Purification and characterization of Rac 2. A cytosolic GTP-binding protein that regulates human neutrophil NADPH oxidase.

Human neutrophils and other phagocytes generate superoxide anion (O2-) as a means of destroying ingested microorganisms. O2- is produced by an NADPH-consuming oxidase composed of membrane and cytosolic components. Activation of the NADPH oxidase is absolutely dependent upon GTP, indicating the requirement for a GTP-binding protein in this process. We have utilized a five-step chromatographic procedure to isolate a GTP-binding protein from human neutrophil cytosol which can stimulate NADPH oxidase activity in a cell-free assay. Oxidase enhancing activity was shown to coisolate with this GTP-binding component, which was purified to apparent homogeneity. The GTP-binding protein was identified as Rac 2 by immunological reactivity and amino acid sequencing. Thus, Rac 2 appears to be a third cytosolic component required for human neutrophil NADPH oxidase activation. Recombinant Rac 2 was shown to bind guanine nucleotides in a Mg(2+)-dependent fashion. GDP dissociation rates were determined and shown to be regulated by the free Mg2+ concentration. Rac 2 was found to possess the highest rate of intrinsic GTP hydrolysis of any of the characterized members of the Ras superfamily. The biochemical properties of Rac 2 indicate it is likely to be subject to regulatory cofactors in vivo.     

The neutrophil NADPH oxidase.

The NADPH oxidase of phagocytes catalyzes the conversion of oxygen to O2(-). This multicomponent enzyme complex contains five essential protein components, two in the membrane and three in the cytosol. Unassembled and inactive in resting phagocytes, the oxidase becomes active after translocation of cytosolic components to the membrane to assemble a functional oxidase. Multiple factors regulate its assembly and activity, thus serving to maintain this highly reactive system under spatial and temporal control until recruited for antimicrobial or proinflammatory events. The recent identification of homologs of one of the membrane components in nonphagocytic cells will expand understanding of the biological contexts in which this system may function.     

A neutrophil GTP-binding protein that regulates cell free NADPH oxidase activation is located in the cytosolic fraction

The dormant O2(-)-generating oxidase in plasma membranes from unstimulated neutrophils becomes activated in the presence of arachidonate and a multicomponent cytosolic fraction. This process is stimulated by nonhydrolyzable GTP analogues and may involve a pertussis toxin insensitive GTP-binding protein. Our studies were designed to characterize the putative GTP-binding protein, localizing it to either membrane or cytosolic fraction in this system. Exposure of the isolated membrane fraction to guanosine-5'-(3-O-thio)triphosphate (GTP gamma S), with or without arachidonate, had no effect on subsequent NADPH oxidase activation by the cytosolic fraction. Preexposure of the cytosolic fraction to GTP gamma S alone did not enhance activation of the membrane oxidase. However, preexposure of the cytosol to GTP gamma S then arachidonate caused a four-fold enhancement of its ability to activate the membrane oxidase. This enhancement was evident after removal of unbound GTP gamma S and arachidonate, and was not augmented by additional GTP gamma S during membrane activation. A reconstitution assay was developed for cytosolic component(s) responsible for the GTP gamma S effect. Cytosol preincubated with GTP gamma 35S then arachidonate was fractionated by anion exchange chromatography. A single peak of protein-bound GTP gamma 35S was recovered that had reconstitutive activity. Cytosol preincubated with GTP gamma 35S alone was similarly fractionated and the same peak of protein-bound GTP gamma 35S was observed. However, this peak had no reconstitutive activity. We conclude that the GTP-binding protein regulating this cellfree system is located in the cytosolic fraction. The GTP gamma S-liganded form of this protein may be activated or stabilized by arachidonate.     

Phospholipase D-dependent and-independent activation of the neutrophil NADPH oxidase

Stimulation of the respiratory burst of human neutrophils by fMet-Leu-Phe (in the absence of cytochalasin B) is largely unaffected when the activities of protein kinase C and phospholipase D are inhibited. This has been confirmed using three separate assays to measure the respiratory burst. However, whilst these enzymes are not required for the initiation or maximal rate of oxidant generation, they are required to sustain oxidase activity. In contrast, in the presence of cytochalasin B, fMet-Leu-Phe stimulated oxidase activity is much more dependent on phospholipase D activity. It is proposed that (in the absence of cytochalasin B) activation of the NADPH oxidase utilises cytochrome b molecules that are already present on the plasma membrane and activation occurs independently of phospholipase D and protein kinase C. Once these complexes are inactivated, then new cytochrome b molecules must be recruited from sub-cellular stores. This translocation and/or activation of these molecules is phospholipase D dependent. Some support for this model comes from the finding that the translocation of CD11b (which co-localises with cytochrome b) onto the cell surface is phospholipase D dependent.Abbreviations GM-CSF granulocyte-macrophage colony-stimulating factor - fMet-Leu-Phe N-formylmethionyl-leucyl-phenylalanine luminol 5-amino-2,3-dihydro-1,4-phthalazinedione, O₂,-superoxide radical     

Role of Rac GTPase activating proteins in regulation of NADPH oxidase in human neutrophils

Precise spatiotemporal regulation of O₂⁻-generating NADPH oxidases (Nox) is a vital requirement. In the case of Nox1–3, which depend on the small GTPase Rac, acceleration of GTP hydrolysis by GTPase activating protein (GAP) could represent a feasible temporal control mechanism. Our goal was to investigate the molecular interactions between RacGAPs and phagocytic Nox2 in neutrophilic granulocytes. In structural studies we revealed that simultaneous interaction of Rac with its effector protein p67^phox and regulatory protein RacGAP was sterically possible. The effect of RacGAPs was experimentally investigated in a cell-free O₂⁻-generating system consisting of isolated membranes and recombinant p47^phox and p67^phox proteins. Addition of soluble RacGAPs decreased O₂⁻ production and there was no difference in the effect of four RacGAPs previously identified in neutrophils. Depletion of membrane-associated RacGAPs had a selective effect: a decrease in ARHGAP1 or ARHGAP25 level increased O₂⁻ production but a depletion of ARHGAP35 had no effect. Only membrane-localized RacGAPs seem to be able to interact with Rac when it is assembled in the Nox2 complex. Thus, in neutrophils multiple RacGAPs are involved in the control of O₂⁻ production by Nox2, allowing selective regulation via different signaling pathways.     

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

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

Mechanism of NADPH oxidase activation by the Rac/Rho-GDI complex

The low molecular weight GTP binding protein Rac is essential to the activation of the NADPH oxidase complex, involved in pathogen killing during phagocytosis. In resting cells, Rac exists as a heterodimeric complex with Rho GDP dissociation inhibitor (Rho-GDI). Two types of interactions exist between Rac and Rho-GDI: a protein-lipid interaction, implicating the polyisoprene of the GTPase, as well as protein-protein interactions. Using the two-hybrid system, we show that nonprenylated Rac1 interacts very weakly with Rho-GDI, pointing to the predominant role of protein-isoprene interaction in complex formation. In the absence of this strong interaction, we demonstrate that three sites of protein-protein interaction, Arg66(Rac)-Leu67(Rac), His103(Rac), and the C-terminal polybasic region Arg183(Rac)-Lys188(Rac), are involved and cooperate in complex formation. When Rac1 mutants are prenylated by expression in insect cells, they all interact with Rho-GDI. Rho-GDI is able to exert an inhibitory effect on the GDP/GTP exchange reaction except in the complex in which Rac1 has a deletion of the polybasic region (Arg183(Rac)-Lys188(Rac)). This complex is, most likely, held together through protein-lipid interaction only. Although able to function as GTPases, the mutants of Rac1 that failed to interact with Rho-GDI also failed to activate the NADPH oxidase in a cell-free assay after loading with GTP. Mutant Leu119(Rac)Gln could both interact with Rho-GDI and activate the NADPH oxidase. The Rac1/Rho-GDI and Rac1(Leu119Gln)/Rho-GDI complexes, in which the GTPases were bound to GDP, were found to activate the oxidase efficiently. These data suggest that Rho-GDI stabilizes Rac in an active conformation, even in the GDP-bound state, and presents it to its effector, the p67phox component of the NADPH oxidase.     

Activation of human neutrophil NADPH oxidase and lateral mobility of membrane proteins. A study with crosslinkers

Fluorescence photobleaching recovery was employed to investigate the relationship between the activation of neutrophil NADPH oxidase and lateral mobility of membrane proteins. Treatment of neutrophils with the crosslinking reagent disuccinimidyl suberate (DSS) blocked activation of the respiratory burst without affecting the lateral motion of concanavalin A receptors. Neutrophils treated with DSS after prestimulation with concanavalin A generated superoxide in response to another stimulator, phorbol myristate acetate, in spite of the lateral immobilization of concanavalin A receptors. The apparent lack of correlation between the activation of NADPH oxidase and the lateral motion of membrane proteins is discussed.     

Bacillus anthracis toxins inhibit human neutrophil NADPH oxidase activity

Bacillus anthracis, the causative agent of anthrax, is a Gram-positive, spore-forming bacterium. B. anthracis virulence is ascribed mainly to a secreted tripartite AB-type toxin composed of three proteins designated protective Ag (PA), lethal factor, and edema factor. PA assembles with the enzymatic portions of the toxin, the metalloprotease lethal factor, and/or the adenylate cyclase edema factor, to generate lethal toxin (LTx) and edema toxin (ETx), respectively. These toxins enter cells through the interaction of PA with specific cell surface receptors. The anthrax toxins act to suppress innate immune responses and, given the importance of human neutrophils in innate immunity, they are likely relevant targets of the anthrax toxin. We have investigated in detail the effects of B. anthracis toxin on superoxide production by primary human neutrophils. Both LTx and ETx exhibit distinct inhibitory effects on fMLP (and C5a) receptor-mediated superoxide production, but have no effect on PMA nonreceptor-dependent superoxide production. These inhibitory effects cannot be accounted for by induction of neutrophil death, or by changes in stimulatory receptor levels. Analysis of NADPH oxidase regulation using whole cell and cell-free systems suggests that the toxins do not exert direct effects on NADPH oxidase components, but rather act via their respective effects, inhibition of MAPK signaling (LTx), and elevation of intracellular cAMP (ETx), to inhibit upstream signaling components mediating NADPH oxidase assembly and/or activation. Our results demonstrate that anthrax toxins effectively suppress human neutrophil-mediated innate immunity by inhibiting their ability to generate superoxide for bacterial killing.     

Identification of novel GTP-binding proteins in the human neutrophil

We describe here the existence of previously undescribed GTP-binding proteins within the human neutrophil. These proteins specifically bind guanine nucleotides under conditions in which the previously characterized G-proteins are unable to bind. We have partially purified these proteins and present both functional and immunologic data which indicate that they are unrelated to Gn, the major neutrophil pertussis toxin substrate. An additional protein, of apparent molecular mass 22 kDa, may be related to the ras G-protein family. Analysis of the structural and functional characteristics of these novel proteins will promote a better understanding of the process of neutrophil activation.     

Studies on the electron-transfer mechanism of the human neutrophil NADPH oxidase.

A superoxide-generating NADPH oxidase was solubilized from phorbol 12-myristate 13-acetate-activated human neutrophils with a mixture of sodium deoxycholate (0.125%, w/v) and Lubrol-PX (0.125%, v/v). The solubilized preparation contained FAD (577 pmol/mg of protein) and cytochrome b-245 (479 pmol/mg of protein) and produced 11.61 mol of O2-./s per mol of cytochrome b (340 nmol of O2-./min per mg of protein). On addition of NADPH, the cytochrome b-245 was reduced by 7.9% and the FAD by 38% in the aerobic steady state; NADH addition caused little steady-state reduction of cytochrome b and FAD. In this preparation, and several others, the measured rate of O2-. production correlated with the turnover of cytochrome b calculated from the extent of cytochrome b-245 reduction under aerobic conditions. Addition of diphenyleneiodonium abolished the reduction of both the FAD and cytochrome b-245 components and inhibited O2-. production. The haem ligand imidazole inhibited O2-. generation and cytochrome b reduction while permitting FAD reduction. These results support the suggestion that the human neutrophil NADPH oxidase has the electron-transport sequence: NADPH----FAD----cytochrome b-245----O2.     

Sequential phospholipase activation in the stimulation of the neutrophil NADPH oxidase

Abstract Stimulation of human neutrophils with the chemotactic peptide fMet-Leu-Phe results in activation of a rapid, transient burst of oxidant secretion, which reaches a maximal rate by about 1 min after stimulation. This phase of oxidant secretion is then followed by intracellular oxidant production, which is detected by luminol chemiluminescence but not by assays such as cytochrome c reduction or scopoletin oxidation. The rapid phase of oxidant secretion requires increases in intracellular free Ca²⁺ and phospholipase A₂ activity, but not the activities of phospholipase D or D or protein kinase C. In contrast, intracellular oxidant production requires the activities of phospholipase D and protein kinase C. A model is thus proposed suggesting the sequential activation of different phospholipases which activate oxidase molecules on the plasma membrane or else from the membranes of specific granules.     

Bilirubin inhibits the activation of superoxide-producing NADPH oxidase in a neutrophil cell-free system.

We studied the effect of bilirubin on the NADPH-dependent superoxide production induced by sodium dodecyl sulfate in a cell-free system consisting of the membrane and cytosolic fractions of pig neutrophils. Preincubation of the cytosolic fraction with bilirubin before the addition of sodium dodecyl sulfate resulted in the time- and dose-dependent inhibition of the superoxide production while the preincubation of the membrane fraction with the tetrapyrrole did not result in the inhibition. When the pigment was added after the initiation of the reaction, the ongoing production was not affected by the addition. Other tetrapyrroles, such as hemin, protoporphyrin and biliverdin, also inhibited the production. The results indicate that bilirubin inhibits the activation process of the superoxide producing NADPH oxidase by decreasing the potency of the cytosolic fraction and its inhibitory effect seems to be due to the hydrophobic nature of the tetrapyrrole.     

Inositol lipids and phosphatidic acid inhibit cell-free activation of neutrophil NADPH oxidase

The effect of inositol lipids on the SDS-initiated cell-free activation of NADPH oxidase in membranes of human neutrophils was investigated. In a system consisting of low density membranes, cytosol and SDS, low doses of phosphatidylinositol, phosphatidylinositol mono- and biphosphates and phosphatidic acid interfered with activation of the oxidase. The inhibition was relieved by increasing concentrations of the cytosol. Conversely, preincubation of multilamellar phosphoinositide vesicles with cytosol reduced its ability to support activation of the oxidase.     

Kinetics of cell-free activation of neutrophil NADPH oxidase. Effects of neomycin and guanine nucleotides.

The effects of neomycin, fluoride and the non-hydrolysable guanine nucleotide analogue GTP gamma S on the kinetics of cell-free activation of NADPH oxidase in membranes of resting human neutrophils were investigated. Arachidonate-mediated activation of the oxidase followed a first-order reaction course (kobs. = 0.39 min-1 at 26 degrees C). In the presence of NaF during the activation process, activity was enhanced while the activation rate was slightly reduced (kobs. = 0.25 min-1 at 26 degrees C). Neomycin blocked activation (half-maximal effect at 25 microM) without affecting rates of superoxide release by preactivated enzyme in vitro or in vivo. In spite of reduced specific activity neither the first-order rate constant of the activation nor the Km of the oxidase were altered by neomycin. Oxidase activated in the presence of GTP gamma S exhibited increased specific activity and unchanged Km; the course of the reaction deviated from first-order kinetics. Kinetic evidence is presented for two separate activation reactions: a GTP gamma S-independent, basal, first-order process and a GTP gamma S-dependent sigmoid activation process. The results are compatible with the existence in neutrophil membranes of two separate pools of dormant oxidase. An alternative scheme of the formation of two active forms of NADPH oxidase is also presented.     

Hypohalous acid-modified human serum albumin induces neutrophil NADPH oxidase activation,degranulation, and shape change

Halogenated lipids, proteins, and lipoproteins formed in reactions with myeloperoxidase (MPO)-derived hypochlorous acid (HOCl) and hypobromous acid (HOBr) can contribute to the regulation of functional activity of cells and serve as mediators of inflammation. Human serum albumin (HSA) is the major plasma protein target of hypohalous acids. This study was performed to assess the potency of HSA modified by HOCl (HSA–Cl) and HOBr (HSA–Br) to elicit selected neutrophil responses. HSA–Cl/Br were found to induce neutrophil degranulation, generation of reactive oxygen intermediates, shape change, and actin cytoskeleton reorganization. Thus HSA–Cl/Br can initially act as a switch and then as a feeder of the “inflammatory loop” under oxidative stress. In HSA–Cl/Br-treated neutrophils, monoclonal antibodies against CD18, the β subunit of β₂ integrins, reduced the production of superoxide anion radicals and hydrogen peroxide as well as MPO exocytosis, suggesting that CD18 contributed to neutrophil activation. HSA–Cl/Br-induced neutrophil responses were also inhibited by genistein, a broad-specificity tyrosine kinase inhibitor, and wortmannin, a phosphoinositide 3-kinase (PI3K) inhibitor, supporting the notion that activation of both tyrosine kinase and PI3K may play a role in neutrophil activation by HSA modified in MPO-dependent reactions. These results confirm the hypothesis that halogenated molecules formed in vivo via MPO-dependent reactions can be considered as a new class of biologically active substances potentially able to contribute to activation of myeloid cells in sites of inflammation and serve as inflammatory response modulators.     

Low molecular weight GTP-binding proteins in human neutrophil granule membranes

Degranulation of neutrophils involves the differential regulation of the exocytosis of at least two populations of granules. Low molecular weight GTP-binding proteins (LMW-GBPs) have been implicated in the regulation of vesicular traffic in the secretory pathways of several types of cells. In the present study we identify distinct subsets of LMW-GBPs associated with the membranes of neutrophil-specific and azurophilic granules. Ninety-four percent of total [35S]guanosine 5'-(3-O-thio)triphosphate (GTP gamma S) binding activity was equally distributed between the plasma membrane and cytosol with the remaining 6% localized in the granules. In contrast, the cytosol contained only 10% of the total GTPase activity while the specific granules accounted for 13%. [alpha-32P]GTP binding to proteins transferred to nitrocellulose revealed LMW-GBPs in all fractions except the azurophilic granules. The specific granules contained three out of four bands which were found in the plasma membrane; these ranged from 20 to 23 kDa and all were resistant to alkaline extraction. Photoaffinity labeling with [alpha-32P]8-azido-GTP in the presence of micromolar Al3+ identified proteins of 25 and 26 kDa unique to azurophilic granules; these could not be labeled with [alpha-32P]8-azido-ATP and could be extracted by acidic but not alkaline pH. Botulinum C3-mediated [32P]ADP-ribosylation identified proteins of 16, 20, and 24 kDa both in plasma membranes and those of specific granules. An anti-ras monoclonal antibody, 142-24E5, recognized a 20-kDa protein localized to the plasma and specific granule membranes which could not be extracted by alkaline pH, was not a substrate for botulinum C3 ADP-ribosyltransferase, and was translocated from specific granules to plasma membrane after exposure of neutrophils to phorbol myristate acetate. We conclude that neutrophil-specific and azurophilic granules contain distinct subsets of LMW-GBPs which are uniquely situated to regulate the differential exocytosis of these two compartments.     

Participation of Rac GTPase activating proteins in the deactivation of the phagocytic NADPH oxidase

The aim of the present study was to investigate possible mechanisms that could be involved in the deactivation of the assembled, catalytically active NADPH oxidase of phagocytic cells and thereby lead to termination of O(2)(.-) production. Our major findings are the following: (1) Addition of GDP to the active oxidase is able to reduce O(2)(.-) production both in the fully purified and in a semi-recombinant cell-free activation system. (2) p67(phox) inhibits GTP hydrolysis on Rac whereas p47(phox) has no effect on Rac GTPase activity. (3) Soluble regulatory proteins (GTPase activating protein, guanine nucleotide dissociation inhibitor, and the Rac-binding domain of the target protein p21-activated kinase) inhibit activation of the NADPH oxidase but have no effect on electron transfer via the assembled enzyme complex. (4) Membrane-associated GTPase activating proteins (GAPs) have access also to the assembled, catalytically active oxidase. Taken together, we propose that the GTP-bound active form of Rac is required for sustained enzyme activity and that membrane-localized GAPs have a role in the deactivation of NADPH oxidase.     

Characterisation of electron currents generated by the human neutrophil NADPH oxidase

Electron transport by the human neutrophil NADPH oxidase is an important microbicidal weapon for phagocytes. The electron current (I_e) generated by the neutrophil NADPH oxidase is poorly characterised due to the lack of appropriate electrophysiological data. In this study, I fully characterise the neutrophil generated I_e when the NADPH oxidase is activated by NADPH and GTPγS. The neutrophil I_e was markedly voltage-dependent in the entire voltage range in comparison to those electron currents measured after chloride was removed from the external bath solution. The difference in I_e measured in chloride free conditions was not due to a change in the activation kinetics of voltage-gated proton channels. The I_e depolarises the neutrophil plasma membrane at a rate of 2.3 V s⁻¹ and this depolarisation was opposed when voltage-gated proton channels are activated. 3 mM ZnCl₂ depolarised the membrane potential to +97.8 ± 2.5 mV (n = 4), and this depolarisation was abolished after NADPH oxidase inhibition.     

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.