Reactivity of renal and mesenteric resistance vessels to angiotensin II is mediated by NOXA1/NOX1 and superoxide signaling.

IF 3.7 2区医学 Q1 PHYSIOLOGY

American Journal of Physiology-renal Physiology Pub Date : 2023-04-01 Epub Date: 2023-02-09 DOI:10.1152/ajprenal.00236.2022

Mark D Stevenson, Aleksandr E Vendrov, Xi Yang, Yuenmu Chen, Hernán A Navarro, Nicholas Moss, Marschall S Runge, William J Arendshorst, Nageswara R Madamanchi

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Abstract

Activation of NADPH oxidase (NOX) enzymes and the generation of reactive oxygen species and oxidative stress regulate vascular and renal function and contribute to the pathogenesis of hypertension. The present study examined the role of NOXA1/NOX1 function in vascular reactivity of renal and mesenteric resistance arteries/arterioles of wild-type and Noxa1^-/- mice. A major finding was that renal blood flow is less sensitive to acute stimulation by angiotensin II (ANG II) in Noxa1^-/- mice compared with wild-type mice, with a direct action on resistance arterioles independent of nitric oxide (NO) bioavailability. These functional results were reinforced by immunofluorescence evidence of NOXA1/NOX1 protein presence in renal arteries, afferent arterioles, and glomeruli as well as their upregulation by ANG II. In contrast, the renal vascular response to the thromboxane mimetic U46619 was effectively blunted by NO and was similar in both mouse genotypes and thus independent of NOXA1/NOX1 signaling. However, phenylephrine- and ANG II-induced contraction of isolated mesenteric arteries was less pronounced and buffering of vasoconstriction after acetylcholine and nitroprusside stimulation was reduced in Noxa1^-/- mice, suggesting endothelial NO-dependent mechanisms. An involvement of NOXA1/NOX1/O₂^•- signaling in response to ANG II was demonstrated with the specific NOXA1/NOX1 assembly inhibitor C25 and the nonspecific NOX inhibitor diphenyleneiodonium chloride in cultured vascular smooth muscle cells and isolated mesenteric resistance arteries. Collectively, our data indicate that the NOX1/NOXA1/O₂^•- pathway contributes to acute vasoconstriction induced by ANG II in renal and mesenteric vascular beds and may contribute to ANG II-induced hypertension.NEW & NOTEWORTHY Renal reactivity to angiotensin II (ANG II) is mediated by superoxide signaling produced by NADPH oxidase (NOX)A1/NOX1. Acute vasoconstriction of renal arteries by ANG was blunted in Noxa1^-/- compared with wild-type mice. NOXA1/NOX1/O₂^•- signaling was also observed in ANG II stimulation of vascular smooth muscle cells and isolated mesenteric resistance arteries, indicating that it contributes to ANG II-induced hypertension. A NOXA1/NOX1 assembly inhibitor (C25) has been characterized that inhibits superoxide production and ameliorates the effects of ANG II.

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肾脏和肠系膜阻力血管对血管紧张素 II 的反应是由 NOXA1/NOX1 和超氧化物信号介导的。

NADPH氧化酶（NOX）酶的活化以及活性氧和氧化应激的产生调节血管和肾脏功能，并导致高血压的发病。本研究考察了 NOXA1/NOX1 功能在野生型小鼠和 Noxa1-/- 小鼠肾动脉和肠系膜阻力动脉/细动脉血管反应性中的作用。一个主要发现是，与野生型小鼠相比，Noxa1-/-小鼠的肾血流量对血管紧张素 II（ANG II）急性刺激的敏感性较低，直接作用于阻力动脉血管，与一氧化氮（NO）的生物利用度无关。免疫荧光证据表明，NOXA1/NOX1 蛋白存在于肾动脉、传入动脉和肾小球中，并在 ANG II 的作用下上调，这进一步证实了上述功能性结果。相反，肾血管对血栓素模拟物 U46619 的反应被 NO 有效地减弱，两种基因型小鼠的反应相似，因此与 NOXA1/NOX1 信号无关。然而，Noxa1-/-小鼠的肾上腺素和 ANG II 诱导的离体肠系膜动脉收缩不明显，乙酰胆碱和硝普钠刺激后血管收缩的缓冲作用减弱，这表明内皮 NO 依赖性机制。在培养的血管平滑肌细胞和离体肠系膜阻力动脉中，特异性 NOXA1/NOX1 组装抑制剂 C25 和非特异性 NOX 抑制剂二苯基碘氯化铵证明了 NOXA1/NOX1/O2 信号参与了对 ANG II 的反应。总之，我们的数据表明，NOX1/NOXA1/O2--通路有助于 ANG II 在肾脏和肠系膜血管床诱导的急性血管收缩，并可能有助于 ANG II 诱导的高血压。与野生型小鼠相比，Noxa1-/-小鼠肾动脉受 ANG 影响的急性血管收缩减弱。在 ANG II 对血管平滑肌细胞和离体肠系膜阻力动脉的刺激中也观察到了 NOXA1/NOX1/O2 信号传导，这表明 NOXA1/NOX1/O2 信号传导有助于 ANG II 诱导的高血压。目前已发现一种 NOXA1/NOX1 组装抑制剂（C25），它能抑制超氧化物的产生并改善 ANG II 的影响。

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来源期刊

American Journal of Physiology-renal Physiology 医学-泌尿学与肾脏学

CiteScore

8.40

自引率

7.10%

发文量

154

审稿时长

2-4 weeks

期刊介绍： The American Journal of Physiology - Renal Physiology publishes original manuscripts on timely topics in both basic science and clinical research. Published articles address a broad range of subjects relating to the kidney and urinary tract, and may involve human or animal models, individual cell types, and isolated membrane systems. Also covered are the pathophysiological basis of renal disease processes, regulation of body fluids, and clinical research that provides mechanistic insights. Studies of renal function may be conducted using a wide range of approaches, such as biochemistry, immunology, genetics, mathematical modeling, molecular biology, as well as physiological and clinical methodologies.

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