ABSTRACT
Asparaginyl endopeptidase (AE) of Schistosoma mansoni (Sm32), also known as legumain, is a cysteine protease indirectly involved in the digestion of hemoglobin of Schistosoma sp. in the gastrodermis, being a vaccine candidate against this trematode and a potential drug target. This study presents a model for the three-dimensional structure of Sm32 determined by means of homology modeling and a molecular dynamics simulation with explicit solvent refinement. The structure proved to be consistent with other AEs of known crystal structures described in their proenzyme form, revealing a catalytic domain that has a caspase-like overall structure and a C-terminal prodomain that adopts a death-domain-like architecture. We identified amino acid mutations in the ßIV strand, differences in the active site and in the surface electrostatic potentials between Sm32 and its homologous proteins of mouse and human. Additionally, amino acid changes in the activation peptide (AP) of the S. mansoni protein were determined. Our results strongly suggest that Sm32 can be exploited as a potential target for drug design and for the development of biomarkers used in diagnosis and in novel vaccines for the control of parasitic infection, opening the perspective of medicinal chemistry developments.
