Abstract
Paracoccin (PCN) is a bifunctional protein primarily present in the cell wall of Paracoccidioides brasiliensis, a human pathogenic dimorphic fungus. PCN has one chitinase region and four potential lectin sites and acts as both a fungal virulence factor and an immunomodulator of the host response. The PCN activity on fungal virulence, mediated by the chitinase site, was discovered by infecting mice with yeast overexpressing PCN (PCN-ov). PCN-ov are characterized by increased chitin hydrolysis, a narrow cell wall, and augmented resistance to phagocytes' fungicidal activity. Compared to wild-type (wt) yeast, infection with PCN-ov yeast causes a more severe disease, which is attributed to the increased PCN chitinase activity. In turn, immunomodulation of the host response was demonstrated by injecting, subcutaneously, recombinant PCN in mice infected with wt-P. brasiliensis. Through its carbohydrate binding site, the injected recombinant PCN interacts with Toll-like receptor 2 (TLR2) and Toll-like receptor 4 (TLR4) N-glycans on macrophages, triggers M1 polarization, and stimulates protective Th1 immunity against the fungus. The PCN-treatment of wt yeast-infected mice results in mild paracoccidioidomycosis. Therefore, PCN paradoxically influences the course of murine paracoccidioidomycosis. The disease is severe when caused by yeast that overexpress endogenous PCN, which exerts a robust local chitinase activity, followed by architectural changes of the cell wall and release of low size chito-oligomers. However, the disease is mild when exogenous PCN is injected, which recognizes N-glycans on systemic macrophages resulting in immunomodulation.
Highlights
Fungal chitinases (EC 3.2.1.14) hydrolyse chitin, a β-(1,4)-N-acetyl D-glucosamine homopolymer that is a primary constituent of the fungi cell wall (Puccia et al, 2011)
Since PCN activity depends on the recognition of N-glycans linked to Toll-like receptor 2 (TLR2) and Toll-like receptor 4 (TLR4) (Alegre-Maller et al, 2014), we investigated whether the deduced protein primary structure contained potential carbohydrate-binding sites
RECOMBINANT PARACOCCIN INDUCES PROTECTIVE IMMUNITY AGAINST FUNGAL INFECTION. Because of their carbohydrate-binding sites, PCN interacts with GlcNAc monomer and homopolymers (Ganiko et al, FIGURE 1 | Identification of catalytic and potential carbohydrate-binding regions in paracoccin (PCN). (A) The PCN amino acid residue sequence (PADG_03,347) from P. brasiliensis used in protein domain analyzes
Summary
Fungal chitinases (EC 3.2.1.14) hydrolyse chitin, a β-(1,4)-N-acetyl D-glucosamine homopolymer that is a primary constituent of the fungi cell wall (Puccia et al, 2011). We identified and characterized a P. brasiliensis protein, paracoccin (PCN), which has both lectin (Coltri et al, 2006; Ganiko et al, 2007) and chitinase (dos Reis Almeida et al, 2010) properties. Soluble recombinant PCN, administered to P. brasiliensis infected hosts, acts as an immunomodulatory agent that favors protection against the fungus (Alegre-Maller et al, 2014; Alegre et al, 2014). This article describes the structural organization of the PCN catalytic and putative carbohydrate-binding regions and the paradoxical effects of each type of region, acting as a P. brasiliensis virulence factor and an immunomodulatory agent that induces protection against PCM
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