Participation of mast cells and its TLR2 and dectin-1 receptors in defense against C. albicans: phagocytosis and production/release of nitric oxide and hydrogen peroxide

Candida albicans (C. albicans) is a common fungus present in gastrointestinal tract mucosa including oral cavity, which may cause local or invasive candidiasis, especially in immunosuppression. The mechanisms of defense against this fungus may be triggered by the binding of the pattern recognition receptors TLR2 and dectin-1 to its ligands, such as phospholipomannan and -glucans found in the cell wall of C. albicans. Mast cells express these receptors on cell membrane and reside in the interfaces with the environment, and may be one of the first lines of defense. Their immune mechanisms include synthesis and secretion of mediators, antigen presentation, as well as phagocytic and microbicidal activities. These mechanisms can be triggered independently or cooperatively by TLR2 and dectin-1. Therefore, the aim of the study was to evaluate in vitro the phagocytosis, the generation of nitric oxide and hydrogen peroxide by mast cells challenged or not with C. albicans, and the involvement of TLR2 and dectin-1 receptors in these mechanisms. Bone marrow-derived mast cell (BMMCs) from wild type mice (BMMCs Wt) or TLR2-/- (BMMCs TLR2-/-) was challenge with C. albicans. Cells were also in vitro blocked with specific anti-dectin-1 antibodies (BMMCs BD-1 and BMMCs TLR2-/-BD-1). The mechanisms were analyzed using fluorescent phagocytosis assay, Griess colorimetric method and by DAF-FM diacetate, CellRox® Deep Reagent and Amplex® Red enzyme assays. Results were expressed by percentage, mean and standard deviations obtained from the least three independent experiments. Statistic was performed using factorial ANOVA and Fischer. Among BMMCs Wt, there was higher phagocytosis rate associated with increased intracellular NO production at 60 minutes, comparing to other periods. The extracellular release of NO was higher at 120 minutes comparing to other periods. The number of phagocytized yeasts increased over time, however with significant difference only among the 30 and 120 minutes. Among BMMCs TLR2-/-, there was higher number of phagocytized yeast at 60 minutes compared to 120 minutes. However, the extracellular release of NO at 60 minutes was lower comparing to other periods. In comparison to BMMCs Wt, the BMMCs TLR2-/- showed a reduction in the phagocytosis rate, at 60 minutes, lower release of extracellular NO, at all times, and fewer numbers of phagocytized yeast at 120 minutes. Compared to BMMCs Wt, the BMMCs BD-1 and BMMCs TLR2-/-/BD-1 showed a reduction in the phagocytosis rate with lower intracellular NO production, at 60 minutes, and decrease of extracellular NO release, at 60 and 120 minutes. Comparing to BMMCs Wt, the BMMCs TLR2-/-/BD-1 showed increased production of intracellular NO, after 30 minutes, and fewer phagocytized yeast, at 60 and 120 minutes. Therefore, we conclude that mast cells are able to phagocytose C. albicans with concomitant production of the potentially microbicidal substances. Also conclude that these mechanisms involve the fungal recognition via TLR2 and dectin-1, especially by means of synergistic way. (AU)