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Exploration of Alternative Scaffolds for P2Y<sub>14</sub> Receptor Antagonists Containing a Biaryl Core

Kwan‐Young Jung, Jinha Yu, Zhiwei Wen, Veronica Salmaso, Tadeusz Karcz, Ngan B. Phung, Zhoumou Chen, Sierra Duca, John M. Bennett, Steven Dudas, Daniela Salvemini, Zhan‐Guo Gao, Donald N. Cook, Kenneth A. Jacobson

2020Journal of Medicinal Chemistry35 citationsDOIOpen Access PDF

Abstract

Various heteroaryl and bicyclo-aliphatic analogues of zwitterionic biaryl P2Y14 receptor (P2Y14R) antagonists were synthesized, and affinity was measured in P2Y14R-expressing Chinese hamster ovary cells by flow cytometry. Given this series’ low water solubility, various polyethylene glycol derivatives of the distally binding piperidin-4-yl moiety of moderate affinity were synthesized. Rotation of previously identified 1,2,3-triazole attached to the central m-benzoic acid core (25) provided moderate affinity but not indole and benzimidazole substitution of the aryl-triazole. The corresponding P2Y14R region is predicted by homology modeling as a deep, sterically limited hydrophobic pocket, with the outward pointing piperidine moiety being the most flexible. Bicyclic-substituted piperidine ring derivatives of naphthalene antagonist 1, e.g., quinuclidine 17 (MRS4608, IC50 ≈ 20 nM at hP2Y14R/mP2Y14R), or of triazole 2, preserved affinity. Potent antagonists 1, 7a, 17, and 23 (10 mg/kg) protected in an ovalbumin/Aspergillus mouse asthma model, and PEG conjugate 12 reduced chronic pain. Thus, we expanded P2Y14R antagonist structure–activity relationship, introducing diverse physical–chemical properties.

Topics & Concepts

ChemistryStereochemistryBicyclic moleculeMoietyQuinuclidinePiperidineLinkerSteric effectsBioisostereChemical synthesisCombinatorial chemistryBiochemistryIn vitroOperating systemComputer scienceAdenosine and Purinergic SignalingSynthesis and Biological EvaluationPharmacological Receptor Mechanisms and Effects