Click chemistry inspired facile one-pot synthesis of mannosyl triazoles and their hemagglutination inhibitory properties: The effect of alkyl chain spacer length between the triazole and phthalimide moieties in the aglycone backbone

A phthalimide-triazole derivative obtained by click chemistry exhibits trypanocidal activity, induces autophagy and ameliorates Trypanosoma cruzi infection

Chagas disease (CD), caused by Trypanosoma cruzi, remains a leading cause of cardiomyopathy and heart failure in Latin America. Since the 1970s, benznidazole (BNZ) and nifurtimox (NFX) have been the only chemotherapeutic agents used to treat CD. However, their toxicity and low effectiveness in the chronic phase of the disease, make the development of more efficient chemotherapeutics imperative. Here, we investigated the effects of 1,2,3-triazole hybrids, synthesized via click chemistry, containing either phthalimide (FT1, FT2, FT3, FT4) or naphthoquinone (NT1) moieties on T. cruzi and their cytotoxicity on mammalian cells. NT1 and FT1 were the most effective against intracellular parasite with an IC50 = 31.1 and 189.2 µM, respectively. FT1-FT4 showed low cytotoxicity to mammalian cells (CC50 > 754 µM), while NT1 exhibited moderate toxicity (CC50 ≥ 96.1 µM). FT1 demonstrated the highest selectivity towards trypomastigotes and amastigotes with selectivity indexes (SeI) of 6.9 and 6.7, respectively. Ultrastructural analysis of trypomastigotes treated with FT1 revealed mitochondrial alterations, lipid accumulation and Golgi complex disorganization. FT1 also decreased the mitochondrial membrane potential, increased mitochondrial reactive oxygen species (ROS) production, and induced late apoptosis in trypomastigotes. In infected cardiac cells, FT1 treatment led to degradation of amastigotes and Golgi disruption. An increase in autophagosomes in treated host cells and their interaction with intracellular parasites suggest that FT1-induced host cell autophagy may play a role in mitigating the infection and protecting cardiac cells from its deleterious effects.

Design, synthesis, biological evaluation and docking study of some new aryl and heteroaryl thiomannosides as FimH antagonists

FimH is a mannose-recognizing lectin that is expressed by Escherichia coli guiding its ability to adhere and infect cells. It is involved in pathogenesis of urinary tract infections and Chron's disease. Several X-ray structure-guided ligand design studies were extensively utilized in the discovery and optimization of small molecule aryl mannoside FimH antagonists. These antagonists retain key specific interactions of the mannose scaffolds with the FimH carbohydrate recognition domains. Thiomannosides are attractive and stable scaffolds, and this work reports the synthesis of some of their new aryl and heteroaryl derivatives as FimH antagonists. FimH-competitive binding assays as well as biofilm inhibition of the new compounds (24-32) were determined in comparison with the reference n-heptyl α-d-mannopyranoside (HM). The affinity among these compounds was found to be governed by the structure of the aryl and heteroarylf aglycones. Two compounds 31 and 32 revealed higher activity than HM. Molecular docking and total hydrophobic to topological polar surface area ratio calculations attributed to explain the obtained biological results. Finally, the SAR study suggested that introducing an aryl or heteroaryl aglycone of sufficient hydrophobicity and of proper orientation within the tyrosine binding site considerably enhance binding affinity. The potent and synthetically feasible FimH antagonists described herein hold potential as leads for the development of sensors for detection of E. coli and treatment of its diseases.