Lactoperoxidase (LPO) is an enzyme with antimicrobial properties present in saliva, milk, tears, and airway secretions. Although the formation of microbicidal oxidants by LPO has been recognized for some time, the source of hydrogen peroxide (H2O2) for LPO-catalyzed reactions remains unknown. Reactive oxygen species produced by the phagocyte NADPH oxidase (phox) play a critical role in host defense against pathogens; however, analogous oxidant-generating systems in other tissues have not been associated with antimicrobial activity. Several homologues of gp91phox, the catalytic core of this enzyme, were described recently; dual oxidase (Duox)1/thyroid oxidase 1 and Duox2/thyroid oxidase 2 were identified in the thyroid gland and characterized as H2O2 donors for thyroxin biosynthesis. We examined Duox1 and Duox2 expression in secretory glands and on mucosal surfaces and give evidence for their presence and activity in salivary glands, rectum, trachea, and bronchium. Epithelial cells in salivary excretory ducts and rectal glands express Duox2, whereas tracheal and bronchial epithelial cells express Duox1. Furthermore, we detected Duox1-dependent H2O2 release by cultured human bronchial epithelial cells. Our observations suggest that Duox1 and Duox2 are novel H2O2 sources that can support LPO-mediated antimicrobial defense mechanisms on mucosal surfaces.
Superoxide production by phagocytes involves activation of a multi-component NADPH oxidase. Recently, several homologues of the catalytic component of the phagocyte oxidase, gp91 phox , were identified in various tissues. Here we describe two proteins, p41 and p51, with significant homology to two cytosolic components of the phagocytic oxidase, p47 phox and p67 phox . Like p47 phox , p41 contains an amino-terminal Phox homology domain, two SH3 domains, and a conserved carboxylterminal, proline-rich motif. Similarly, p51 is homologous to p67 phox , containing four amino-terminal tetratrico-peptide repeats, a conserved "activation domain" motif, a PB1 domain, and a carboxyl-terminal SH3 domain. The highest levels of p41 transcript are detected in the colon and in other gastrointestinal tissues that express Nox1, the predominant gp91 phox homologue in these tissues. In contrast, the p51 transcript showed a more widespread expression pattern, suggesting that it may support other tissue-specific oxidases. Mouse colon in situ hybridization detected both transcripts in the epithelial cells of colon crypts. Heterologous co-expression of p41 and p51 significantly enhances the superoxide-generating activity of Nox1-expressing cells; thus, p41 and p51 appear to be novel regulators of Nox1. These proteins also support the activity of gp91 phox , albeit at much lower levels than the cytosolic phox counterparts. Our results suggest colon epithelial cells contain a multi-component NAD(P)H oxidase with a molecular architecture similar to the phagocytic oxidase.
Reactive oxygen species (ROS) serve several physiological functions; in some settings they act in host defense, while in others they function in cellular signaling or in biosynthetic reactions. We studied the expression and function of a recently described source of ROS, NAD(P)H oxidase 1 or Nox1, which has been associated with cell proliferation. In situ hybridization in mouse colon revealed high Nox1 expression within the lower two-thirds of colon crypts, where epithelial cells undergo proliferation and differentiation. Human multitumor tissue array analysis confirmed colon-specific Nox1 expression, predominantly in differentiated epithelial tumors. Differentiation of Caco2 and HT29 cells with 1α,25-dihydroxyvitamin D3 or IFN-γ enhances Nox1 expression and decreases cell proliferation, suggesting that Nox1 does not function as a mitogenic oxidase in colon epithelial cells. Transduction with retrovirus encoding Nox1 restored activation and differentiation-dependent superoxide production in gp91phox-deficient PLB-985 cells, indicating close functional similarities to the phagocyte oxidase (phox). Furthermore, coexpression of cytosolic components, p47phox and p67phox, augments Nox1 activity in reconstituted K562 cells. Finally, Nox1 partially restores superoxide production in neutrophils differentiating ex vivo from gp91phox-deficient CD34+ peripheral blood-derived stem cells derived from patients with X-linked chronic granulomatous disease. These studies demonstrate a significant functional homology (cofactor-dependent and activation-regulated superoxide production) between Nox1 and its closest homologue, gp91phox, suggesting that targeted up-regulation of Nox1 expression in phagocytic cells could provide a novel approach in the molecular treatment of chronic granulomatous disease.
The dual oxidase-thiocyanate-lactoperoxidase (Duox/SCN−/LPO) system generates the microbicidal oxidant hypothiocyanite in the airway surface liquid by using LPO, thiocyanate, and Duox-derived hydrogen peroxide released from the apical surface of the airway epithelium. This system is effective against several microorganisms that infect airways of cystic fibrosis and other immunocompromised patients. We show herein that exposure of airway epithelial cells to Pseudomonas aeruginosa obtained from long-term cultures inhibits Duox1-dependent hydrogen peroxide release, suggesting that some microbial factor suppresses Duox activity. These inhibitory effects are not seen with the pyocyanin-deficient P. aeruginosa strain PA14 Phz1/2. We show that purified pyocyanin, a redox-active virulence factor produced by P. aeruginosa, inhibits human airway cell Duox activity by depleting intracellular stores of NADPH, as it generates intracellular superoxide. Long-term exposure of human airway (primary normal human bronchial and NCI-H292) cells to pyocyanin also blocks induction of Duox1 by Th2 cytokines (IL-4, IL-13), which was prevented by the antioxidants glutathione and N-acetylcysteine. Furthermore, we showed that low concentrations of pyocyanin blocked killing of wild-type P. aeruginosa by the Duox/SCN−/LPO system on primary normal human bronchial epithelial cells. Thus, pyocyanin can subvert Pseudomonas killing by the Duox-based system as it imposes oxidative stress on the host. We also show that lactoperoxidase can oxidize pyocyanin, thereby diminishing its cytotoxicity. These data establish a novel role for pyocyanin in the survival of P. aeruginosa in human airways through competitive redox-based reactions between the pathogen and host.
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