Abstract 16878: Cardiac Overexpression of RXFP1 via AAV9 Gene Therapy Sensitizes Myocardial Inotropic Response to Serelaxin

Background: The pleiotropic hormone relaxin has been shown to mediate physiologic responses during pregnancy by facilitating increases in vascular compliance and cardiac output. While relaxin signaling has been attributed to increases in atrial inotropy, the hormonal effects on ventricular contractility have not been explored in vivo . In this study, we investigated the dose-response effects of recombinant human relaxin (serelaxin) on ventricular mechanics. Methods and Results: Adult male CD1 mice were anesthetized and mechanically ventilated prior to Millar cardiac catheterization. A pressure-volume catheter was advanced into the left ventricle (LV), and baseline systolic and diastolic pressure/volume (PV) loops were recorded (Pre). Mice were injected with either saline, 10 μg/kg (low dose) or 1 mg/kg (high dose) of serelaxin, and PV loops were obtained after stabilization (Post) . Mice injected with 1 mg/kg demonstrated significantly higher LV contractility ( Fig A ) independent of preload ( Fig B ). These responses were not observed with low dose. In order to further examine the role of RXFP1 in modulating these responses, healthy CD1 were injected with AAV9-RXFP1 or empty vector as control and receptor overexpression was confirmed four weeks later via qPCR ( Fig C ). PV loop analysis showed an increased inotropic response [ΔP Max , Δ(dP/dt) Max ] and improved relaxation kinetics [Δ(dP/dt) Min , Δτ] in RXFP1-overexpressing mice at a lower dose of serelaxin, when compared to empty vector mice ( Fig D ). Conclusions: Our data show a novel, dose-dependent correlation between serelaxin and ventricular inotropic and lusitropic responses in mice. These responses were observed at a lower drug dose in cardiac RXFP1-overexpressing mice. We propose that further investigation of this phenomenon could advance the therapeutic, cardioprotective effects associated with relaxin therapy in different etiologies of heart failure that may exhibit changes in RXFP1 expression.