EC:1.6.3.1 - FACTA Search

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Query: EC:1.6.3.1 (NADPH oxidase)
11,281 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

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

Chronic granulomatous diseases (CGDs) are characterized by recurrent infections resulting from impaired superoxide production by a phagocytic cell, nicotinamide adenine dinucleotide phosphate (reduced) (NADPH) oxidase. Complementary DNAs were cloned that encode the 67-kilodalton (kD) cytosolic oxidase factor (p67), which is deficient in 5% of CGD patients. Recombinant p67 (r-p67) partially restored NADPH oxidase activity to p67-deficient neutrophil cytosol from these patients. The p67 cDNA encodes a 526-amino acid protein with acidic middle and carboxyl-terminal domains that are similar to a sequence motif found in the noncatalytic domain of src-related tyrosine kinases. This motif was recently noted in phospholipase C-gamma, nonerythroid alpha-spectrin (fodrin), p21ras-guanosine triphophatase-activating protein (GAP), myosin-1 isoforms, yeast proteins cdc-25 and fus-1, and the 47-kD phagocyte oxidase factor (p47), which suggests the possibility of common regulatory features.
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PMID:Cloning of a 67-kD neutrophil oxidase factor with similarity to a noncatalytic region of p60c-src. 169 59

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

Professional phagocytes contain a unique NADPH oxidase responsible for the production of microbicidal oxidants. Activation of this oxidase requires participation of cytosolic and membrane proteins, but the interactions of these components are incompletely understood. Patients with autosomal recessive Chronic Granulomatous Diseases (CGD) are characterized by functional defects in phagocyte oxidase activity resulting from a deficiency of either a 47 kDa (p47) or a 67 kDa (p67) cytosolic oxidase component. Cytosols from such patients are valuable for biochemical studies of the oxidase, but are not generally available because CGD is a rare disorder. The present study illustrates means of producing cytosols functionally and immunochemically deficient in either p47 or p67. Cytosol from monocytes cultured for 6 days is immunochemically deficient in p47 but not p67, while cytosol from HL-60 cells induced with retinoic acid for 3 days is deficient in p67 but not p47. Each of these cytosols fail to generate superoxide when added to neutrophil membranes in a cell-free assay but complement each other when combined. Complementation studies in which these cytosols were mixed in the cell-free assay with p47- or p67- deficient CGD cytosol established the functional characteristics of the experimentally produced cytosols.
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PMID:Production of myeloid cell cytosols functionally and immunochemically deficient in the 47 kDa or 67 kDa NADPH oxidase cytosolic factors. 216 70

Activation of the phagocyte NADPH oxidase requires participation of membrane-bound cytochrome b558 and cytosol proteins of 47 kDa (p47) and 67 kDa (p67). We examined the sequence of participation of p47 and p67 in activation of the oxidase using an arachidonate-activated cell-free superoxidase (O2-) generating assay requiring phagocyte membrane and cytosol. Neutrophil cytosol from patients with certain forms of autosomal recessive chronic granulomatous disease (CGD) lack either p47 or p67. Initial incubation of membrane and arachidonate with CGD cytosol deficient in either p47 or p67 fails to generate superoxide in the cell-free assay until addition of complementary cytosol. CGD cytosol was incubated with arachidonate and membrane for 5-15 min and the lag time of O2- generation was measured after addition of complementary CGD cytosol. The lag time is shortened when p47, but not p67, is present in the initial incubation. We have previously shown that the peptide, RGVHFIF, corresponding to a cytoplasmic carboxyl-terminal domain of the large subunit of cytochrome b558, inhibits activation of NADPH oxidase in the cell-free assay, but does not affect the enzyme activity of fully assembled oxidase. Experiments with sequential addition of complementary CGD cytosols were performed as above, except that RGVHFIF was added after the initial incubation. The peptide failed to inhibit when added after initial incubation if p47 was present during that incubation. In contrast, the peptide markedly inhibited oxidase activity if p47 was absent during the initial incubation. These results suggest that p47, but not p67, is a participant with membrane and/or other cytosol components in early arachidonate-dependent reactions. In the absence of p67, these reactions culminate in the irreversible formation of a metastable activation intermediate that is insensitive to inhibition by RGVHFIF. After addition of p67, this activation intermediate subsequently reacts to form the active NADPH oxidase.
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PMID:The phagocyte 47-kilodalton cytosolic oxidase protein is an early reactant in activation of the respiratory burst. 216 17

Differentiation of myeloid cells is associated with the gradual acquisition of functional capacity to produce a respiratory burst. In our study HL-60 cells were differentiated to the monocyte phenotype with IFN-gamma or 1,25-dihydroxyvitamin D3, or to the neutrophil phenotype with retinoic acid or DMSO to compare the time-course of expression of membrane and cytosolic oxidase components, and to correlate this with the appearance of a functional oxidase. Over a 6-day period of induction the rank order of the ability of these agents to induce expression of PMA-stimulated superoxide production was: IFN-gamma greater than 1,25(OH)2D3 greater than retinoic acid greater than DMSO. Immunoblot analysis of HL-60 membranes and cytosol was used to assess the amount of specific phagocyte oxidase factors (91 and 22 kDa subunits of membrane cytochrome b558 (gp91 and p22), and 47 and 67 kDa cytosol oxidase factors (p47 and p67)). HL-60 cell membranes or cytosol were tested in a cell-free assay of superoxide production by mixing with normal neutrophil cytosol or membranes, respectively. p47 was first detected at 16 h of differentiation, increasing similarly thereafter with all induction regimens and reaching a maximum by 3 to 4 days. The earliest detection of p67 varied from 2 to 6 days depending on the inducing agent and appeared to be the limiting cytosol component. Small amounts of both subunits of cytochrome b558 were detected in uninduced HL-60 membranes, but were sufficient to support substantial superoxide production when combined with normal neutrophil cytosol. Both cytochrome b558 subunit proteins and membrane oxidase activity increased during differentiation in parallel. We conclude that membrane and cytosol components of the NADPH oxidase complex appear at different times and increase differently during HL-60 differentiation. The production of p67 is the major factor limiting the respiratory burst during HL-60 differentiation.
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PMID:Induction of the respiratory burst in HL-60 cells. Correlation of function and protein expression. 217 May 20

Studies of neutrophil nicotinamide adenine dinucleotide phosphate (NADPH) oxidase activation in a cell-free system showed that the low molecular-weight guanosine triphosphatase (GTPase) Rac was required, and that Rap1a may participate in activation of the catalytic complex. Full-length posttranslationally modified Rac2 was active, whereas only the 1-166 truncated form of Rap1a was functional in the cell-free system, and thus, clarification of the function of Rap1a and Rac2 in intact human phagocytes is needed to provide further insight into their roles as signal transducers from plasma membrane receptors. In the present studies, oligonucleotide-directed mutagenesis was used to introduce a series of mutations into human rap1a or rac2 in the mammalian expression vector pSR alpha neo. HL60 cells transfected with wild-type or mutated rac2 or rap1a cDNA constructs and control HL60 cells transfected with the pSR alpha neo vector containing no inserted cDNA were selected in G418-containing media, then subclones were isolated. Compared with the parent HL60 cells, each of the stable transfected cell lines differentiated similarly into neutrophil-like cells and expressed comparable levels of NADPH oxidase components p47-phox, p67-phox and gp91-phox. The differentiated vector control cell line produced O2. in response to receptor stimulation at rates that were not significantly different from parent HL60 cells. O2-. production by differentiated cell lines expressing mutated N17 Rap1a or N17 Rac2 dominant-negative proteins was inhibited, whereas O2-. production by the subline overexpressing wild-type Rap1a was increased by fourfold. O2-. production by the differentiated cell line expressing GTPase-defective V12 Rap1a was also significantly inhibited, a finding that is consistent with a requirement for cycling between guanosine diphosphate- and GTP-bound forms of Rap1a for continuous NADPH oxidase activation in intact neutrophils. A model is proposed in which Rac2 mediates assembly of the p47 and p67 oxidase components on the cytosolic face of the plasma membrane via cytoskeletal reorganization, whereas Rap1a functions downstream as the final activation switch involving direct physical interaction with the transmembrane flavocytochrome component of the NADPH oxidase.
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PMID:Function of wild-type or mutant Rac2 and Rap1a GTPases in differentiated HL60 cell NADPH oxidase activation. 783 80

The neutrophil NADPH oxidase activation factors, p47, p67 and the small guanosine-nucleotide-binding regulatory (G) protein Rac1, were expressed in a baculovirus/insect cell system and purified. In coinfection experiments in which Sf9 cells overexpressed concomitantly p47, p67 and Rac1, the latter was not detected in the p47-p67 complex. The propensity of p47 and p67 to associate together was used to purify recombinant p67 from baculovirus-infected Sf9 cells. 20% of the overexpressed Rac1 in infected Sf9 cells was prenylated and was extracted with low doses of detergent from membranes. Elicitation of full oxidase activity on crude neutrophil membranes using a cell-free system required addition of recombinant p47 and p67, but not that of Rac. In contrast, in the case of KCl-washed membranes, addition of Rac, prenylated or unprocessed, together with p47 and p67 was found to enhance oxidase activation up to fivefold. In all experiments, the amount of added arachidonic acid was optimized. In contrast to prenylated Rac, non-prenylated Rac had to be loaded with guanosine 5'-(3-thiotriphosphate) (GTP[S]) to exhibit full activation efficiency. In the cell-free system used, Rac was shown to be the mediator of the GTP[S] effect. The results suggest that the plasma membrane of resting neutrophils contains a sufficient amount of prenylated Rac for efficient oxidase activation. We therefore propose that Rac has a membrane-associated role and helps to dock and position p47 and p67 on the flavocytochrome b component of the oxidase complex.
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PMID:Activation of the O2(-)-generating NADPH oxidase in a semi-recombinant cell-free system. Assessment of the function of Rac in the activation process. 800 73

The production of free oxygen radicals by polymorphonuclear cells (PMNs) was studied in 25 patients after blunt trauma. Superoxide generation significantly increased immediately after trauma and returned to normal soon after the event. Patients were subsequently divided into two groups: those who developed sepsis and those who did not develop infectious complications. Superoxide production by intact PMNs following stimulation by three different stimulants was initially not different in trauma patients who developed sepsis. Follow-up showed an increase in superoxide production when infection complicated the course of trauma patients. Further studies were performed in a cell-free system containing cell membranes and cytosol from patients or healthy controls. No difference in the production of superoxide was found when membranes from trauma patients or controls were mixed with cytosols from controls. When cytosols from patients were mixed with membranes from controls, a significant increase in superoxide production was observed in the group that developed sepsis. Immunoblotting analysis of two protein components of the cytosolic portion of the NADPH oxidase, p47 and p67, were done. The increase in quantity of p47 correlated with the increase in superoxide production during sepsis, and thus may be the major contributor to the high activity.
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PMID:Superoxide production by neutrophils from trauma patients: regulation of NADPH oxidase activity. 802 54

We have presented evidence that rap1b, a 22 kDa low molecular weight GTP binding protein, becomes associated with the cytoskeleton in thrombin-activated platelets. The initial incorporation is very rapid and occurs as fast as we can measure it. Thus, some rap1b is associated with the cytoskeleton as fast as it is formed. The remainder of the rap1b is incorporated more slowly. This biphasic incorporation of rap1b is similar to the incorporation of GPIIb/IIIa into the cytoskeleton, but no interaction between GPIIb/IIIa and rap1b could be demonstrated. Phosphorylation of rap1b by cAMP-dependent protein kinase did not inhibit its association with the cytoskeleton. We conclude that rap1b is one of an increasing number of proteins that associate with the cytoskeleton during cell activation. The function of rap1b in the cytoskeleton is unclear at this time. However, it is possible to speculate on potential roles. There is growing evidence that low molecular weight G proteins participate in the formation of multi-molecular aggregates. For example, p21rac promotes the assembly of a membrane-associated complex composed of NADPH oxidase, p47, and p67 and this complex is important for activation of NADPH oxidase in neutrophils. Similarly, in yeast, BUD1, a homolog of rap1, forms a complex with BUD5 (a homolog of GDI), BEMI, CDC24, and CDC42 (a homolog of G25K). This multi-protein aggregate may be important in cytoskeletal structure in yeast. In platelets, rad1b, which is membrane associated, may promote the assembly of a complex of proteins during cell activation and may localize this complex to the plasma membrane.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Cytoskeletal interactions of Rap1b in platelets. 820 87

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