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Bridged Piperidine Analogues of a High Affinity Naphthalene-Based P2Y<sub>14</sub>R Antagonist

Zhiwei Wen, Veronica Salmaso, Kwan‐Young Jung, Ngan B. Phung, Varun Gopinatth, Qasim Shah, Alexandra T. Patterson, John C.R. Randle, Zhoumou Chen, Daniela Salvemini, David I. Lieberman, Gregory S. Whitehead, Tadeusz Karcz, Donald N. Cook, Kenneth A. Jacobson

2022Journal of Medicinal Chemistry16 citationsDOIOpen Access PDF

Abstract

High affinity phenyl-piperidine P2Y14R antagonist 1 (PPTN) was modified with piperidine bridging moieties to probe receptor affinity and hydrophobicity. Various 2-azanorbornane, nortropane, isonortropane, isoquinuclidine, and ring-opened cyclopentylamino derivatives preserved human P2Y14R affinity (fluorescence binding assay), and their pharmacophoric overlay was compared. Enantiomeric 2-azabicyclo[2.2.1]hept-5-en-3-one precursors assured stereochemically unambiguous, diverse products. Pure (S,S,S) 2-azanorbornane enantiomer 15 (MRS4738) displayed higher affinity than 1 (3-fold higher affinity than enantiomer 16) and in vivo antihyperallodynic and antiasthmatic activity. Its double prodrug 143 (MRS4815) dramatically reduced lung inflammation in a mouse asthma model. Related lactams 21–24 and dicarboxylate 42 displayed intermediate affinity and enhanced aqueous solubility. Isoquinuclidine 34 (IC50 15.6 nM) and isonortropanol 30 (IC50 21.3 nM) had lower lipophilicity than 1. In general, rigidified piperidine derivatives did not lower lipophilicity dramatically, except those rings with multiple polar groups. P2Y14R molecular modeling based on a P2Y12R structure showed stable and persistent key interactions for compound 15.

Topics & Concepts

ChemistryPiperidineLipophilicityStereochemistryEnantiomerMolecular modelChemical synthesisIn vitroBiochemistryAdenosine and Purinergic SignalingPharmacological Receptor Mechanisms and EffectsChemical Synthesis and Analysis
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