Cardiovasc Res. 2021 Jul 28. pii: cvab171. [Epub ahead of print]
Livia L Camargo,
Augusto C Montezano,
Misbah Hussain,
Yu Wang,
Zhiguo Zou,
Francisco J Rios,
Karla B Neves,
Rheure Alves-Lopes,
Fazli R Awan,
Tomasz J Guzik,
Thomas Jensen,
Richard C Hartley,
Rhian M Touyz.
AIMS: NOX-derived reactive oxygen species (ROS) are mediators of signaling pathways implicated in vascular smooth muscle cell (VSMC) dysfunction in hypertension. Among the numerous redox-sensitive kinases important in VSMC regulation is c-Src. However, mechanisms linking NOX/ROS to c-Src are unclear, especially in the context of oxidative stress in hypertension. Here we investigated the role of NOX-induced oxidative stress in VSMCs in human hypertension focusing on NOX5, and explored c-Src, as a putative intermediate connecting NOX5-ROS to downstream effector targets underlying VSMC dysfunction.
METHODS AND RESULTS: VSMC from arteries from normotensive (NT) and hypertensive (HT) subjects were studied. NOX1,2,4,5 expression, ROS generation, oxidation/phosphorylation of signaling molecules, actin polymerization and migration were assessed in the absence and presence of NOX5 (melittin) and Src (PP2) inhibitors. NOX5 and p22phox-dependent NOXs (NOX1-4) were downregulated using NOX5 siRNA and p22phox-siRNA approaches. As proof of concept in intact vessels, vascular function was assessed by myography in transgenic mice expressing human NOX5 in a VSMC-specific manner. In HT VSMCs NOX5 was upregulated, with associated oxidative stress, hyperoxidation (c-Src, peroxiredoxin, DJ-1) and hyperphosphorylation (PKC, ERK1/2, MLC20) of signaling molecules. NOX5 siRNA reduced ROS generation in NT and HT subjects. NOX5 siRNA, but not p22phox-siRNA, blunted c-Src phosphorylation in HT VSMCs. NOX5 siRNA reduced phosphorylation of MLC20 and FAK in NT and HT. In p22phox- silenced HT VSMCs, Ang II-induced phosphorylation of MLC20 was increased, effects blocked by melittin and PP2. NOX5 and c-Src inhibition attenuated actin polymerization and migration in HT VSMCs. In NOX5 transgenic mice, vascular hypercontractilty was decreased by melittin and PP2.
CONCLUSIONS: We define NOX5/ROS/c-Src as a novel feedforward signaling network in human VSMCs. Amplification of this system in hypertension contributes to VSMC dysfunction. Dampening the NOX5/ROS/c-Src pathway may ameliorate hypertension-associated vascular injury.
TRANSLATIONAL PERSPECTIVE: Oxidative stress is a major factor contributing to vascular damage in hypertension. We corroborate experimental evidence that NOX-derived ROS generation is increased in human vascular smooth muscle cells (VSMC) and demonstrate that in human hypertension NOX5 upregulation is a major trigger of VSMC dysfunction. We uncover new regulatory molecular mechanisms of NOX5 and define NOX5/ROS/c-Src as a novel signaling pathway in human VSMCs. This system is augmented in hypertension contributing to abnormal VSMC redox signaling, cytoskeletal disorganization and vascular dysfunction. Modulating the NOX5/ROS/c-Src pathway may have therapeutic potential by targeting redox signaling pathways involved in vascular dysfunction associated with hypertension.
Keywords: NOX5; hypertension; oxidative stress. vascular smooth muscle cells