Angiotensin-Converting Enzyme-Dependent Intrarenal Angiotensin II Contributes to CTP: Phosphoethanolamine Cytidylyltransferase Downregulation, Mitochondrial Membranous Disruption, and Reactive Oxygen Species Overgeneration in Diabetic Tubulopathy.

IF 5.9 2区生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY Antioxidants & redox signaling Pub Date : 2024-11-04 DOI:10.1089/ars.2024.0637

Xia-Qing Li, Zhang-Zhang Xiao, Ke Ma, Xia-Yun Liu, Huan-Huan Liu, Bo Hu, Qian Zhao, Hong-Yue Li, Rui-Chang Chen, Yu Meng, Liang-Hong Yin

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Abstract

Aims: The limited therapeutic options for diabetic tubulopathy (DT) in early diabetic kidney disease (DKD) reflect the difficulty of targeting renal tubular compartment. While renin-angiotensin-aldosterone system (RAS) inhibitors are commonly utilized in the management of DKD, how intrarenal RAS contributes to diabetic tubular injury is not fully understood. Mitochondrial disruption and reactive oxygen species (ROS) overgeneration have been involved in diabetic tubular injury. Herein, we aim to test the hypothesis that angiotensin-converting enzyme (ACE)-dependent intrarenal angiotensin II (AngII) disrupts tubular mitochondrial membranous homeostasis and causes excessive ROS generation in DT. Results: Mice suffered from renal tubular mitochondrial disruption and ROS overgeneration following high-fat diet/streptozocin-type 2 diabetic induction. Intrarenal AngII generation is ACE-dependent in DT. Local AngII accumulation in renal tissues was achieved by intrarenal artery injection. ACE-dependent intrarenal AngII-treated mice exhibit markedly elevated levels of makers of tubular injury. CTP: Phosphoethanolamine cytidylyltransferase (PCYT2), the primary regulatory enzyme for the biosynthesis of phosphatidylethanolamine, was enriched in renal tubules according to single-cell RNA sequencing. ACE-dependent intrarenal AngII-induced tubular membranous disruption, ROS overgeneration, and PCYT2 downregulation. The diabetic ambiance deteriorated the detrimental effect of ACE-dependent intrarenal AngII on renal tubules. Captopril, the ACE inhibitor (ACEI), showed efficiency in partially ameliorating ACE-dependent intrarenal AngII-induced tubular deterioration pre- and post-diabetic induction. Innovation and Conclusion: This study uncovers a critical role of ACE-dependent intrarenal AngII in mitochondrial membranous disruption, ROS overgeneration, and PCYT2 deficiency in diabetic renal tubules, providing novel insight into DT pathogenesis and ACEI-combined therapeutic targets. Antioxid. Redox Signal. 00, 000-000.

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血管紧张素转换酶依赖性肾上腺内血管紧张素 II 导致糖尿病肾小管病变中的 CTP：磷脂酰乙醇胺胞苷酸基转移酶下调、线粒体膜破坏和活性氧过量生成。

目的：早期糖尿病肾病（DKD）中糖尿病肾小管病变（DT）的治疗方案有限，这反映了针对肾小管区室的治疗难度很大。虽然肾素-血管紧张素-醛固酮系统（RAS）抑制剂通常用于治疗糖尿病肾病，但肾内 RAS 如何导致糖尿病肾小管损伤尚未完全明了。线粒体破坏和活性氧（ROS）过度生成与糖尿病肾小管损伤有关。在此，我们旨在验证血管紧张素转换酶（ACE）依赖性肾内血管紧张素 II（AngII）破坏糖尿病肾小管线粒体膜稳态并导致 ROS 生成过多的假设。结果小鼠在高脂饮食/链脲佐菌素 2 型糖尿病诱导后出现肾小管线粒体破坏和 ROS 过度生成。在 DT 中，肾小管内 AngII 的生成依赖于 ACE。肾动脉内注射实现了肾组织内 AngII 的局部蓄积。ACE依赖性肾内AngII处理的小鼠表现出明显升高的肾小管损伤制造者水平。CTP：根据单细胞RNA测序，肾小管中富含磷脂酰乙醇胺胞苷酸转移酶（PCYT2），它是磷脂酰乙醇胺生物合成的主要调节酶。ACE依赖性肾内AngII诱导肾小管膜破坏、ROS过度生成和PCYT2下调。糖尿病环境恶化了 ACE 依赖性肾内 AngII 对肾小管的有害影响。ACE抑制剂（ACEI）卡托普利（Captopril）在部分程度上改善了糖尿病诱导前后ACE依赖性肾内AngII诱导的肾小管恶化。创新与结论：本研究揭示了 ACE 依赖性肾内 AngII 在糖尿病肾小管线粒体膜破坏、ROS 过度生成和 PCYT2 缺乏中的关键作用，为 DT 发病机制和 ACEI 联合治疗靶点提供了新的见解。抗氧化。氧化还原信号。00, 000-000.

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来源期刊

Antioxidants & redox signaling 生物-内分泌学与代谢

CiteScore

14.10

自引率

1.50%

发文量

170

审稿时长

3-6 weeks

期刊介绍： Antioxidants & Redox Signaling (ARS) is the leading peer-reviewed journal dedicated to understanding the vital impact of oxygen and oxidation-reduction (redox) processes on human health and disease. The Journal explores key issues in genetic, pharmaceutical, and nutritional redox-based therapeutics. Cutting-edge research focuses on structural biology, stem cells, regenerative medicine, epigenetics, imaging, clinical outcomes, and preventive and therapeutic nutrition, among other areas. ARS has expanded to create two unique foci within one journal: ARS Discoveries and ARS Therapeutics. ARS Discoveries (24 issues) publishes the highest-caliber breakthroughs in basic and applied research. ARS Therapeutics (12 issues) is the first publication of its kind that will help enhance the entire field of redox biology by showcasing the potential of redox sciences to change health outcomes. ARS coverage includes: -ROS/RNS as messengers -Gaseous signal transducers -Hypoxia and tissue oxygenation -microRNA -Prokaryotic systems -Lessons from plant biology