Abstract
Abstract Background and Aims RXFP1 is a G protein-coupled receptor (GPCR) for the pregnancy hormone, relaxin. While preclinical studies, performed primarily in rodent, describe beneficial effects of this pleiotropic peptide across several organ systems, there has been a disappointing lack of success in translating these observations into clinical benefit. To provide a potential pharmacological explanation accounting for this translational gap, the aim of this study was thus to thoroughly evaluate RXFP1 expression across species and tissues as well as to evaluate the renal-intrinsic effects of the RXFP1 agonist, AZD5462. Method Unbiased bioinformatic analysis of several gene expression databases was used as a first approach to compare RXFP1 tissue-level expression between rodent and human. Experimental validation was subsequently performed using scRNAseq, RNAscope and immunohistochemistry on mouse, rat, non-human primate (NHP) and human kidney. The putative renal target engagement effects of RXFP1 agonism were assessed by determining the acute and chronic effects of the RXFP1-selective small molecule agonist, AZD5462, on plasma renin concentrations in both NHPs and in a Phase 1 randomized, single-blind, placebo-controlled study in healthy humans. Results RXFP1 was identified as one of the most highly expressed GPCRs in human and NHP kidney glomeruli. Specifically, by multiple assays, we identified glomerular endothelial cells as the principal cell type expressing RXFP1. This observation is in stark contrast to mouse and rat kidney, where RXFP1 was not readily detected. AZD5462 administered orally to NHPs and healthy human participants elicited an early and sustained dose-dependent increase in plasma renin concentration, and in humans an additional decline in serum creatinine. Conclusion Human RXFP1 kidney glomerular expression is conserved with NHPs but not rodent, thus highlighting the translational and pharmacological challenges in studying RXFP1/relaxin biology across species. The concordant ability of AZD5462 to induce elevations in renin and reduction in serum creatinine, together with relaxin's reported renal-hemodynamic activity in humans, may underlie a previously unappreciated renal-intrinsic RXFP1 target engagement mechanism driving its hemodynamic and renal effects. The potential therapeutic benefits of RXFP1 agonism are the subject of on-going clinical trials in heart failure patients.
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