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The superoxide-generating NADPH oxidase: structural aspects and activation mechanism 总被引:31,自引:0,他引:31
Vignais PV 《Cellular and molecular life sciences : CMLS》2002,59(9):1428-1459
Flavocytochrome b
558
is the catalytic core of the respiratory-burst oxidase, an enzyme complex that catalyzes the NADPH-dependent reduction of
O2 into the superoxide anion O2
- in phagocytic cells. Flavocytochrome b
558
is anchored in the plasma membrane. It is a heterodimer that consists of a large glycoprotein gp91phox (phox for phagocyte oxidase) (β subunit) and a small protein p22phox (α subunit). The other components of the respiratory-burst oxidase are water-soluble
proteins of cytosolic origin, namely p67phox, p47phox, p40phox and Rac. Upon cell stimulation, they assemble with the membrane-bound
flavocytochrome b
558
which becomes activated and generates O2
-. A defect in any of the genes encoding gp91phox, p22phox, p67phox or p47phox results in chronic granulomatous disease, a
genetic disorder characterized by severe and recurrent infections, illustrating the role of O2
- and the derived metabolites H2O2 and HOCl in host defense against invading microorganisms. The electron carriers, FAD and hemes b, and the binding site for NADPH are confined to the gp91phox subunit of flavocytochrome b
558
. The p22phox subunit serves as a docking site for the cytosolic phox proteins. This review provides an overview of current
knowledge on the structural organization of the O2
--generating flavocytochrome b
558
, its kinetics, its mechanism of activation and the regulation of its biosynthesis. Homologues of gp91phox, called Nox and
Duox, are present in a large variety of non-phagocytic cells. They exhibit modest O2
--generating oxidase activity, and some act as proton channels. Their role in various aspects of signal transduction is currently
under investigation and is briefly discussed.
Received 28 May 2002; received after revision 20 June 2002; accepted 24 June 2002 相似文献
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The transmembrane electrochemical proton gradient generated by the redox systems of the respiratory chain in mitochondria and aerobic bacteria is utilized by proton translocating ATP synthases to catalyze the synthesis of ATP from ADP and P(i). The bacterial and mitochondrial H(+)-ATP synthases both consist of a membranous sector, F0, which forms a H(+)-channel, and an extramembranous sector, F1, which is responsible for catalysis. When detached from the membrane, the purified F1 sector functions mainly as an ATPase. In chloroplasts, the synthesis of ATP is also driven by a proton motive force, and the enzyme complex responsible for this synthesis is similar to the mitochondrial and bacterial ATP synthases. The synthesis of ATP by H(+)-ATP synthases proceeds without the formation of a phosphorylated enzyme intermediate, and involves co-operative interactions between the catalytic subunits. 相似文献
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Summary It is possible to dissociate the activity of different enzymatic systems of the bacteriumEscherichia coli by the action of high hydrostatic pressures. This activity is studied in the microbes after having been subjected to high hydrostatic pressure. Each enzymatic system is inhibited at different pressures. The enzymes of the bacteria submitted to pressures lower than the inhibiting limit show a residual enzymatic activity; sometimes this activity appears after a phase of lag. 相似文献
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Summary ATP hydrolysis and inorganic pyrophosphate hydrolysis in chloroplasts of spinach leaves are characterized by a different pH optimum, a different sensitivity to magnesium ions, top-chloromercuribenzoate and to ageing. It is concluded that ATP and inorganic pyrophosphate are likely hydrolyzed by two different enzymes in chloroplasts. 相似文献
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J. P. Issartel A. Dupuis J. Garin J. Lunardi L. Michel P. V. Vignais 《Cellular and molecular life sciences : CMLS》1992,48(4):351-362
The transmembrane electrochemical proton gradient generated by the redox systems of the respiratory chain in mitochondria and aerobic bacteria is utilized by proton translocating ATP synthases to catalyze the synthesis of ATP from ADP and Pi. The bacterial and mitochondrial H+-ATP synthases both consist of a membranous sector, F0, which forms a H+-channel, and an extramembranous sector, F1, which is responsible for catalysis. When detached from the membrane, the purified F1 sector functions mainly as an ATPase. In chloroplasts, the synthesis of ATP is also driven by a proton motive force, and the enzyme complex responsible for this synthesis is similar to the mitochondrial and bacterial ATP synthases. The synthesis of ATP by H+-ATP synthases proceeds without the formation of a phosphorylated enzyme intermediate, and involves co-operative interactions between the catalytic subunits. 相似文献
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