Laboratory of Cardiovascular Research, Tel Aviv Sourasky Medical Center, Affiliated with the Sackler Faculty of Medicine, Tel-Aviv University, Tel-Aviv, Israel.
Department of Cardiology, Sackler School of Medicine, Tel-Aviv University, Tel-Aviv, Israel.
PLoS One. 2023 Aug 24;18(8):e0275550. doi: 10.1371/journal.pone.0275550. eCollection 2023.
Renal injury induces major changes in plasma and cardiac metabolites. Using a small- animal in vivo model, we sought to identify a key metabolite whose levels are significantly modified following an acute kidney injury (AKI) and to analyze whether this agent could offer cardiac protection once an ischemic event has occurred.
Metabolomics profiling of cardiac lysates and plasma samples derived from rats that underwent AKI 1 or 7 days earlier by 5/6 nephrectomy versus sham-operated controls was performed. We detected 26 differential metabolites in both heart and plasma samples at the two selected time points, relative to sham. Out of which, kynurenic acid (kynurenate, KYNA) seemed most relevant. Interestingly, KYNA given at 10 mM concentration significantly rescued the viability of H9C2 cardiac myoblast cells grown under anoxic conditions and largely increased their mitochondrial content and activity as determined by flow cytometry and cell staining with MitoTracker dyes. Moreover, KYNA diluted in the drinking water of animals induced with an acute myocardial infarction, highly enhanced their cardiac recovery according to echocardiography and histopathology.
KYNA may represent a key metabolite absorbed by the heart following AKI as part of a compensatory mechanism aiming at preserving the cardiac function. KYNA preserves the in vitro myocyte viability following exposure to anoxia in a mechanism that is mediated, at least in part, by protection of the cardiac mitochondria. A short-term administration of KYNA may be highly beneficial in the treatment of the acute phase of kidney disease in order to attenuate progression to reno-cardiac syndrom and to reduce the ischemic myocardial damage following an ischemic event.
肾损伤会引起血浆和心脏代谢物的重大变化。本研究使用小动物体内模型,旨在确定一种关键代谢物,其水平在急性肾损伤(AKI)后显著改变,并分析该物质在发生缺血事件后是否能提供心脏保护。
对接受 5/6 肾切除术的 AKI 大鼠和假手术对照大鼠的心脏和血浆样本进行代谢组学分析。与假手术组相比,我们在这两个选定的时间点检测到心脏和血浆样本中 26 种差异代谢物。其中,犬尿酸(犬尿氨酸,KYNA)似乎最为相关。有趣的是,10mM 浓度的 KYNA 显著挽救了在缺氧条件下生长的 H9C2 心肌细胞的活力,并通过流式细胞术和用 MitoTracker 染料染色的细胞测定法大大增加了它们的线粒体含量和活性。此外,在急性心肌梗死动物的饮用水中稀释 KYNA,根据超声心动图和组织病理学,显著提高了它们的心脏恢复。
KYNA 可能代表 AKI 后被心脏吸收的关键代谢物,作为一种旨在保护心脏功能的代偿机制的一部分。KYNA 通过保护心脏线粒体,在缺氧暴露后保持体外心肌细胞活力,至少部分介导了这一机制。KYNA 的短期给药可能对治疗肾脏疾病的急性期非常有益,以减轻向肾心综合征的进展,并减少缺血事件后的缺血性心肌损伤。
