Cytosolic Oxidase Components P47phox Research Articles

Conformational changes in truncated p47phox proteins monitored by fluorescent labeling.

The leukocyte NADPH oxidase of neutrophils is a membrane-bound enzyme that catalyzes the reduction of oxygen to O2- at the expense of NADPH. During activation, the cytosolic oxidase components p47phox and p67phox, each containing two Src homology 3 (SH3) domains, migrate to the plasma membrane. p47phox and p67phox associate with cytochrome b558, a membrane-integrated flavohemoprotein, to assemble the active oxidase. Oxidase activation can be mimicked in a cell-free system using an anionic amphiphile, such as sodium dodecyl sulfate or arachidonic acid, as an activating agent. Activators of the oxidase in vitro cause exposure of the SH3 domains of p47phox, which has probably been masked by the C-terminal region of this protein in a resting state. We show here that the fluorescence exhibited by the covalently labeled N,N'-di-methyl-N(iodoacetyl)-N'-(7-nitrobenz-2-oxa-1,3-diazol-4-yl) ethyleneamine (IANBD) was increased when N-terminal-truncated p47Phox-(SH3)2-C was treated with anionic amphiphiles. This finding was similar to the results obtained with the full-length p47phox. However, the fluorescence of C-terminal-truncated p47Phox-N-(SH3)2 and that of both C-terminal and N-terminal truncated p47Phox-(SH3)2 were not altered by the activators. These results indicate that the C-terminal region of p47phox is a primary target of the conformational change during the activation of NADPH oxidase.

C-terminal region of the cytosolic subunit p47 phox is a primary target of conformational change during the activation of leukocyte NADPH oxidase

The leukocyte NADPH oxidase of neutrophils is a membrane-bound enzyme that catalyzes the production of O 2 – from oxygen using NADPH as the electron donor. During activation, the cytosolic oxidase components p47 phox and p67 phox, each containing two Src homology 3 (SH3) domains, migrate to the plasma membrane, where they associate with cytochrome b 558, a membrane-integrated flavohemoprotein, to assemble the active oxidase. Oxidase activation can be mimicked in a cell-free system using an anionic amphiphile, such as sodium dodecyl sulfate or arachidonic acid and the phosphorylation of p47 phox with protein kinase C. Activators of the oxidase in vitro cause exposure of p47 phox-SH3, which has probably been masked by the C-terminal region of this protein in a resting state. We show here that the total protein steady-state intrinsic fluorescence exhibited by the tryptophan residues of p47 phox substantially decreased when N-terminal truncated p47 phox-SH3-C was treated with anionic amphiphiles or phosphorylated with protein kinase C. This finding was similar to the results obtained with full-length p47 phox. However, the fluorescence of C-terminal truncated p47 phox-N-SH3 and both C-terminal and N-terminal truncated p47 phox-SH3 were not altered by the activators. These results indicate that the C-terminal region of p47 phox is a primary target of the conformational change during the activation of NADPH oxidase.

Conformational changes of the leukocyte NADPH oxidase subunit p47 phox during activation studied through its intrinsic fluorescence

The leukocyte NADPH oxidase of neutrophils is a membrane-bound enzyme that catalyzes the production of O − 2 from oxygen using NADPH as the electron donor. Dormant in resting neutrophils, the enzyme acquires catalytic activity when the cells are exposed to appropriate stimuli. During activation, the cytosolic oxidase components p47 phox and p67 phox migrate to the plasma membrane, where they associate with cytochrome b 558, a membrane-integrated flavohemoprotein, to assemble the active oxidase. Oxidase activation can be mimicked in a cell-free system using an anionic amphiphile, such as sodium dodecyl sulfate or arachidonic acid, as an activating agent. In whole cells and under certain circumstances in the cell-free system the phosphorylation of p47 phox mediates the activation process. It has been proposed that conformational changes in the protein structure of cytosolic factor p47 phox may be an important part of the activation mechanism. We show here that the total protein steady-state intrinsic fluorescence (an emission maximum of 338 nm) exhibited by the tryptophan residues of p47 phox substantially decreased when p47 phox was treated with anionic amphiphiles. A similar decrease in fluorescence was also observed when p47 phox was phosphorylated with protein kinase C. Furthermore, a red shift of emission maximum and an increase of quenching by ionic quenchers and acrylamide were observed in the presence of activators. These results indicate the occurrence of a conformational change in the protein structure of p47 phox. We propose that this alteration in conformation results in the appearance of a binding site through which p47 phox interacts with cytochrome b 558 during the activation process.

Activation of the leukocyte NADPH oxidase subunit p47phox by protein kinase C. A phosphorylation-dependent change in the conformation of the C-terminal end of p47phox.

The leukocyte NADPH oxidase of neutrophils is a membrane-bound enzyme that catalyzes the production of O2- from oxygen using NADPH as electron donor. Dormant in resting neutrophils, the enzyme acquires catalytic activity when the cells are exposed to appropriate stimuli. During activation, the cytosolic oxidase components p47phox and p67phox migrate to the plasma membrane, where they associate with cytochrome b558, a membrane-bound flavohemoprotein, to assemble the active oxidase. An essential element of the activation process is the phosphorylation of p47phox, an event that accompanies oxidase activation in whole cells and can activate the oxidase in a cell-free system. We show here that the phosphorylation of p47phox leads to a substantial decrease in the reactivity of cysteine C378 toward N-ethylmaleimide, indicating the occurrence of a conformational change involving the C-terminal region of p47phox. A similar conformational change occurs when p47phox is exposed to arachidonate, one of a number of anionic detergents that activate the oxidase in the cell-free system. We propose that this change in conformation results in the appearance of a binding site through which p47phox interacts with cytochrome b558 during the activation process.

A rise in ionized calcium activates the neutrophil NADPH-oxidase but is not sufficient to directly translocate cytosolic p47phox or p67phox to b cytochrome containing membranes.

Neutrophil production of reactive oxygen species is dependent on an assembly process that involves a translocation of the cytosolic NADPH-oxidase components (p47phox; p67phox; Rac2) to a b cytochrome containing membrane. Based on the fact that an intracellular Ca2+ rise can activate the oxidase without any extracellular release of reactive oxygen species, we suggest that the oxidase can be assembled in a membrane distinct from the plasma membrane. Disintegrated cells were used to monitor Ca2+ dependent membrane binding of neutrophil cytosolic proteins. Membranes containing the b cytochrome part of the oxidase, i.e., specific granules and plasma membranes/secretory vesicles, were used in the translocation experiments. Several cytosolic proteins were found to translocate to specific granules as well as the plasma membranes/secretory vesicles, one of them being annexin I. Using antibodies in the blotting assay against the cytosolic oxidase components p47phox and p67phox, we could show that no Ca2+ dependent translocation of these cytosolic proteins occur to neither of the b cytochrome containing membranes.

Activation of signaling pathways in HL60 cells and human neutrophils by farnesylthiosalicylate.

Effects of the farnesylcysteine mimetic, farnesylthiosalicylate on the activation of myeloid cells were studied. In dimethyl-sulfoxide-differentiated HL60 cells and in human neutrophils farnesylthiosalicylate (< or = 20 microM) dose-dependently elevated cytosolic Ca2+ concentrations, suggesting phospholipase-C-mediated release of the ion from intracellular stores. In human neutrophils, in addition to the production of inositol trisphosphate, farnesylthiosalicylate induced activation of the NADPH oxidase and translocation of the cytosolic oxidase components p47-phox and p67-phox to the membrane. The calcium signal, inositol-trisphosphate production and superoxide generation elicited by farnesylthiosalicylate were partially blocked by treatment of the cells with pertussis toxin, consistent with participation of pertussis-toxin-sensitive and pertussis-toxin-resistant elements. In HL60 cells, farnesylthiosalicylate (< or = 20 microM) did not activate NADPH oxidase but dose-dependently augmented PMA-elicited activity of the enzyme. This effect was resistant to pertussis-toxin treatment. In vitro augmentation of PKC-mediated phosphorylation of histone and cytosolic p47-phox by farnesylthiosalicylate and the finding that downregulation of PKC abrogated potentiation of NADPH oxidase activity by farnesylthiosalicylate were compatible with the involvement of PKC in the response of HL60 cells to farnesylthiosalicylate. It is suggested that the effects of farnesylthiosalicylate on myeloid cells reflect interaction of the analog with prenylcysteine-docking sites on cellular signaling elements.

Characteristics of the inhibition of NADPH oxidase activation in neutrophils by apocynin, a methoxy-substituted catechol.

Phagocytes are able to generate reactive oxygen species by an activatable NADPH oxidase system. We investigated the inhibition of NADPH oxidase activation by a methoxy-substituted catechol, apocynin. Oxygen uptake by neutrophils incubated with 300 microM apocynin was completely inhibited at 7 min after addition of serum-treated zymosan (STZ), with a lagtime of inhibition of 2 to 3 min. The lagtime of effect of apocynin in neutrophils relatively deficient of myeloperoxidase was about 50% longer when compared with normal cells. Inhibition of the STZ-induced respiratory burst by apocynin was also observed in human eosinophils but not in human alveolar macrophages. Immunoblots of neutrophil membranes, isolated at 2 and 7 min after STZ stimulation of neutrophils, demonstrated translocation of the cytosolic oxidase components p47-phox and p67-phox to the membrane fraction. Translocation at 7 min after STZ stimulation was markedly reduced when the neutrophils had been incubated with 300 microM apocynin, but translocation was normal after 2 min of stimulation. These properties suggest that apocynin is an intracellular inhibitor of the assembly of NADPH oxidase in neutrophils and eosinophils and that apocynin requires conversion by peroxidases to exert its inhibitory effect. The capacity of neutrophils for intracellular killing of Staphylococcus aureus was not affected by apocynin. The potential therapeutic value of apocynin was demonstrated in vitro by its ability to protect secretory leukocyte proteinase inhibitor from oxidative inactivation by neutrophils.

Cytosolic guanine nucleotide-binding protein Rac2 operates in vivo as a component of the neutrophil respiratory burst oxidase. Transfer of Rac2 and the cytosolic oxidase components p47phox and p67phox to the submembranous actin cytoskeleton during oxidase activation.

The respiratory burst oxidase is responsible for O2- production in stimulated neutrophils and B lymphocytes. Components of this oxidase include cytochrome b558, a membrane-bound flavohemoprotein; the cytosolic polypeptides p47phox and p67phox; and one or more small G proteins including Rac1, Rac2, and/or Rap1A. We found that when normal neutrophils were activated, small percentages of each of the cytosolic proteins p47phox, p67phox, and Rac2 were transferred to the membrane cytoskeleton. However, Rac2 was not transferred to the membrane during activation of p47phox-deficient neutrophils. In normal cells, some p47phox also became associated with the non-cytoskeletal portion of the plasma membrane, but p67phox, Rac2, and O(2-)-forming activity were restricted to the cytoskeleton. Neutrophil activation also causes the phosphorylation of multiple serines in p47phox. The most heavily phosphorylated forms of p47phox were found solely in the membrane cytoskeleton. These results suggest that 1) the membrane cytoskeleton participates in respiratory burst oxidase activation, 2) the fully phosphorylated p47phox is located in the active oxidase, which resides in the membrane cytoskeleton, and 3) Rac2 acts like a dedicated component of the respiratory burst oxidase.

Inhibition of neutrophil NADPH oxidase assembly by a myristoylated pseudosubstrate of protein kinase C.

To further define the role played by protein kinase C (PKC) in the activation of the neutrophil NADPH oxidase, we have utilized a pseudosubstrate of PKC which was myristoylated at the N terminus. In electropermeabilized neutrophils, the myristoylated pseudosubstrate Phe-Ala-Arg-Lys-Gly-Ala-Leu-Arg-Gln (myr-psi PKC) inhibited PMA-induced protein phosphorylations and activation of the NADPH oxidase, induced either by PMA or by the receptor agonist formyl-methionyl-leucyl-phenylalanine. Both the pseudosubstrate lacking the N-terminal myristate (psi PKC) and a myristoylated control peptide (Phe-Ala-Glu-Asp-Gly-Ala-Leu-Glu-Gln, myr-CP) were without effect on these responses. The myristoylated pseudosubstrate was also tested in a cell-free system, in which NADPH oxidase activation can be achieved by addition of SDS and guanosine 5'-3-O-(thio)triphosphate in a staurosporine-insensitive manner. Myr-psi PKC, but not psi PKC or myr-CP, proved to be a potent inhibitor of NADPH oxidase activity in the cell-free system, indicating that the inhibition observed in permeabilized neutrophils may have been caused by an effect other than PKC inhibition. In the presence of myr-psi PKC, translocation in the cell-free system of the cytosolic oxidase components p47-phox and p67-phox to the plasma membrane was inhibited. From these results we conclude that myristoylation profoundly increases the ability of pseudosubstrates of PKC to inhibit not only PKC-mediated phosphorylations, but also NADPH oxidase activation. The latter effect, however, is most probably not related to PKC inhibition but may indicate a critical role of the membrane surface charge in the translocation of the cytosolic oxidase components p47-phox and p67-phox.

The translocation of respiratory burst oxidase components from cytosol to plasma membrane is regulated by guanine nucleotides and diacylglycerol.

The respiratory burst oxidase is a multimeric enzyme responsible for O2- production by stimulated neutrophils and a few other cell types. In the resting neutrophil, the oxidase is dormant, and its subunits are distributed between the cytosol, in which they appear to exist in the form of a multisubunit complex, and the plasma membrane; but, when the neutrophil is activated, the cytosolic complex translocates to the membrane to assemble the active enzyme. Using a cell-free system in which oxidase activity was elicited with SDS, we examined the effects of GTP gamma S and dioctanoylglycerol (DiC8) on both the activation of O2- production and the transfer of the cytosolic oxidase components p47phox and p67phox to the plasma membrane. GTP (added as undialyzed cytosol) and GTP gamma S augmented the transfer of the oxidase components to the plasma membrane and was essential for the acquisition of O2- producing activity by the oxidase. DiC8 also supported the SDS-mediated transfer of oxidase components to the membrane, but O2- production did not take place unless GTP or GTP gamma S was present. In the presence of these nucleotides, however, DiC8 augmented both translocation and O2- production. We interpreted these results in terms of a mechanism in which 2 membrane-binding sites are created during the activation of the cytosolic complex, one for diacylglycerol and the other for a second site on the membrane. Development of the second membrane-binding site depends upon the action of a G protein and is essential for the expression of oxidase activity. The results further suggested that the priming of the respiratory burst oxidase in intact neutrophils might be due to an increase in membrane diacylglycerol concentration that occurs in response to the priming stimulus. Because of the increased diacylglycerol content, a larger than usual amount of active respiratory burst oxidase could be assembled on the primed plasma membrane when the neutrophil is fully activated.