Aspergillus fumigatus LaeA-mediated phagocytosis is associated with a decreased hydrophobin layer

Abstract

Aspergillus fumigatus is the causal agent of the life-threatening disease invasive aspergillosis. A. fumigatus laeA deletants, aberrant in toxin biosynthesis and spore development, are decreased in virulence. Among other characteristics, the decreased virulence is associated with increased spore susceptibility to macrophage phagocytosis. Three characteristics, cell wall microbe-associated molecular patterns (MAMPs), secreted metabolites, and rodlet content, thought to be important in macrophage-Aspergillus spore interactions were examined. Flow cytometry analysis of wild-type and △laeA spores did not reveal any differences in surface-accessible MAMPs, including β-(1,3)-glucan, α-mannose, chitin, and other carbohydrate ligands. Blocking experiments with laminarin and mannan supported the conclusion that differences in cell wall carbohydrates were not responsible for enhanced △laeA spore phagocytosis. Aspergillus spores have been reported to secrete metabolites affecting phagocytosis. Neither spent culture exchange, transwell, nor coincubation internalization experiments supported a role for secreted metabolites in the differential uptake of wild-type and △laeA spores. However, sonication assays implicated a role for surface rodlet protein/hydrophobin (RodAp) in differential spore phagocytosis. A possible role of RodAp in enhanced △laeA spore uptake was further assessed by RodAp extraction and quantification, where wild-type spores were found to contain 60% more RodAp than △laeA spores. After removal of the surface rodlet layer, wild-type spores were phagocytosed at similar rates as △laeA spores. We conclude that increased uptake of △laeA resting spores is not associated with changes in secreted metabolite production of this mutant or surface carbohydrate availability but, rather, due to a decrease in the surface RodAp content of △laeA spores. We theorize that RodAp acts as an antiphagocytic molecule, possibly via physicochemical means and/or by impeding MAMP recognition by macrophage receptors. Copyright © 2010, American Society for Microbiology. All Rights Reserved.