Division of Pulmonary Allergy and Critical Care Medicine, University of Pittsburgh School of Medicine, Pittsburgh, Pennsylvania.
Vascular Medicine Institute, University of Pittsburgh School of Medicine, Pittsburgh, Pennsylvania.
Antioxid Redox Signal. 2019 Oct 1;31(10):673-686. doi: 10.1089/ars.2018.7627. Epub 2019 Mar 6.
Asthma, characterized by airway obstruction and hyper-responsiveness, is more severe and less responsive to treatment in obese subjects. While alterations in mitochondrial function and redox signaling have been implicated in asthma pathogenesis, it is unclear whether these mechanisms differ in lean obese asthmatics. In addition, we previously demonstrated that circulating platelets from asthmatic individuals have altered bioenergetics; however, it is unknown whether platelet mitochondrial changes reflect those observed in airway epithelial cells. Herein we hypothesized that lean and obese asthmatics show differential bioenergetics and redox signaling in airway cells and that these alterations could be measured in platelets from the same individual. Using freshly isolated bronchial airway epithelial cells and platelets from lean and obese asthmatics and healthy individuals, we show that both cell types from obese asthmatics have significantly increased glycolysis, basal and maximal respiration, and oxidative stress compared with lean asthmatics and healthy controls. This increased respiration was associated with enhanced arginine metabolism by arginase, which has previously been shown to drive respiration. Inducible nitric oxide synthase (iNOS) was also upregulated in cells from all asthmatics. However, due to nitric oxide synthase uncoupling in obese asthmatics, overall nitric oxide (NO) bioavailability was decreased, preventing NO-dependent inhibition in obese asthmatic cells that was observed in lean asthmatics. These data demonstrate bioenergetic differences between lean and obese asthmatics that are, in part, due to differences in NO signaling. They also suggest that the platelet may serve as a useful surrogate to understand redox, oxidative stress and bioenergetic changes in the asthmatic airway.
哮喘的特征是气道阻塞和高反应性,在肥胖人群中更为严重,且对治疗的反应较差。虽然线粒体功能和氧化还原信号的改变与哮喘发病机制有关,但尚不清楚这些机制在瘦 肥胖哮喘患者中是否存在差异。此外,我们之前的研究表明,哮喘患者的循环血小板存在生物能量改变;然而,尚不清楚血小板线粒体的变化是否反映了气道上皮细胞中观察到的变化。在此,我们假设瘦 肥胖哮喘患者的气道细胞存在不同的生物能量和氧化还原信号,并且可以从同一患者的血小板中测量到这些变化。
使用从瘦 肥胖哮喘患者和健康个体中分离的新鲜支气管气道上皮细胞和血小板,我们发现与瘦哮喘患者和健康对照组相比,肥胖哮喘患者的两种细胞类型的糖酵解、基础和最大呼吸以及氧化应激均显著增加。这种增加的呼吸与精氨酸酶增强的精氨酸代谢有关,精氨酸酶先前已被证明可驱动呼吸。诱导型一氧化氮合酶 (iNOS) 在所有哮喘患者的细胞中也上调。然而,由于肥胖哮喘患者中的一氧化氮合酶解偶联,总的一氧化氮 (NO) 生物利用度降低,从而阻止了在瘦哮喘患者中观察到的肥胖哮喘患者细胞中的 NO 依赖性抑制。
这些数据表明,瘦 肥胖哮喘患者之间存在生物能量差异,部分原因是 NO 信号的差异。它们还表明血小板可能是一种有用的替代物,可以了解哮喘气道中的氧化还原、氧化应激和生物能量变化。