Entamoeba histolytica is a cosmopolitan protozoan parasite that can produce infections in the intestine and some organs (liver, lungs, and brain), with worldwide prevalence. There are treatments against E. histolytica (antiparasitics), but as the drugs used in these treatments have presented some type of resistance and/or side effects, there are cases with complications of this disease. Therefore, it is necessary to develop new drugs aimed at a specific therapeutic target against this parasite. Here, we used the compound 5,5′‐[(4‐nitrophenyl)methylene]bis(6‐hydroxy‐2‐mercapto‐3‐methyl‐4(3H)‐pyrimidinone) in the patenting process (called D4). D4 has a reported specific use against a glycolytic enzyme, the triosephosphate isomerase of Trichomonas vaginalis (TvTIM). We determined that D4 has an amoebicidal effect in in vitro cultures, with an IC50 value of 18.5 µM, and we proposed a specific site of interaction (Lys77, His110, Gln115, and Glu118) in the triosephosphate isomerase of E. histolytica (EhTIM). Furthermore, compound D4 has favorable experimental and theoretical toxicity results. Therefore, D4 should be further investigated as a potential drug against E. histolytica.
In the pharmaceutical industry, the development of selective drugs to an enzyme or the repositioning of commercial drugs, today, is booming. The glycolytic enzyme triosephosphate isomerase (TIM) has been used as a therapeutic target for the development of new drugs against various pathogenic organ-isms. Therefore, saving resources in the development of new drugs, by directing the interaction of pharmacological compounds to an interaction site with a high probability to be selective, represents an opportunity for researchers.In this study, we propose a potential site as a therapeutic target against TIM, for the development of drugs with probability to be safe in humans.We propose that K214, which is in the position near the sequence Y209, G210, G211, S212, V213, is indispensable for interaction with the tested compounds to interact near the active site of TIMs. In addition, the TIMs that present F46, achieve a better interaction and a greater effect on the decrease in the enzymatic activity of the compounds tested. Therefore, we determine compounds with this effect and from its derivatives could be used in other TIMs. To contribute to the development of new selective drugs against bacteria, parasites or other organisms that nowadays have non-specific conventional treatments.
Hypertension (HTN) causes end-organ damage and is a major cause of morbidity and mortality globally. Recent studies suggested blood cells participate in the maintenance of HTN. Platelets—anucleated cell fragments derived from megakaryocytes—exert diverse functions, including their well-characterized role in the formation of hemostatic clots. However, platelets from patients with HTN exhibit altered membrane lipid and protein compositions that impact platelet function and lead to formation of aggregates and vascular obstructions. Here, for the first time, we have identified, by proteomic analyses, the most relevant 11 proteins that show the greatest difference in their expression in platelets derived from patients with HTN, in comparison with those from normotensive individuals. These proteins are involved in cytoskeletal organization and the coagulation cascade that contributes to platelet activation, release of granule contents, and aggregation, which culminate in thrombus formation. These results have important implications in our understanding of the molecular mechanisms associated with the development of HTN, and in consequence, the development of new strategies to counteract the cardiovascular disorders associated with constitutive activation of platelets in HTN.
Mucosal innate immunity functions as the first line of defense against invading pathogens. Members of the IL-1 family are key cytokines upregulated in the inflamed mucosa. Inflammatory cytokines are regulated by limiting their function and availability through their activation and secretion mechanisms. IL-1 cytokines secretion is affected by the lack of a signal peptide on their sequence, which prevents them from accessing the conventional protein secretion pathway; thus, they use unconventional protein secretion pathways. Here we show in mouse macrophages that LPS/ATP stimulation induces cytokine relocalization to the plasma membrane, and conventional secretion blockade using monensin or Brefeldin A triggers no IL-36γ accumulation within the cell. In silico modeling indicates IL-36γ can pass through both the P2X7R and Gasdermin D pores, and both IL-36γ, P2X7R and Gasdermin D mRNA are upregulated in inflammation; further, experimental blockade of these receptors’ limits IL-36γ release. Our results demonstrate that IL-36γ is secreted mainly by an unconventional pathway through membrane pores formed by P2X7R and Gasdermin D.
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