The NADPH oxidase of professional phagocytes--prototype of the NOX electron transport chain systems.

The NADPH oxidase is an electron transport chain in "professional" phagocytic cells that transfers electrons from NADPH in the cytoplasm, across the wall of the phagocytic vacuole, to form superoxide. The electron transporting flavocytochrome b is activated by the integrated function of four cytoplasmic proteins. The antimicrobial function of this system involves pumping K+ into the vacuole through BKCa channels, the effect of which is to elevate the vacuolar pH and activate neutral proteases. A number of homologous systems have been discovered in plants and lower animals as well as in man. Their function remains to be established.

NCB5OR is a novel soluble NAD(P)H reductase localized in the endoplasmic reticulum.

The NAD(P)H cytochrome b5 oxidoreductase, Ncb5or (previously named b5+b5R), is widely expressed in human tissues and broadly distributed among the animal kingdom. NCB5OR is the first example of an animal flavohemoprotein containing cytochrome b5 and chrome b5 reductase cytodomains. We initially reported human NCB5OR to be a 487-residue soluble protein that reduces cytochrome c, methemoglobin, ferricyanide, and molecular oxygen in vitro. Bioinformatic analysis of genomic sequences suggested the presence of an upstream start codon. We confirm that endogenous NCB5OR indeed has additional NH2-terminal residues. By performing fractionation of subcellular organelles and confocal microscopy, we show that NCB5OR colocalizes with calreticulin, a marker for endoplasmic reticulum. Recombinant NCB5OR is soluble and has stoichiometric amounts of heme and flavin adenine dinucleotide. Resonance Raman spectroscopy of NCB5OR presents typical signatures of a six-coordinate low-spin heme similar to those found in other cytochrome b5 proteins. Kinetic measurements showed that full-length and truncated NCB5OR reduce cytochrome c actively in vitro. However, both full-length and truncated NCB5OR produce superoxide from oxygen with slow turnover rates: kcat = approximately 0.05 and approximately 1 s(-1), respectively. The redox potential at the heme center of NCB5OR is -108 mV, as determined by potentiometric titrations. Taken together, these data suggest that endogenous NCB5OR is a soluble NAD(P)H reductase preferentially reducing substrate(s) rather than transferring electrons to molecular oxygen and therefore not an NAD(P)H oxidase for superoxide production. The subcellular localization and redox properties of NCB5OR provide important insights into the biology of NCB5OR and the phenotype of the Ncb5or-null mouse.

New equations for redox and nano-signal transduction.

Cells maintain redox potentials (Eh) in intracellular compartments, sometimes referred to as redox environments. These potentials are often very reducing, for example in the cytoplasm, but throughout the cell different potentials are maintained, commensurate with the functionality of that particular part of the cell. Furthermore, within a simple cellular compartment, "hot-spots" of redox poise may be maintained. However, despite this complexity, the quantification of such redox potentials has been attempted, and there is indeed a need to accurately assess such potentials, and to monitor how they might change with time. Changes in intracellular potentials may control the oxidation or reduction of protein residues, such as cysteine, which would alter the conformation of those proteins and so modulate their function. Although there are several methods for estimating the intracellular redox potential, the most accessible technique is the measurement of intracellular concentrations of GSH and GSSG, and the calculation of Eh using the Nernst equation. However, using this equation shows that the Eh imposed by the glutathione couple is dependent on the total concentration of glutathione present, and therefore values of Eh obtained may be erroneous. Here, we suggest new equations that can be used to calculate the redox environments of cells.

Chronic granulomatous disease.

Chronic granulomatous disease (CGD) is a primary immunodeficiency that affects phagocytes of the innate immune system and is characterized by a greatly increased susceptibility to severe bacterial and fungal infections. CGD is caused by mutations in any one of four genes that encode the subunits of phagocyte NADPH oxidase, the enzyme that generates microbicidal (and pro-inflammatory) oxygen radicals. Of the 410 CGD mutations identified, 95% cause the complete or partial loss of protein and provide little information regarding the relationship between protein structure and function. The remaining 5%, however, result in normal levels of inactive protein and many have provided valuable insights into the function of affected subunits and their roles in oxidase regulation and catalysis. Moreover, recent CGD studies have revealed that recombination events between the p47-phox gene (NCF-1) and its pseudogenes not only cause the absence of p47-phox, but also predict the generation of a novel fusion protein.

Characterization of nitric oxide consumption pathways by normal, chronic granulomatous disease and myeloperoxidase-deficient human neutrophils.

The detailed mechanisms by which acutely activated leukocytes metabolize NO and regulate its bioactivity are unknown. Therefore, healthy, chronic granulomatous disease (CGD) or myeloperoxidase (MPO)-deficient human neutrophils were examined for their ability to consume NO and attenuate its signaling. fMLP or PMA activation of healthy neutrophils caused NO consumption that was fully blocked by NADPH oxidase inhibition, and was absent in CGD neutrophils. Studies using MPO-deficient neutrophils, enzyme inhibitors, and reconstituted NADPH oxidase ruled out additional potential NO-consuming pathways, including Fenton chemistry, PGH synthase, lipoxygenase, or MPO. In particular, the inability of MPO to consume NO resulted from lack of H(2)O(2) substrate since all superoxide (O(2)(-.) reacted to form peroxynitrite. For healthy or MPO-deficient cells, NO consumption rates were 2- to 4-fold greater than O(2)(-.) generation, significantly faster than expected from 1:1 termination of NO with O(2)(-.). Finally, fMLP or PMA-stimulated NO consumption fully blocked NO-dependent neutrophil cGMP synthesis. These data reveal NADPH oxidase as the central regulator of NO signaling in human leukocytes. In addition, they demonstrate an important functional difference between CGD and either normal or MPO-deficient human neutrophils, namely their inability to metabolize NO which will alter their ability to adhere and migrate in vivo.

Nitrolinoleate inhibits superoxide generation, degranulation, and integrin expression by human neutrophils: novel antiinflammatory properties of nitric oxide-derived reactive species in vascular cells.

Nitration of unsaturated fatty acids such as linoleate by NO-derived reactive species forms novel derivatives (including nitrolinoleate [LNO2]) that can stimulate smooth muscle relaxation and block platelet activation by either NO/cGMP or cAMP-dependent mechanisms. Here, LNO2 was observed to inhibit human neutrophil function. LNO2, but not linoleic acid or the nitrated amino acid 3-nitrotyrosine, dose-dependently (0.2 to 1 micromol/L) inhibited superoxide (O2*-) generation, Ca2+ influx, elastase release, and CD11b expression in response to either phorbol 12-myristate 13-acetate or N-formyl-Met-Leu-Phe. LNO2 did not elevate cGMP, and inhibition of guanylate cyclase by 1H-[1,2,4]oxadiazole[4,3-a]quinoxalin-1-one did not restore neutrophil responses, ruling out a role for NO. In contrast, LNO2 caused elevations in intracellular cAMP in the presence and absence of phosphodiesterase inhibition, suggesting activation of adenylate cyclase. Compared with phorbol 12-myristate 13-acetate-activated neutrophils, N-formyl-Met-Leu-Phe-activated neutrophils were more susceptible to the inhibitory effects of LNO2, indicating that LNO2 may inhibit signaling both upstream and downstream of protein kinase C. These data suggest novel signaling actions for LNO2 in mediating its potent inhibitory actions. Thus, nitration of lipids by NO-derived reactive species yields products with antiinflammatory properties, revealing a novel mechanism by which NO-derived nitrated biomolecules can influence the progression of vascular disease.

Identification of a novel NCF-1 (p47-phox) pseudogene not containing the signature GT deletion: significance for A47 degrees chronic granulomatous disease carrier detection.

The p47-phox gene, NCF-1, has 2 nearly identical pseudogenes (psiNCF-1) in proximity at chromosomal locus 7q11.23. A dinucleotide deletion (DeltaGT) at the beginning of exon 2 that leads to a frameshift and premature stop codon is considered the signature sequence of the pseudogenes. It is also the most prevalent mutation in p47-phox-deficient (A47 degrees ) chronic granulomatous disease (CGD) as a result of the insertion of a DeltaGT-containing fragment of pseudogene into NCF-1. Extending our study of the relationship between NCF-1 and psiNCF-1 to 53 unaffected control individuals, we found that although in most (n = 44), the ratio of pseudogene (DeltaGT) to functional gene (GTGT) sequence in amplicons spanning exon 2 was 2:1, as previously observed, surprisingly, in 7 persons the ratio was 1:1, and in 2 persons the ratio was 1:2. The lowered ratios are explained by the presence, in a heterozygous or homozygous state, respectively, of a pseudogene that contains GTGT rather than DeltaGT. It is possible that this pseudogene has not undergone deletion of GT, but more likely, based on analysis of additional NCF-1/psiNCF-1 markers, it represents the previously unidentified product of the reciprocal crossover of DNA fragments between the functional gene and one of its pseudogenes. The mutated NCF-1 resulting from this event is the predominant A47 degrees CGD allele. The existence of 2 extended haplotypes encompassing NCF-1/psiNCF-1 further complicates the detection of A47 degrees CGD carriers. Although most have a DeltaGT/GTGT ratio of 5:1, some have a ratio of 2:1 and are indistinguishable by this means from unaffected individuals.

Assembly of the neutrophil respiratory burst oxidase: a direct interaction between p67PHOX and cytochrome b558 II.

Activation of the phagocyte NADPH oxidase complex requires assembly of the cytosolic factors p47PHOX, p67PHOX, p40PHOX, and Rac with the membrane-bound cytochrome b558. We recently established a direct interaction between p67PHOX and cytochrome b558. In the present study, we show that removal of the C-terminal domain of p67PHOX increased its binding to cytochrome b558. Whereas phosphorylated p40PHOX alone did not bind to cytochrome b558, phosphorylated p47PHOX did, and, moreover, it allowed the binding of p40PHOX to the cytochrome. Furthermore, both increased the binding of p67PHOX) to the cytochrome. Phosphorylated p47PHOX thus appears to increase the binding of p67(PHOX) to cytochrome b558 by serving as an adapter, bringing p67PHOX into proximity with cytochrome b558, whereas phosphorylated p40(PHOX) may increase the binding by inducing a conformational change that allows p67PHOX to interact fully with cytochrome b558.