Abstract
Cryptococcal meningoencephalitis (CME) is deadly. CME is responsible for 19% of deaths in AIDS patients, and its global mortality is greater than 60%. The recommended CME therapy requires amphotericin B (AmB), a fungicidal drug targeting fungal ergosterol. AmB also binds to the host's cholesterol and is highly toxic. Liposomal AmB (AmB-LLs), relative to deoxycholate-solubilized AmB, has lower toxicity and longer tissue retention, but it requires high doses for treatment and its efficacy in treating CME remains unsatisfactory. To improve the effectiveness of AmB-LLs, we previously developed DectiSomes-targeted AmB-LLs decorated with host dectins that recognize fungal polysaccharides. DectiSomes, relative to untargeted AmB-LLs, modestly improve efficacy against systemic cryptococcosis, in contrast to the drastic improvement observed in candidiasis or aspergillosis models. We speculated that limited tissue penetration of the regular-sized DectiSomes might have contributed to the modest improvement in treating systemic cryptococcosis. Here, we discovered that DectiSomes of a smaller size (~50 nm), compared with DectiSomes of the regular size (~100 nm) or untargeted AmB-LLs of either size, had a much better capability in reducing cryptococcal burden of various organs including the brain and in prolonging the survival of mice with systemic cryptococcosis. The performance of small DectiSomes was far superior to all other groups at two different doses of AmB tested. Furthermore, no kidney toxicity was observed in any of the treatment regimens tested. Taken together, our findings indicate that small DectiSomes can be a powerful antifungal delivery platform to drastically improve therapies against the deadly CME. IMPORTANCE: Systemic cryptococcosis is fatal even with antifungal interventions. The most effective drug against this disease is amphotericin B (AmB). However, AmB is highly toxic as it binds to fungal ergosterol and also mammalian cholesterol. Liposomal AmB was introduced to the clinic in 1990s because it showed reduced toxicity and longer retention in various organs. However, the dose of AmB required for treatment using liposomal formulation is high and the outcome is far from satisfactory. In our previous work, we generated DectiSomes, dectin-decorated liposomes loaded with AmB that more effectively deliver the drug to the pathogen and enhance antifungal efficacy. However, the improvement in treating systemic cryptococcosis, compared with candidiasis and aspergillosis, is modest. Here, we generated DectiSomes that are half their regular size to improve tissue penetration. We discovered that small DectiSomes are superior in reducing fungal burden in various organs including the brain and in prolonging animal survival.