Potential antichagasic: the rational pursuit of compounds with selective action by cruzain

Chagas \' disease, a parasitosis caused by Trypanosoma cruzi, is an endemic disease that affects most part of Latin America. About 18 million people are infected by the parasite and around 21 thousand deaths are related to Chagas\' disease each year. Nowadays, 100 millions of people are estimated to be under the risk of infection in the 18 countries of the endemic areas. The therapeutic armamentarium available against Chagas\' disease is comprehended by only two drugs, nifurtmox and benznidazol, which are not effective in the chronic phase of the disease. Cruza in, the most abundant cysteine protease of the parasite, is essential in all stages of the cellular development of the parasite and responsible for invasion and modification of the immunologic system of the human host. Besides, it has differences relatively to those enzymes in the humans. So, it is an excellent biochemical target for searching new agents against T. cruzi. This said and in the view of cruzain specificity, understanding the mechanism of interaction of compounds with this enzyme is considered very interesting in order to design derivatives with potential anti-Chagas\'disease. The present work had the objective of elucidating the affinity of different classes \'of compounds to the enzyme, in the rational search for new trypanomicides. So, mutual peptide prodrugs, derived from primaquine (PQ) and nitrofurazone (NF), previously synthesized, and designed double peptide prodrugs of hydroxymethylnitrofurazone (NFOH), which synthesis has been studied, were submitted to molecular modeling and docking studies. The peptides were chosen based on specific cleavage by cruzain. The interaction with the enzyme and the drug as well as the active compound release mechanism from those derivatives were evaluated. The studies have indicated the dipeptide LysArg as the best carrier to be used in the design of new prodrugs, corroborating what had been earlier observed in the tests of T. cruzi infected cell culture. Based on the possibility of a second mechanism of action through the interaction between cruzain Cys 25 and the semicarbazone group, found in NF and NFOH, analogs of this c/ass of compounds were designed, and synthesized, using classic bioisosterism between sultur and oxygen. Molecular modeling and docking studies have indicated also the participation of this mechanism in the activity of the nitro-heterocyclic compounds referred. All bioisosters showed to inhibit cruzain IC50 between 2.71 µM and 22.83 µM -- also evidencing this mechanism of action. With the purpose of studying the influence of (thio)semicarbazone group present in the synthesized bioisoster derivatives, 20 and 3D QSAR have been developed for a series of compounds reported in the literature, leading to robust and high- preditive leveI models, confirming their action in cruzaine. Those groups might be used in the design of new trypanomicides. Complementing the rational search for new antichagasic compounds, a virtual screening of new ligands, using the structure-based drug design (SBDD) was developed based on a specific pharmacophore model obtained for cruzain. This study have provided the suggestion of twenty compounds from the CHEMDIV data bank with possible inhibitory activity in cruzain. Based on the results obtained, the conclusion is that the studies herein developed with prodrugs and analogs through rational drug design lead to important data towards the research of new candidates as new antichagasic drugs. (AU)