1 Division of Allergy, Pulmonary, and Critical Care Medicine, Department of Medicine.
Am J Respir Cell Mol Biol. 2013 Nov;49(5):778-87. doi: 10.1165/rcmb.2012-0463OC.
Pulmonary arterial hypertension (PAH) has been associated with a number of different but interrelated pathogenic mechanisms. Metabolic and oxidative stresses have been shown to play important pathogenic roles in a variety of model systems. However, many of these relationships remain at the level of association. We sought to establish a direct role for metabolic stress and oxidant injury in the pathogenesis of PAH. Mice that universally express a disease-causing mutation in bone morphogenic protein receptor 2 (Bmpr2) were exposed to room air or to brief daily hyperoxia (95% oxygen for 3 h) for 6 weeks, and were compared with wild-type animals undergoing identical exposures. In both murine tissues and cultured endothelial cells, the expression of mutant Bmpr2 was sufficient to cause oxidant injury that was particularly pronounced in mitochondrial membranes. With the enhancement of mitochondrial generation of reactive oxygen species by hyperoxia, oxidant injury was substantially enhanced in mitochondrial membranes, even in tissues distant from the lung. Hyperoxia, despite its vasodilatory actions in the pulmonary circulation, significantly worsened the PAH phenotype (elevated right ventricular systolic pressure, decreased cardiac output, and increased pulmonary vascular occlusion) in Bmpr2 mutant animals. These experiments demonstrate that oxidant injury and metabolic stress contribute directly to disease development, and provide further evidence for PAH as a systemic disease with life-limiting cardiopulmonary manifestations.
肺动脉高压 (PAH) 与许多不同但相互关联的发病机制有关。代谢和氧化应激已被证明在各种模型系统中发挥重要的致病作用。然而,许多这些关系仍然停留在关联的水平上。我们试图确定代谢应激和氧化剂损伤在 PAH 发病机制中的直接作用。在普遍表达骨形态发生蛋白受体 2 (Bmpr2) 致病突变的小鼠中,暴露于室内空气或每天短暂的高氧(95%氧气 3 小时)6 周,并与接受相同暴露的野生型动物进行比较。在两种鼠组织和培养的内皮细胞中,突变型 Bmpr2 的表达足以引起氧化剂损伤,特别是在线粒体膜中更为明显。随着高氧增强线粒体产生的活性氧,氧化剂损伤在线粒体膜中大大增强,即使在远离肺部的组织中也是如此。尽管高氧在肺循环中具有血管扩张作用,但在 Bmpr2 突变动物中,它显著加重了 PAH 表型(右心室收缩压升高、心输出量降低和肺血管闭塞增加)。这些实验表明,氧化剂损伤和代谢应激直接导致疾病发展,并为 PAH 作为一种具有危及生命的心肺表现的系统性疾病提供了进一步证据。