Candidacidal activity of myeloperoxidase: mechanisms of inhibitory influence of soluble cell wall mannan.
AUTOR(ES)
Wright, C D
RESUMO
We have previously demonstrated the ability of human neutrophil myeloperoxidase to bind to mannan isolated from Candida albicans. Mannan may therefore be a primary component of the yeast cell wall which provides for binding of myeloperoxidase, a requirement potentially important for the candidacidal activity of the enzyme. In this report, we describe experiments to consider the relationship of the mannan-binding activity of myeloperoxidase to its candidacidal activity and the possibility that free mannan may inhibit myeloperoxidase-mediated candidacidal activity. We observed that binding of myeloperoxidase to the target yeasts was required for killing of C. albicans. We also observed that addition of soluble mannan significantly reduced myeloperoxidase-mediated killing of the yeasts in a dose-dependent manner by antagonizing binding of myeloperoxidase. Soluble mannan was demonstrated to have a similar dose-dependent inhibitory effect on neutrophil-mediated candidacidal activity without influencing phagocytosis of the organism. On the basis of these observations, we speculate that mannan solubilized in plasma and tissue fluid may interfere with neutrophil-mediated host defense against Candida infection.
ACESSO AO ARTIGO
http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=264526Documentos Relacionados
- Candidacidal activity of myeloperoxidase: therapeutic influence of the enzyme in vivo.
- The fungicidal mechanisms of human monocytes. I. Evidence for myeloperoxidase-linked and myeloperoxidase-independent candidacidal mechanisms.
- Influence of yeast mannan on release of myeloperoxidase by human neutrophils: determination of structural features of mannan required for formation of myeloperoxidase-mannan-neutrophil complexes.
- Myeloperoxidase: a myeloid cell nuclear antigen with DNA-binding properties.
- Mechanism of the bactericidal action of myeloperoxidase: increased permeability of the Escherichia coli cell envelope.