RKER-012, a novel modified ActRIIB ligand trap, attenuated right ventricular cardiomyopathy in a preclinical model of pulmonary arterial hypertension

IF 37.6 1区 医学 Q1 CARDIAC & CARDIOVASCULAR SYSTEMS
P Jain, C Materna, K Babbs, T Nurse, J Ishimwe, H Natarajan, S Joshi, L Lerner, F Fisher, J Seehra, J Lachey
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引用次数: 0

Abstract

Background The primary cause of death in pulmonary arterial hypertension (PAH) is right ventricular (RV) failure. Initially, the RV adapts to heightened pressure through adaptive remodeling, but prolonged pressure overload triggers maladaptive remodeling, culminating in failure. Overactive activin/growth differentiation factor (GDF) signaling has been implicated in cardiomyopathy and heart failure. RKER-012, a research version of KER-012, is an investigational modified activin receptor type IIB (ActRIIB) ligand trap designed to specifically bind and inhibit select TGF-β ligands, including activins A and B and GDFs 8 and 11. RKER-012 previously exhibited a cardioprotective effect in a pulmonary arterial banding (PAB) model of RV dysfunction. To determine the effect of RKER-012 on afterload-induced RV cardiomyopathy caused by increased pulmonary artery pressure, we utilized an angio-obliterative Sugen/hypoxia (SH) rat model of PAH that closely mimics human PAH pathology. Methods Male Sprague Dawley rats were subcutaneously (s.c.) injected with one dose of Sugen 5416 and exposed to 10% hypoxia for 3 weeks during which they received either vehicle (SH-Veh; s.c; BIW) or RKER-012 (10 mg/kg; s.c; BIW). Normoxic (Nx) control rats were maintained in room air for 3 weeks with BIW s.c. vehicle treatment. After 3 weeks of treatment, systolic pulmonary arterial pressure (sPAP) and Fulton index (FI) were assessed. Hallmark genes of inflammatory process, endothelial/platelet activation, and fibrosis were evaluated in the RV by qPCR. Results Increases in FI (+99.4%;p<0.0001) and sPAP (+250.9%;p<0.0001) were observed in SH-Veh rats vs. Nx rats, consistent with the development of pulmonary and cardiac impairment. In contrast, treatment with RKER-012 reduced FI (-28.0%;p<0.001) and sPAP (-44.5%;p<0.001). In the RV, SH-Veh rats had increased expression of TGF-ß pathway genes involved in inflammation, endothelial/platelet activation, and fibrosis. RKER-012 treatment reduced expression of these genes (Tgf-β1, -44.7%;p=0.003; Fstl3, -43.5%;p=0.0162; Mcp1, -22.5%;p=0.535; Cd68, -60.3%;p=0.0048; Ctgf, -57.1%;p=0.0139; Col1a1, -47.2%, p=0.0255 ;Col3a1, -69.5%;p<0.0001; Lox, -61.4%;p=0.0054; P-selectin, -63.9%;p=0.018) in comparison to SH-Veh treatment. Conclusion Consistent with previous findings in a PAB mouse model, RKER-012 treatment protected against increased sPAP and maladaptive cardiac remodeling in a SH rat model of PAH. Additionally, RKER-012 attenuated RV cardiomyopathy by reducing the expression of genes involved in inflammatory and fibrotic processes. These preclinical findings in the RV paralleled the changes in circulating cardiovascular health biomarkers, including reduced NT-proBNP, observed in a Phase 1 trial of KER-012 in healthy volunteers. These findings, along with the safety and tolerability observed in the Phase 1 trial, provided rationale for the ongoing Phase 2 TROPOS trial of KER-012 in patients with PAH (NCT05975905).
RKER-012是一种新型改良ActRIIB配体陷阱,可减轻肺动脉高压临床前模型中的右心室心肌病变
背景肺动脉高压(PAH)的主要死因是右心室(RV)衰竭。起初,右心室通过适应性重塑来适应压力的升高,但长期的压力过载会引发适应性重塑不良,最终导致右心室功能衰竭。过度活跃的激活素/生长分化因子(GDF)信号传导与心肌病和心力衰竭有关。RKER-012是KER-012的研究版,是一种正在研究的改良型活化素受体ⅡB型(ActRⅡB)配体捕获剂,旨在特异性结合和抑制特定的TGF-β配体,包括活化素A和B以及生长分化因子8和11。此前,RKER-012 在肺动脉绑扎(PAB)的 RV 功能障碍模型中显示出了心脏保护作用。为了确定 RKER-012 对肺动脉压力升高引起的后负荷诱导的 RV 心肌病的影响,我们采用了血管闭塞性 Sugen/hypoxia (SH) PAH 大鼠模型,该模型非常接近人类 PAH 病理学。方法 雄性 Sprague Dawley 大鼠皮下注射(s.c.)一剂量的 Sugen 5416,并暴露于 10% 的缺氧环境中 3 周,在此期间接受药物(SH-Veh;s.c; BIW)或 RKER-012(10 mg/kg;s.c; BIW)治疗。正常缺氧(Nx)对照组大鼠在室内空气中维持 3 周,接受 BIW s.c. 药物治疗。治疗 3 周后,评估收缩肺动脉压(sPAP)和富尔顿指数(FI)。通过 qPCR 评估了 RV 中炎症过程、内皮/血小板活化和纤维化的标志基因。结果 在 SH-Veh 大鼠与 Nx 大鼠之间观察到 FI(+99.4%;p<0.0001)和 sPAP(+250.9%;p<0.0001)的增加,这与肺部和心脏损伤的发展相一致。相反,用 RKER-012 治疗可降低 FI(-28.0%;p<0.001)和 sPAP(-44.5%;p<0.001)。在 RV 中,SH-Veh 大鼠参与炎症、内皮/血小板活化和纤维化的 TGF-ß 通路基因表达增加。RKER-012 治疗降低了这些基因的表达(Tgf-β1,-44.7%;p=0.003;Fstl3,-43.5%;p=0.0162;Mcp1,-22.5%;p=0.535;Cd68,-60.3%;p=0.0048;Ctgf,-57.1%;p=0.0139;Col1a1,-47.2%,p=0.0255;Col3a1,-69.5%;p<0.0001;Lox,-61.4%;p=0.0054;P-选择素,-63.9%;p=0.018)。结论 与之前在 PAB 小鼠模型中的发现一致,RKER-012 治疗可防止 SH PAH 大鼠模型中 sPAP 的增加和不良心脏重塑。此外,RKER-012 还能减少炎症和纤维化过程中相关基因的表达,从而减轻 RV 心肌病。这些在 RV 中的临床前研究结果与 KER-012 在健康志愿者中进行的一期试验中观察到的循环心血管健康生物标志物的变化(包括 NT-proBNP 的降低)相一致。这些发现以及在 1 期试验中观察到的安全性和耐受性,为 KER-012 在 PAH 患者中正在进行的 2 期 TROPOS 试验(NCT05975905)提供了依据。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
European Heart Journal
European Heart Journal 医学-心血管系统
CiteScore
39.30
自引率
6.90%
发文量
3942
审稿时长
1 months
期刊介绍: The European Heart Journal is a renowned international journal that focuses on cardiovascular medicine. It is published weekly and is the official journal of the European Society of Cardiology. This peer-reviewed journal is committed to publishing high-quality clinical and scientific material pertaining to all aspects of cardiovascular medicine. It covers a diverse range of topics including research findings, technical evaluations, and reviews. Moreover, the journal serves as a platform for the exchange of information and discussions on various aspects of cardiovascular medicine, including educational matters. In addition to original papers on cardiovascular medicine and surgery, the European Heart Journal also presents reviews, clinical perspectives, ESC Guidelines, and editorial articles that highlight recent advancements in cardiology. Additionally, the journal actively encourages readers to share their thoughts and opinions through correspondence.
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