Ángel L. Rosas

Melanin and virulence in Cryptococcus neoformans.

Melanin synthesis has been associated with virulence for the human pathogenic fungus Cryptococcus neoformans. Recent evidence indicates that C. neoformans cells synthesize melanin during infection and that this pigment protects the fungus against immune defense mechanisms.

Synthesis of Polymerized Melanin by Cryptococcus neoformans in Infected Rodents

ABSTRACT The ability of Cryptococcus neoformans to synthesize polymerized melanin in vitro has been associated with virulence, but it is unclear whether this fungus synthesizes polymerized melanin during infection. To study this question, we used two approaches: one involved the generation of monoclonal antibodies (MAbs) to melanin for use in immunohistochemical studies of C. neoformans-infected rodents, and the other sought to isolate fungal melanin from infected tissues. Digestion of in vitro-melanized C. neoformanscells with proteases, denaturant, and hot concentrated acid yields melanin particles that retain the shape of fungal cells and are therefore called melanin ghosts. BALB/c mice were immunized with melanin ghosts, and two immunoglobulin M MAbs to melanin were generated from the spleen of one mouse. Immunofluorescence analyses of lung and brain tissues of rodents infected with wild-type melanin-producing (Mel+) C. neoformans strains demonstrated binding of the MAbs to the fungal cell wall. No binding was observed when infections were performed with mutant albino (Mel−)C. neoformans strains. Particles with striking similarity to melanin ghosts were recovered after digestion of lung and brain tissues from Mel+C. neoformans-infected rodents and were reactive with the MAbs to melanin. No particles were recovered from tissues infected with Mel−C. neoformans. A Mel+C. neoformans strain grown on lung or brain homogenate agar became lightly pigmented and also yielded particles similar to melanin ghosts upon digestion, providing additional evidence that lung and brain tissues contain substrate for C. neoformans melanization. These results demonstrate that C. neoformans synthesizes polymerized melanin during infection, which has important implications for pathogenesis and antifungal drug development.

Passive Immunization with Melanin-Binding Monoclonal Antibodies Prolongs Survival of Mice with Lethal Cryptococcus neoformans Infection

ABSTRACT Passive immunization with monoclonal antibodies (MAbs) to melanin prolonged the survival of and reduced the fungal burden inCryptococcus neoformans-infected mice in comparison to controls. MAbs to melanin reduced the growth rate of in vitro-melanizedC. neoformans cells, suggesting a new mechanism of antibody-mediated protection.

Isolation and serological analyses of fungal melanins.

Melanins are notoriously difficult to work with because of their unique physical and chemical properties. The study of melanins is hampered by the scarcity of melanin-specific reagents and serological techniques. In this study we describe modifications to the standard method for the isolation of melanins from in vitro-melanized fungal cells and detail the optimization of serological techniques for the study of melanin compounds. The isolation procedure involves the digestion of melanized cells with a combination of proteolytic and glycolytic enzymes, denaturant, organic extractions, and boiling in 6.0 M HCl. Elemental quantitative analyses suggest that this procedure does not significantly affect the relative elemental composition of melanins. For the serological assays, our goal was to achieve a homogenous distribution of melanin particles on a solid support to maximize their recognition by melanin-binding antibodies. The results from enzyme-linked immunosorbent assays (ELISAs) demonstrate that melanins, in general, disperse more efficiently on, and adhere better to, medium-binding polystyrene surfaces, especially in the presence of trace amounts of salt. Blocking the melanin-coated ELISA plates with the commercially available SuperBlock((R)) Blocking Buffer for 4 h was more efficient at reducing non-specific binding of a negative control monoclonal antibody (mAb) compared to blocking with 2% bovine serum albumin (BSA) and 5% milk. Increasing the ionic strength of the antibody solutions reduced binding to the melanins, indicating that binding is in part mediated by electrostatic interactions. These conditions were also applied to immunofluorescence (IF) analyses of melanins, and the results were consistent with those obtained by ELISA.

Melanization decreases the susceptibility of Cryptococcus neoformans to enzymatic degradation

Cryptococcus neoformans is a free-living fungus that is primarily found in soils contaminated with avian excreta. Recent studies have shown that C. neoformans can synthesize melanins or melanin-like compounds in avian excreta. Melanization has been associated with protection of C. neoformans against harsh environmental conditions, such as ultraviolet radiation and extremes of temperature. In this study we examined whether melanization can protect C. neoformans against enzymatic degradation. Our results demonstrated that in vitro melanization decreases the susceptibility of C. neoformans to hydrolytic enzymes. This suggests a role for melanin in protection of C. neoformans against enzymatic degradation by antagonistic microbes in the environment.

Activation of the Alternative Complement Pathway by Fungal Melanins

ABSTRACT Melanins are complex biological pigments formed by the oxidative polymerization of phenolic and/or indolic compounds. These pigments have been implicated in the pathogenesis of some microbial infections, malignancies, degenerative disorders, and autoimmune diseases. Recent studies have demonstrated that melanins have antigenic and anti-inflammatory properties. These findings led us to further explore the interaction of melanins with the immune system. Melanin particles (“ghosts”) were isolated from in vitro-melanized Cryptococcus neoformans cells and Aspergillus niger conidia and then incubated in normal human serum containing 125I-labeled complement C3. The results demonstrated deposition of C3 fragments onto the melanin ghosts as early as 1 min after incubation, with maximum deposition occurring after 12 min for C. neoformans-derived melanin ghosts and after 25 min for A. niger-derived melanin ghosts. The blocking of classical pathway activation did not affect the kinetics or total deposition of C3 onto the melanin ghosts, indicating that melanins activate complement through the alternative pathway. Immunofluorescence analysis of lungs from BALB/c mice injected intratracheally with C. neoformans-derived melanin ghosts demonstrated deposition of C3 fragments onto the ghosts. Small granulomas were also observed surrounding the ghosts. However, melanization of the C. neoformans cell wall did not alter the kinetics or total deposition of C3 fragments onto the fungal cells. The finding that melanin surfaces can activate the complement system suggests a potential mechanism for the pathogenesis of some degenerative and/or autoimmune processes that involve melanized cells as well as another potential role for melanin in the virulence of melanin-producing microorganisms.