Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:1.6.99.6 (NADPH oxidase)
 10,295 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Guanine and/or adenine nucleotides appear to be involved in the activation of the superoxide-generating NADPH oxidase of phagocytic cells. Their precise roles, however, are unclear, as much of the evidence for their involvement comes from experiments in which nucleotides have been added to complex systems already rich in both endogenous nucleotides and enzymes capable of interconverting them. To circumvent this problem we have examined the role of nucleotides in neutrophil NADPH oxidase activation by using a cell-free system in which adenine and guanine nucleotide concentrations were carefully controlled and monitored by (i) depletion of endogenous nucleotides by extensive dialysis and charcoal treatment; (ii) reconstitution of the depleted system with reagents analyzed for purity; and (iii) measurement of nucleotide levels in cytosol preparations and in oxidase reaction mixtures by HPLC analysis. In contrast to previous reports that have demonstrated only a several-fold enhancement of oxidase activity by GTP or its analogs, we have shown that oxidase activation was absolutely dependent upon GTP in reactions containing dialyzed cytosol in which the total endogenous nucleotide levels were reduced by greater than 99.5%. Kinetic studies revealed that GTP is required at or before the rate-limiting step in oxidase activation. Two nonhydrolyzable analogs of GTP, guanosine 5'-(gamma-thio)triphosphate and guanylyl imidodiphosphate, were even more active than GTP, suggesting the involvement of one or more GTP-binding proteins. In contrast, ATP was neither necessary nor sufficient for oxidase activation. If reaction mixtures were contaminated with GDP and/or GMP, however, ATP (but not its nonhydrolyzable analog adenylyl imidodiphosphate) could indirectly support oxidase activation by means of endogenous enzymes that catalyze the ATP-dependent conversion of GMP and GDP to GTP.
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PMID:Absolute requirement for GTP in activation of human neutrophil NADPH oxidase in a cell-free system: role of ATP in regenerating GTP. 131 25

The superoxide-generating NADPH oxidase system in phagocytes consists of at least membrane-associated cytochrome b558 and three cytosolic components named SOCI/NCF-3/sigma 1/C1, SOCII/NCF-1/p47-phox, and SO-CIII/NCF-2/p67-phox. p47-phox and p67-phox were isolated, and their primary structures were determined, but SOCI has not been well characterized. In the present study, we first purified SOCI to homogeneity from the cytosol fraction of the differentiated HL-60 cells. The purified SOCI was a small GTP-binding protein (G protein) with a M(r) of about 22,000. The guanosine 5'-(3-O-thio)triphosphate-bound form, but not the GDP-bound form, of this small G protein showed the SOCI activity. The partial amino acid sequence of SOCI thus far determined was identical to the amino acid sequence deduced from the cDNA encoding rac2 p21. None of the purified small G proteins, including Ki-ras p21, smg p21B/rap1B p21, rhoA p21, and rac1 p21, showed the SOCI activity. These results indicate that SOCI is a small G protein very similar, if not identical, to rac2 p21. The GDP/GTP exchange reaction of SOCI was stimulated and inhibited by stimulatory and inhibitory GDP/GTP exchange proteins for small G proteins, named smg GDS and rho GDI, respectively. The NADPH oxidase activity was also stimulated and inhibited by smg GDS and rho GDI, respectively. These results indicate that the superoxide-generating NADPH oxidase system is regulated by both smg GDS and rho GDI through rac2 p21 or the rac2-related small G protein in phagocytes.
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PMID:Regulation of the superoxide-generating NADPH oxidase by a small GTP-binding protein and its stimulatory and inhibitory GDP/GTP exchange proteins. 131 93

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.
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PMID:Purification and characterization of Rac 2. A cytosolic GTP-binding protein that regulates human neutrophil NADPH oxidase. 133 Oct 90

rac1 and rac2 p21s are ras p21-like small GTP-binding proteins which are implicated in the NADPH oxidase-catalyzed superoxide generation in phagocytes. rac1 and rac2 p21s have a Cys-A-A-Leu (A = aliphatic amino acid) structure in their C-terminal region which may undergo post-translational processing including prenylation, proteolysis, and carboxyl methylation. We studied the function of this post-translational processing of rac p21s in their interaction with the stimulatory and inhibitory GDP/GTP exchange proteins for rac p21s, named smg GDS and rho GDI, and in their NADPH oxidase activation. We produced human recombinant rac1 and rac2 p21s in insect cells and purified them from the membrane and soluble fractions as the post-translationally processed and unprocessed forms, respectively. Post-translationally processed rac1 and rac2 p21s were sensitive to both smg GDS and rho GDI, but post-translationally unprocessed rac1 and rac2 p21s were insensitive to them. The GTP gamma S (guanosine 5'-(3-O-thio)triphosphate)-bound form of post-translationally processed rac1 and rac2 p21s stimulated the NADPH oxidase activity, but post-translationally unprocessed rac1 and rac2 p21s were far less effective. These results indicate that both rac1 and rac2 p21s stimulate the NADPH oxidase activity and that their post-translational processing is important not only for their interaction with smg GDS and rho GDI but also for their NADPH oxidase activation.
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PMID:Post-translational processing of rac p21s is important both for their interaction with the GDP/GTP exchange proteins and for their activation of NADPH oxidase. 146 87

Incorporation of the available data on rac in neutrophils, CDC42 in yeast, and rho in fibroblasts suggests a general model for the function of rho-like GTPase (Figure 1). Conversion of an inactive cytoplasmic rho-related p21GDP/GDI complex to active p21. GTP occurs by inhibition of GAP and/or stimulation of exchange factors in response to cell signals. p21.GTP is then able to interact with its target at the plasma membrane. This could result in a conformational change in the target, enabling it to bind cytosolic protein(s). Alternatively, p21.GTP could be actively involved in transporting cytosolic protein(s) to the target. A GAP protein, perhaps intrinsic to the complex, would stimulate GTP hydrolysis allowing p21.GDP to dissociate. Solubilization of p21GDP by interaction with GDI would complete a cycle. What about the nature of the final complex? The rac-regulated NADPH oxidase complex in neutrophils is currently the best understood and most amenable to further biochemical analysis. Two plasma-membrane bound subunits encode the catalytic function necessary for producing superoxide, but the two cytosolic proteins, p47 and p67, are essential for activity. Why the complexity? Production of superoxide is tightly coordinated with phagocytosis, a membrane process driven by rearrangement of cortical actin. This is not unrelated to the membrane ruffling and macropinocytosis that we observe in fibroblasts microinjected with p21rac. It is tempting to speculate, therefore, that in neutrophils rac is involved not only in promoting the assembly of the NADPH oxidase but also in the coordinate reorganization of cortical actin leading to phagocytosis. For CDC42 controlled bud assembly in yeast, the components of the plasma-membrane complex are not so clear. By analogy with rac in neutrophils, it seems likely that CDC42 is involved in promoting the assembly of cytosolic components at the bud site on the plasma membrane. These putative cytosolic proteins have not yet been identified, but BEM1 and ABP1 are two possible candidates. The biochemical basis for the stimulation of adhesion plaques and actin stress fibers by p21rho in fibroblasts is also unclear. However, components of the adhesion plaque such as vinculin and talin are known to be cytosolic when not complexed with integrin receptors, and rho could be involved in regulating their assembly into the adhesion plaque. Several things are still difficult to incorporate into this model. First the target for CDC42, the bud site, although not yet structurally defined requires the activity of another small GTPase, BUD1. Similarly, in activated neutrophils, the NADPH oxidase is found in a complex with rap1, the mammalian homologue of BUD1 (BoKoch et al., 1989). It seems likely, therefore, that the target is not simply a plasma-membrane protein but may be a complex of proteins whose formation is under the control of the rap1/BUD1 GTPase. The other black box in this model is the actin connection: activation of bud assembly by CDC42 is followed by actin polymerization, activation of NADPH oxidase in neutrophils occurs concomitantly with phagocytosis, a cortical actin-dependent process, and p21rho in fibroblasts couples the formation of adhesion plaques to actin stress fibers. One possible link between the GTPase-driven assembly of a plasma-membrane complex and actin polymerization could involve the SH3 domain. Interestingly, both p47 and p67 and yeast ABP1 and BEM1 have SH3 domain. If rho-like GTPases recognize plasma-membrane targets already associated with cortical actin, then this could promote an interaction with a subset of SH3-containing proteins. The result of this would be a GTPase-regulated aggregation of a group of proteins at a single site in the plasma membrane. It is not too difficult to imagine biological processes where such a spatial integration of different biochemical activities would be essential: coupling the assembly of bud components to the formation of actin fibers in yeast; or the activation of NADPH oxidase to phagocytosis in neutrophils; or the assembly of adhesion plaques and the formation of actin stress fibers in fibroblasts are just three examples that have emerged so far. In conclusion, although rho-like GTPases clearly have distinct roles in different mammalian cell types and in yeast, their underlying mechanism of action appears to be strikingly similar. Whether this will remain so when there are some biochemical data to back up these initial observations, time will tell.
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PMID:Ras-related GTPases and the cytoskeleton. 161 Nov 53

Activation of neutrophils was recently reported to be accompanied by large changes in their Cl- content [J. B. Myers, H. F. Cantiello, J. H. Schwartz, and A. I. Tauber. Am. J. Physiol. 259 (Cell Physiol. 28): C531-C540, 1990]. The significance of these ionic changes to the immune response has not been studied. To evaluate the role of intracellular [Cl-], the anionic composition of the cytosol was varied in human neutrophils permeabilized by electroporation or by treatment with streptolysin O. In Cl(-)-rich media, permeabilized but otherwise untreated cells remained quiescent, resembling unstimulated intact cells. In contrast, suspension of permeabilized cells in Cl(-)-depleted media elicited protein phosphorylation, actin polymerization, secretion of lysozyme, and a respiratory burst. The latter was demonstrated by several criteria to be mediated by the NADPH oxidase. The responses observed in Cl(-)-depleted media were insensitive to pretreatment of the cells with pertussis toxin but were inhibited by addition of GDP or by omission of ATP. The data suggest that an early event in signal transduction, common to several effectors, is sensitive to the ionic composition of the cytosol. This component, possibly a GTP-binding protein, may be affected by the anion concentration changes reported to occur during physiological stimulation of neutrophils.
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PMID:Activation of permeabilized neutrophils: role of anions. 163 84

Activation of superoxide-producing NADPH oxidase of neutrophils requires the presence of cell membranes, cytosolic components and arachidonate and is markedly enhanced by non-hydrolysable analogues of guanine nucleotides, i.e. guanosine 5'-[gamma-thio]triphosphate and guanosine 5'[beta gamma-imido]triphosphate (p[NH]ppG). Gel filtration and ultrafiltration of the cytosol decreased the basal activity of NADPH oxidase. Activity could be restored by GTP, suggesting participation of the nucleotide in basal activation. Preincubation of neutrophil cytosol with periodate-oxidized p[NH]ppG (ox-p[NH]ppG) followed by gel filtration resulted in a time-dependent enhancement of basal oxidase activity. The presence of GDP or GTP, but not ATP, during the incubation with ox-p[NH]ppG abolished this enhancement. These data are consistent with a stable association of ox-p[NH]ppG with an oxidase-linked cytosolic protein. SDS/PAGE of neutrophil cytosol preincubated with [3H]ox-p[NH]ppG revealed radioactivity in bands migrating as 100, 70, 47, 34 and 22 kDa proteins. Evidence for covalent labelling of the cytosolic protein p47-phox with [3H]ox-p[NH]ppG is presented. Heterogeneity of cytosolic GTP-binding sites and possible participation of protein p47-phox in functional interaction with GTP analogues during cell-free activation are suggested.
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PMID:Involvement of GTP in cell-free activation of neutrophil NADPH oxidase. Studies with GTP analogues. 163 53

Superoxide production by neutrophil NADPH oxidase activated in a cell-free system consisting of plasma membranes, cytosol and arachidonate is enhanced by nonhydrolyzable analogs of GTP and reduced by GDP. To characterize the interaction of guanine nucleotides with the system, dialdehyde analogs of GTP and GDP (oGTP and oGDP) were employed. oGDP or oGTP caused an irreversible and dose dependent inactivation of NADPH oxidase-supporting cytosolic activity. Cytosol was fractionated on S and Q Sepharose ion exchange columns into three fractions, combinations of which synergistically supported activation of NADPH oxidase. Two fractions shown by immunoblotting to contain the oxidase-linked p47 and p67 proteins were inactivated by oGDP. Labeling with [alpha-32P]-oGTP lead to incorporation of the label into several proteins.
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PMID:Dialdehyde-GDP blocks activity of cytosolic components of neutrophil NADPH oxidase. 204 36

Electropermeabilization creates small pores in the plasma membrane allowing the introduction of low-molecular-weight modulatory components, such as ions and nucleotides, into the cytosol. The present study investigates fluoride-mediated stimulation of the signal transduction pathway that activates the respiratory burst in electropermeabilized neutrophils. In marked contrast to intact (i.e., non-electropermeabilized) neutrophils, cells permeabilized by this technique demonstrated an immediate and potent stimulation of the superoxide (O2-)-generating NADPH oxidase in response to the addition of fluoride. Furthermore, permeabilization of neutrophils in the presence of exogenously added ATP enhanced the rate of F(-)-mediated O2- production. Fluoride-stimulated O2- production in electropermeabilized neutrophils was antagonized by GDP beta S and dependent upon the presence of Mg2+ in the medium, but was insensitive to pertussis toxin treatment, consistent with the hypothesis that fluoride activates a G protein, probably Gp, by interacting with the nucleotide-binding site on the G alpha subunit. In addition, electropermeabilized neutrophil O2- release triggered by F- was blocked by staurosporine and H-7, indicating that this pathway proceeds largely through protein kinase C activation. However, nucleotide-enhanced O2- production was only partially blocked by these inhibitors, suggesting that under such conditions ATP either competes with the inhibitor-protein kinase interaction or affects the signaling pathway(s) in such a way that protein kinase C may no longer be necessary for the activation of NADPH oxidase.
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PMID:Fluoride-mediated activation of the respiratory burst in electropermeabilized neutrophils. 211 32

The superoxide generating NADPH oxidase was studied in an SDS-activated cell-free system. This system requires the participation of both membranal and cytosolic components. Cytosol derived from elicited peritoneal guinea pig macrophages was fractionated by several nucleotide affinity chromatography procedures. Various such fractionations led to the separation of two distinct factors, both of which are necessary for the activation and/or activity of the superoxide-forming NADPH oxidase. One factor (sigma 2), bound to octyl, 2',5'-ADP-, 5'-ATP-, 5'-GTP-agarose and carboxymethyl-Sepharose but did not bind to hexyl, 5'-AMP-, 5'-ADP- and 5'-GDP-agarose. The other factor (sigma 1) did not bind to any of the above matrices. Subsequent elution of sigma 2 from 2',5'-ADP-agarose was effected by ATP, GTP and NADPH but not by NADH. Elution from GTP-agarose was by ATP and GTP but not by NADPH. Elution from ATP-agarose was by ATP, GTP and also, albeit weakly, by NADPH. The above results suggest that sigma 2 contains a site which recognizes the phosphate group at the ribose 2' position in adenosine, and a site that recognizes purine nucleotide triphosphates.
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PMID:Nucleotide binding properties of cytosolic components required for expression of activity of the superoxide generating NADPH oxidase. 215 58


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