Abstract
AbstractFungal infection is an important public health problem afflicting more than a billion people worldwide. Mycoses are especially important in Latin America, and in Brazil in particular. Paracoccidioides is the genus of fungi responsible for paracoccidioidomycosis comprising two species, P. brasiliensis and P. lutzii. The lungs are the primary infection site, but oral mucosa and airways can also be affected. The glycoprotein gp43 is involved in fungi adhesion to epithelial cells and is the most studied protein of P. brasiliensis. Seminal work identified a specific stretch of 15 amino acids that spans the region 181-195 (called P10) as an important epitope of gp43, being recognized by T lymphocytes in peripheral blood mononuclear cells of mice and humans and is envisioned as a potential vaccine component. Here, we show by using thioflavin T (ThT), transmission electron microscopy and other methods that synthetic P10 forms typical amyloid aggregates in solution in very short times, a property that could hamper vaccine development. In silico, aggregation analysis reveals several aggregation-prone regions (APR) in the P10 sequence that are capable of forming amyloid cores with steric zipper architecture. Seeds of P10 obtained by fibril mechanical fragmentation were able to induce the aggregation of P4 but not P23, as evidenced by ThT binding and mass spectrometry. These two peptides, also derived from gp43, are potent modulators of local and systemic inflammation. In-silico proteolysis studies with gp43 revealed that aggregation-prone, P10-like peptides could be generated by the action of several proteases such as proteinase K, trypsin and pepsin, which suggests that P10 could be formed upon gp43 digestion in a physiological condition. Considering our data in the context of a potential vaccine development, we redesigned the sequence of the P10 peptide, maintaining the antigenic region (HTLAIR), but drastically reducing its aggregation propensity.
Publisher
Cold Spring Harbor Laboratory