Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: 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)

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

Rac, a small GTPase in the ras superfamily, regulates at least two biological processes in animal cells: (i) the polymerization of actin and the assembly of integrin complexes to produce lamellipodia and ruffles; and (ii) the activity of an NADPH oxidase in phagocytic cells. NADPH oxidase activation is mediated through a rac effector protein, p67phox, and using chimeras made between rac and the closely related GTPase, rho, we have identified two distinct effector sites in rac, one N-terminal and one C-terminal, both of which are required for activation of p67phox. The same two effector sites are essential for rac-induced actin polymerization in fibroblasts. p65PAK, a ubiquitous serine/threonine kinase, interacts with rac at both the N- and C-terminal effector sites, but the GTPase-activating protein, bcr interacts with rac at a different region. This makes p65PAK, but not bcr, a candidate effector of rac-induced lamellipodium formation.
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PMID:Rac GTPase interacts with GAPs and target proteins through multiple effector sites. 748 19

NADPH oxidase is a plasma membrane enzyme of phagocytes generating superoxide anions which serve as bactericidal agents. Activation of this multimolecular enzyme minimally requires assembly at the membrane with flavocytochrome b558 of cytosolic components p47phox, p67phox, and Rac proteins. Rac1 and Rac2 are 92% homologous cytosolic small GTPase proteins. Both Rac1 and Rac2 have been implicated with NADPH oxidase activation in vitro; however, Rac2 is largely predominant in human phagocytes. Here, using the yeast two-hybrid system, we provide data demonstrating in vivo interactions between human p47phox, p67phox, and Rac proteins. Rac proteins interact with p67phox in a GTP-dependent manner, but do not interact with p47phox. Moreover, Rac effector site mutants, which are known to be inactive in NADPH oxidase, lose their interaction with p67phox; Rac2L61 mutant, which has an increased NADPH oxidase affinity, shows an increased affinity for p67phox. Finally, we observe that p67phox interacts 6-fold better with Rac2 than with Rac1. We also show a strong intracellular interaction between p47phox and p67phox. These results indicate that activated Rac can regulate NADPH oxidase by interacting with p67phox and that Rac2 is the main p67phox-interacting GTPase in human cells.
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PMID:The Rac target NADPH oxidase p67phox interacts preferentially with Rac2 rather than Rac1. 855 Jun 29

The small GTPase Rac assembles with the cytosolic p47(phox) and p67(phox) and the membrane-associated flavocytochrome b558 to form the multicomponent respiratory burst oxidase. Mutation of amino acids in a region of Rac (residues 26-45), homologous to an effector region in Ras, was previously shown to interfere with Rac binding to the oxidase. Herein we have elucidated an additional region in Rac involved in regulating oxidase activity. Rho family small GTPases contain a 12-amino acid "insert" region (residues 124-135) that is not present in Ras. Point mutations in and deletion of this region were constructed and used for in vitro studies of the activation of PAK65 and NADPH oxidase. Apparent binding constants (based on EC50 values) of the mutant Rac proteins for the oxidase are at least 13-25-fold higher than for wild-type Rac. Mutations in the insert region versus the 26-45 effector region resulted in distinct kinetic consequences, pointing to different roles for these two protein regions: mutations in the insert region but not the 26-45 effector region resulted in an increase in the EC50 for p67(phox). Although mutations in the 26-45 amino acid effector region showed markedly diminished activation of both PAK and the NADPH oxidase, insert region mutations did not affect activation of PAK. We propose that the combinatorial use of the 26-45 effector region and the insert region provides the Rho family GTPases with versatility in their specificity for several downstream targets.
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PMID:Rac "insert region" is a novel effector region that is implicated in the activation of NADPH oxidase, but not PAK65. 870 87

The superoxide (O-2)-generating NADPH oxidase of phagocytes is a multicomponent complex consisting of a membrane-associated flavocytochrome (cytochrome b559), bearing the NADPH binding site and two redox centers (FAD and heme) and three cytosolic activating components: p47(phox), p67(phox), and the small GTPase Rac (1 or 2). The canonical view is that the induction of O-2 generation involves the stimulus-dependent assembly of all three cytosolic components with cytochrome b559, a process mimicked in vitro by a cell-free system activated by anionic amphiphiles. We studied the requirement for individual cytosolic components in the activation of NADPH oxidase in a cell-free system consisting of purified and relipidated cytochrome b559, recombinant p47(phox), p67(phox), and Rac1, and the amphiphile, lithium dodecyl sulfate. We found that pronounced activation of NADPH oxidase can be achieved by exposing cytochrome b559 to p67(phox) and Rac1, in the total absence of p47(phox) (turnover = 60 mol O-2/s/mol cytochrome b559). However, maximal activation (turnover = 153 mol O-2/s/mol cytochrome b559) could only be obtained in the presence of p47(phox). O-2 production, in the absence of p47(phox), was dependent on: high molar ratios of p67(phox) and Rac1 to cytochrome b559, Rac1 being in the GTP-bound form, cytochrome b559 being saturated with FAD, and an optimal concentration of amphiphile. Single cytosolic components or combinations of two cytosolic components, other than p67(phox) and Rac1, were incapable of activation. We conclude that p67(phox) and Rac1 are the only cytosolic components directly involved in the induction of electron transport in cytochrome b559. p47(phox) appears to facilitate or stabilize the interaction of p67(phox) and, possibly, Rac1 with cytochrome b559, and is required for optimal generation of O-2 under physiological conditions.
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PMID:The cytosolic component p47(phox) is not a sine qua non participant in the activation of NADPH oxidase but is required for optimal superoxide production. 893 91

The superoxide (O2-)-generating NADPH oxidase of phagocytic cells is composed of a membrane-bound flavocytochrome (cytochrome b-559) and three cytosolic components, p47-phox, p67-phox, and the small GTPase rac-1 (or 2). Cytochrome b-559 bears the NADPH binding site and the redox centers (FAD and heme). Electron flow through the redox centers, from NADPH to oxygen, is activated consequent to the assembly of the three cytosolic components with cytochrome b-559. We studied the kinetics of electron flow through the redox centers of NADPH oxidase in a cell-free system, consisting of purified relipidated and reflavinated cytochrome b-559 and recombinant cytosolic components, activated by the anionic amphiphile, lithium dodecyl sulphate. The NADPH oxidase complex assembled in vitro exhibited: (a) a high steady-state electron flow (165 electrons/heme/s); (b) low stationary levels of FAD and heme reduction (about 10%), and (c) a high rate constant of heme oxidation by oxygen (1720 s-1). Surprisingly, the kinetic properties of NADPH oxidase assembled in a semi-recombinant cell-free system, lacking p47-phox (found to generate significant amounts of O2-), were similar to those of the complete system, as shown by a steady-state electron flow of 83 electrons/heme/s, low stationary levels of FAD and heme reduction (10%), and a rate constant of heme oxidation by oxygen of 1455 s-1. The kinetic features of NADPH oxidase assembled in vitro from purified and recombinant components differ considerably from those of solubilized enzyme preparations derived from intact stimulated phagocytes. The fast operation of the cell-free system is best explained by the activation-related facilitation of electron flow at both the FAD-->heme and the heme-->oxygen steps.
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PMID:Electron transfer in the superoxide-generating NADPH oxidase complex reconstituted in vitro. 913 Oct 41

The elicitation of an oxidative burst in phagocytes rests on the assembly of a multicomponental complex (NADPH oxidase) consisting of a membrane-associated flavocytochrome (cytochrome b559), representing the redox element responsible for the NADPH-dependent reduction of oxygen to superoxide (O-2), two cytosolic components (p47(phox), p67(phox)), and the small GTPase Rac (1 or 2). We found that 4-(2-aminoethyl)-benzenesulfonyl fluoride (AEBSF), an irreversible serine protease inhibitor, prevented the elicitation of O-2 production in intact macrophages and the amphiphile-dependent activation of NADPH oxidase in a cell-free system, consisting of solubilized membrane or purified cytochrome b559 combined with total cytosol or a mixture of recombinant p47(phox), p67(phox), and Rac1. AEBSF acted at the activation step and did not interfere with the ensuing electron flow. It did not scavenge oxygen radicals and did not affect assay reagents. Five other serine protease inhibitors (three irreversible and two reversible) were found to lack an inhibitory effect on cell-free activation of NADPH oxidase. A structure-function study of AEBSF analogues demonstrated that the presence of a sulfonyl fluoride group was essential for inhibitory activity and that compounds containing an aminoalkylbenzene moiety were more active than amidinobenzene derivatives. Exposure of the membrane fraction or of purified cytochrome b559, but not of cytosol or recombinant cytosolic components, to AEBSF, in the presence of a critical concentration of the activating amphiphile lithium dodecyl sulfate, resulted in a marked impairment of their ability to support cell-free NADPH oxidase activation upon complementation with untreated cytosol or cytosolic components. Kinetic analysis of the effect of varying the concentration of each of the three cytosolic components on the inhibitory potency of AEBSF indicated that this was inversely related to the concentrations of p47(phox) and, to a lesser degree, p67(phox). AEBSF also prevented the amphiphile-elicited translocation of p47(phox) and p67(phox) to the membrane. These results are interpreted as indicating that AEBSF interferes with the binding of p47(phox) and/or p67(phox) to cytochrome b559, probably by a direct effect on cytochrome b559.
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PMID:Inhibition of NADPH oxidase activation by 4-(2-aminoethyl)-benzenesulfonyl fluoride and related compounds. 914 50

Activation of the respiratory burst oxidase involves the assembly of the membrane-associated flavocytochrome b558 with the cytosolic components p47(phox), p67(phox), and the small GTPase Rac. Herein, the interaction between Rac and p67(phox) is explored using functional and physical methods. Mutually facilitated binding (EC50) of Rac1 and p67(phox) within the NADPH oxidase complex was demonstrated using steady state kinetic methods measuring NADPH-dependent superoxide generation. Direct binding of Rac1 and Rac2 to p67(phox) was shown using a fluorescent analog of GTP (methylanthraniloyl guanosine-5'-[beta,gamma-imido]triphosphate) bound to Rac as a reporter group. An increase in the methylanthraniloyl fluorescence was seen with added p67(phox) but not p47(phox), and the emission maximum shifted from 445 to 440 nm. Rac1 and Rac2 bound to p67(phox) with a 1:1 stoichiometry and with Kd values of 120 and 60 nM, respectively. Mutational studies (Freeman, J., Kreck, M., Uhlinger, D. J., and Lambeth, J. D. (1994) Biochemistry 33, 13431-13435; Freeman, J. L., Abo, A., and Lambeth, J. D. (1996) J. Biol. Chem. 271, 19794-19801) previously identified two regions in Rac1 that are important for activity: the "effector region" (residues 26-45) and the "insert region" (residues 124-135). Proteins mutated in the effector region (Rac1(N26H), Rac1(I33N), and Rac1(D38N)) showed a marked increase in both the Kd and the EC50, indicating that mutations in this region affect activity by inhibiting Rac binding to p67(phox). Insert region mutations (Rac1(K132E) and L134R), while showing markedly elevated EC50 values, bound with normal affinity to p67(phox). The structure of Rac1 determined by x-ray crystallography reveals that the effector region and the insert region are located in defined sectors on the surface of Rac1. A model is discussed in which the Rac1 effector region binds to p67(phox), the C terminus binds to the membrane, and the insert region interacts with a different protein component, possibly cytochrome b558.
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PMID:Rac binding to p67(phox). Structural basis for interactions of the Rac1 effector region and insert region with components of the respiratory burst oxidase. 922 59

Rac1 and Rac2 are 92% homologous cytosolic small GTPase proteins. Both Rac1 and Rac2 have been implicated with NADPH oxidase activation in vitro, however, Rac2 is largely predominant in human phagocytes. NADPH oxidase is a plasma membrane enzyme of phagocytes, generating superoxide anions which serve as bactericidal agents. Activation of this multimolecular enzyme, minimally requires assembly at the membrane with flavocytochrome b258 of cytosolic components p47phox, p67phox and Rac proteins. Using the yeast two hybrid system, we provide data demonstrating in vivo interactions between human p47phox, p67phox, and Rac proteins. Rac proteins interact with p67phox in a GTP-dependent manner, but do not interact with p47phox. Moreover, Rac effector site mutants which are known to be inactive in NADPH oxidase lose their interaction with p67phox. Finally, we observe that p67phox interacts six fold better with Rac2 than with Rac1. We also show a strong intracellular interaction between p47phox and p67phox. These results indicate that activated Rac, and particularly Rac2, can regulate superoxide production by NADPH oxidase of phagocytic cells through direct interaction with p67phox subunit. Recently published data suggest that Rac proteins could transduce mitogenic signals in non-phagocytic cells through superoxide production by a phagocytic-related NADPH oxidase enzymatic system which remains to be determined. NADPH oxidase regulation by Rac proteins in phagocytes could then be used as a model to understand the molecular mechanisms underlying Rac functions in various cell types.
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PMID:[Signal transduction by Rac small G proteins in phagocytes]. 925 50

The cytosolic proteins p47phox and p67phox, each containing two SH3 domains, are required for activation of the superoxide-producing phagocyte NADPH oxidase in a cell-free system with human neutrophil membrane and the small GTPase Rac. Here we focus on roles of proline-rich regions (PRRs) that reside in p47phox and p67phox. Deletion of the p47phox PRR, to which the C-terminal SH3 domain of p67phox binds, results in three-fold decreased activation of the enzyme in the cell-free system with the full-length p67phox, suggesting a modulatory role of the p47phox PRR. The modulation is likely mediated via the C-terminal region of p67phox, since the p47phox mutant protein fully activates the oxidase in combination with the N-terminus of p67phox. Neither deletion of the p67phox PRR nor substitutions for prolines in the region affects the ability to support superoxide production under the cell-free conditions, indicating that the PRR of p67phox has no primary function in the oxidase activation.
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PMID:Roles for proline-rich regions of p47phox and p67phox in the phagocyte NADPH oxidase activation in vitro. 942 54


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