been developed for expressing recombinant mutated gp91phox for functional analysis of the oxidase complex. Recent works demonstrated that this cell line genetically deficient in gp91phox is a powerful tool for functional analysis of the NADPH oxidase complex activation.