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Molecular Mechanisms of Desensitization Underlying the Differential Effects of Formyl Peptide Receptor 2 Agonists on Cardiac Structure–Function Post Myocardial Infarction

John A. Lupisella, Stéphane St-Onge, Marilyn Carrier, Erica Cook, Tao Wang, Chi Shing Sum, Gayani Fernando, Kendra Apgar, Rongan Zhang, Nancy Carson, Bradley J. Snyder, Carol S. Ryan, Xiuying Ma, Elizabeth A. Dierks, Sean C. Little, Ellen K. Kick, Nicholas R. Wurtz, Michel Bouvier, Madeleine Héroux, Ricardo Alexandrino Garcia

2022ACS Pharmacology & Translational Science20 citationsDOIOpen Access PDF

Abstract

Formyl peptide receptor 2 (FPR2) plays an integral role in the transition of macrophages from a pro-inflammatory program to one that is pro-resolving. FPR2-mediated stimulation of resolution post myocardial infarction has demonstrated efficacy in rodent models and is hypothesized to reduce progression into heart failure. FPR2 agonists that promote long-lasting receptor internalization can lead to persistent desensitization and diminished therapeutic benefits. In vitro signaling profiles and propensities for receptor desensitization of two clinically studied FPR2 agonists, namely, BMS-986235 and ACT-389949, were evaluated. In contrast to BMS-986235, pre-stimulation with ACT-389949 led to a decrease in its potency to inhibit cAMP production. Moreover, ACT-389949 displayed greater efficacy for β-arrestin recruitment, while efficacy of Gi activation was similar for both agonists. Following agonist-promoted FPR2 internalization, effective recycling to the plasma membrane was observed only with BMS-986235. Use of G protein-coupled receptor kinase (GRK) knock-out cells revealed a differential impact of GRK2 versus GRK5/6 on β-arrestin recruitment and Gi activation promoted by the two FPR2 agonists. In vivo, decreases of granulocytes in circulation were greatly diminished in mice treated with ACT-389949 but not for BMS-986235. With short-term dosing, both compounds induced a pro-resolution polarization state in cardiac monocyte/macrophages post myocardial infarction. By contrast, with long-term dosing, only BMS-986235 preserved the infarct wall thickness and increased left ventricular ejection fraction in a rat model of myocardial infarction. Altogether, the study shows that differences in the desensitization profiles induced by ACT-389949 and BMS-986235 at the molecular level may explain their distinct inflammatory/pro-resolving activities in vivo.

Topics & Concepts

Desensitization (medicine)StimulationAgonistReceptorMyocardial infarctionHomologous desensitizationPharmacologyBeta adrenergic receptor kinaseG protein-coupled receptorInternalizationInternal medicineIn vivoChemistryMedicineEndocrinologyBiologyBiotechnologyS100 Proteins and AnnexinsReceptor Mechanisms and SignalingNeuropeptides and Animal Physiology