Triazoles with inhibitory action on P2X7R impaired the acute inflammatory response in vivo and modulated the hemostatic balance in vitro and ex vivo.

OBJECTIVE: The present study aimed to investigate five triazole compounds as P2X7R inhibitors and evaluate their ability to reduce acute inflammation in vivo. MATERIAL: The synthetic compounds were labeled 5e, 8h, 9i, 11, and 12. TREATMENT: We administered 500 ng/kg triazole analogs in vivo, (1-10 µM) in vitro, and 1000 mg/kg for toxicological assays. METHODS: For this, we used in vitro experiments, such as platelet aggregation, in vivo experiments of paw edema and peritonitis in mice, and in silico experiments. RESULTS: The tested substances 5e, 8h, 9i, 11, and 12 produced a significant reduction in paw edema. Molecules 5e, 8h, 9i, 11, and 12 inhibited carrageenan-induced peritonitis. Substances 5e, 8h, 9i, 11, and 12 showed an anticoagulant effect, and 5e at a concentration of 10 µM acted as a procoagulant. All derivatives, except for 11, had pharmacokinetic, physicochemical, and toxicological properties suitable for substances that are candidates for new drugs. In addition, the ADMET risk assessment shows that derivatives 8h, 11, 5e, and 9i have high pharmacological potential. Finally, docking tests indicated that the derivatives have binding energies comparable to the reference antagonist with a competitive inhibition profile. CONCLUSIONS: Together, the results indicate that the molecules tested as antagonist drugs of P2X7R had anti-inflammatory action against the acute inflammatory response.

Plant natural products as source of new P2 receptors ligands.

In recent years, interest in the research of P2 receptor (P2R)-mediated responses has grown significantly due to the recognition of the involvement of these receptors in various physiological and pathological processes. Despite all the progress made in the functional characterization of P2Rs, purinergic signaling research is still limited by the lack of selective or efficient ligands for different receptor subtypes. In this sense, several molecules have been tested towards these receptors as agonists or antagonists. Historically, natural products have always been sources of new bioactive substances for diverse purposes. However, compared to synthetic molecules, the number of natural products assessed for P2R ligands is still low. In this review, we present examples of studies that demonstrated plant natural products acting directly on P2R and modulating their functionality. In some cases, we highlight that the pharmacological activity previously described for the original organism could be correlated to an agonist or antagonist activity of a specific natural product on these receptors. These examples reinforce the need for more studies to investigate the pharmacological potential of new or known natural compounds targeting P2 receptors.