SummaryMany microbes are surrounded by phagocytosisinhibiting capsules. We took advantage of the large size of the polysaccharide capsule of the pathogenic yeast Cryptococcus neoformans to examine capsular architecture and the relationship between molecular architecture and the interaction of the capsule with potentially opsonic serum proteins. Our experimental design used complementary approaches in which (i) assessment of permeability to macromolecules of different Stokes radii; (ii) determination of the binding of Fab fragments of anticapsular antibodies as a measure of matrix density; (iii) capsular deconstruction by treatment with dimethyl sulphoxide; and (iv) evaluation of capsule plasticity, were used to probe the molecular structure of the capsule. The results showed that the capsule is a matrix with a variable porosity that increases with distance from the cell wall. A high density of the matrix at the capsule interior prevents penetration of large macromolecules to sites near the cell wall. In contrast, the capsular edge that is the interface with phagocytes presents capsular polysaccharide in a very low density that exhibits considerable plasticity and permeability to macromolecules. Notably, the capsule of yeast cells harvested from infected tissue showed a greater matrix density than yeast cells grown in vitro under capsule induction conditions.
Spores are essential particles for the survival of many organisms, both prokaryotic and eukaryotic. Among the eukaryotes, fungi have developed spores with superior resistance and dispersal properties. For the human fungal pathogens, however, relatively little is known about the role that spores play in dispersal and infection. Here we present the purification and characterization of spores from the environmental fungus Cryptococcus neoformans. For the first time, we purified spores to homogeneity and assessed their morphological, stress resistance, and surface properties. We found that spores are morphologically distinct from yeast cells and are covered with a thick spore coat. Spores are also more resistant to environmental stresses than yeast cells and display a spore-specific configuration of polysaccharides on their surfaces. Surprisingly, we found that the surface of the spore reacts with antibodies to the polysaccharide glucuronoxylomannan, the most abundant component of the polysaccharide capsule required for C. neoformans virulence. We explored the role of capsule polysaccharide in spore development by assessing spore formation in a series of acapsular strains and determined that capsule biosynthesis genes are required for proper sexual development and normal spore formation. Our findings suggest that C. neoformans spores may have an adapted cell surface that facilitates persistence in harsh environments and ultimately allows them to infect mammalian hosts.
Cryptococcus neoformans is surrounded by an antiphagocytic polysaccharide capsule whose primary constituent is glucuronoxylomannan (GXM).
Mannan-binding lectin (MBL) is a component of the innate immune system. The goal of the present study was to evaluate binding of MBL to Candida albicans in vitro and in vivo and to assess the impact of MBL treatment on host resistance. The results showed a variable and often discontinuous pattern of binding to individual yeast cells. MBL bound to cells grown at 37 degrees C but not to cells grown at 23 degrees C. The putative MBL ligand was constitutively present on yeast cells grown at 23 degrees C, but the ligand was masked on such cells, such that MBL could not bind. C. albicans yeasts and hyphae in infected tissue bound MBL. Finally, parenteral administration of MBL increased resistance of mice to hematogenously disseminated candidiasis. These results suggest that MBL is an important component of innate resistance to candidiasis and that MBL therapy may be a means to prevent disseminated candidiasis in high-risk patients.
The polysaccharide capsule of Cryptococcus neoformans is a powerful activator of the complement system. The goal of the present study was to assess serum and cellular variables that influence the sites for C3 binding within the capsular matrix. Confocal microscopy using fluorophore-labeled polyclonal anti-C3 and anticapsular monoclonal antibodies and rosetting of fluorescent microspheres coated with anti-C3 were used to identify sites of C3 binding relative to the capsular edge. The results showed that the source of serum was a major variable influencing localization of C3. C3 bound at or very near the capsular edge in the case of human serum. C3 deposition was further from the capsule edge with guinea pig and rat sera; in the case of mouse serum, there was no binding of C3 in the outer region of the capsule. Addition of human C3 to mouse serum led to deposition of the C3 at the capsular edge, indicating that distinct properties of mouse and human C3 account for the differential localization of C3. Finally, the density of the capsular matrix was an important variable in determining sites for C3 deposition. Yeast cells with a high concentration of polysaccharide near the capsule edge supported deposition of mouse C3 at or near the capsular edge, whereas cells with a low matrix density showed deposition well beneath the edge. Taken together, these results indicate that the spatial deposition of C3 within the capsular matrix is a complex process that is influenced by the serum source and the density of the capsular matrix.
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