Institute for Anesthesiologic Pathophysiology and Process Engineering, Ulm University, Ulm, Germany.
Department of Anesthesiology, University Hospital, Ulm, Germany.
Front Immunol. 2020 Jan 23;10:3152. doi: 10.3389/fimmu.2019.03152. eCollection 2019.
Sepsis, that can be modeled by LPS injections, as an acute systemic inflammation syndrome is the most common cause for acute lung injury (ALI). ALI induces acute respiratory failure leading to hypoxemia, which is often associated with multiple organ failure (MOF). During systemic inflammation, the hypothalamus-pituitary-adrenal axis (HPA) is activated and anti-inflammatory acting glucocorticoids (GCs) are released to overcome the inflammation. GCs activate the GC receptor (GR), which mediates its effects via a GR monomer or GR dimer. The detailed molecular mechanism of the GR in different inflammatory models and target genes that might be crucial for resolving inflammation is not completely identified. We previously observed that mice with attenuated GR dimerization (GR) had a higher mortality in a non-resuscitated lipopolysaccharide (LPS)- and cecal ligation and puncture (CLP)-induced inflammation model and are refractory to exogenous GCs to ameliorate ALI during inflammation. Therefore, we hypothesized that impaired murine GR dimerization (GR) would further impair organ function in LPS-induced systemic inflammation under human like intensive care management and investigated genes that are crucial for lung function in this setup. Anesthetized GR and wildtype (GR) mice were challenged with LPS (10 mg·kg, intraperitoneal) and underwent intensive care management ("lung-protective" mechanical ventilation, crystalloids, and norepinephrine) for 6 h. Lung mechanics and gas exchange were assessed together with systemic hemodynamics, acid-base status, and mitochondrial oxygen consumption (JO). Western blots, immunohistochemistry, and real time quantitative polymerase chain reaction were performed to analyze lung tissue and inflammatory mediators were analyzed in plasma and lung tissue. When animals were challenged with LPS and subsequently resuscitated under intensive care treatment, GR mice had a higher mortality compared to GR mice, induced by an increased need of norepinephrine to achieve hemodynamic targets. After challenge with LPS, GR mice also displayed an aggravated ALI shown by a more pronounced impairment of gas exchange, lung mechanics and increased osteopontin (Opn) expression in lung tissue. Impairment of GR dimerization aggravates systemic hypotension and impairs lung function during LPS-induced endotoxic shock in mice. We demonstrate that the GR dimer is an important mediator of hemodynamic stability and lung function, possibly through regulation of Opn, during LPS-induced systemic inflammation.
脓毒症可以通过 LPS 注射来建模,作为一种急性全身炎症综合征,是急性肺损伤(ALI)最常见的原因。ALI 导致急性呼吸衰竭导致低氧血症,常伴有多器官功能衰竭(MOF)。在全身炎症期间,下丘脑-垂体-肾上腺轴(HPA)被激活,抗炎作用的糖皮质激素(GCs)被释放以克服炎症。GCs 激活糖皮质激素受体(GR),GR 通过 GR 单体或 GR 二聚体介导其作用。GR 在不同炎症模型中的详细分子机制以及对于解决炎症可能至关重要的靶基因尚未完全确定。我们之前观察到,GR 二聚化减弱(GR)的小鼠在未复苏的脂多糖(LPS)和盲肠结扎和穿刺(CLP)诱导的炎症模型中死亡率更高,并且对外源性 GCs 改善炎症期间的 ALI 有抗性。因此,我们假设受损的小鼠 GR 二聚化(GR)会在类似于人类重症监护管理的 LPS 诱导的全身炎症下进一步损害器官功能,并研究在此设置中对肺功能至关重要的基因。麻醉的 GR 和野生型(GR)小鼠接受 LPS(10mg·kg,腹腔内)挑战,并接受重症监护管理(“肺保护性”机械通气、晶体和去甲肾上腺素)6 小时。评估肺力学和气体交换以及全身血流动力学、酸碱状态和线粒体耗氧量(JO)。进行 Western blot、免疫组织化学和实时定量聚合酶链反应以分析肺组织,分析血浆和肺组织中的炎症介质。当动物接受 LPS 挑战并随后在重症监护治疗下复苏时,与 GR 小鼠相比,GR 小鼠的死亡率更高,这是由于需要更多去甲肾上腺素来实现血流动力学目标。LPS 挑战后,GR 小鼠的 ALI 也更为严重,表现为气体交换、肺力学的显著恶化和肺组织中骨桥蛋白(Opn)表达增加。GR 二聚化的受损加重了 LPS 诱导的内毒素休克期间的全身低血压并损害了小鼠的肺功能。我们证明,GR 二聚体是 LPS 诱导的全身炎症期间血流动力学稳定性和肺功能的重要介质,可能通过调节 Opn 来实现。
