Department of Respiratory and Critical Care Medicine, Guizhou Province People's Hospital, Guiyang, China.
Department of Anesthesiology and Perioperative Medicine, Rochester, Minnesota, United States.
Am J Physiol Lung Cell Mol Physiol. 2024 Oct 1;327(4):L547-L556. doi: 10.1152/ajplung.00356.2023. Epub 2024 Aug 27.
Bronchial airways and lung parenchyma undergo both static and dynamic stretch in response to normal breathing as well as in the context of insults such as mechanical ventilation (MV) or in diseases such as asthma and chronic obstructive pulmonary disease (COPD) which lead to airway remodeling involving increased extracellular matrix (ECM) production. Here, the role of fibroblasts is critical, but the relationship between stretch- and fibroblast-induced ECM remodeling under these conditions is not well-explored. Piezo (PZ) channels play a role in mechanotransduction in many cell and organ systems, but their role in mechanical stretch-induced airway remodeling is not known. To explore this, we exposed human lung fibroblasts to 10% static stretch on a background of 5% oscillations for 48 h, with no static stretch considered controls. Collagen I, fibronectin, alpha-smooth muscle actin (α-SMA), and Piezo 1 (PZ1) expression was determined in the presence or absence of Yoda1 (PZ1 agonist) or GsMTx4 (PZ1 inhibitor). Collagen I, fibronectin, and α-SMA expression was increased by stretch and Yoda1, whereas pretreatment with GsMTx4 or knockdown of PZ1 by siRNA blunted this effect. Acute stretch in the presence and absence of Yoda1 demonstrated activation of the ERK pathway but not Smad. Measurement of [Ca] responses to histamine showed significantly greater responses following stretch, effects that were blunted by knockdown of PZ1. Our findings identify an essential role for PZ1 in mechanical stretch-induced production of ECM mediated by ERK phosphorylation and Ca influx in lung fibroblasts. Targeting PZ channels in fibroblasts may constitute a novel approach to ameliorate airway remodeling by decreasing ECM deposition. The lung is an inherently mechanosensitive organ that can respond to mechanical forces in adaptive or maladaptive ways, including via remodeling resulting in increased fibrosis. We explored the mechanisms that link mechanical forces to remodeling using human lung fibroblasts. We found that mechanosensitive Piezo channels increase with stretch and mediate extracellular matrix formation and the fibroblast-to-myofibroblast transition that occurs with stretch. Our data highlight the importance of Piezo channels in lung mechanotransduction toward remodeling.
支气管和肺实质在正常呼吸以及机械通气 (MV) 等刺激或哮喘和慢性阻塞性肺疾病 (COPD) 等疾病的情况下会发生静态和动态拉伸,导致涉及细胞外基质 (ECM) 产生增加的气道重塑。在这里,成纤维细胞的作用至关重要,但在这些条件下,拉伸和成纤维细胞诱导的 ECM 重塑之间的关系尚未得到很好的探索。Piezo (PZ) 通道在许多细胞和器官系统的机械转导中发挥作用,但它们在机械拉伸诱导的气道重塑中的作用尚不清楚。为了探索这一点,我们将人肺成纤维细胞暴露于 10%的静态拉伸下,背景为 5%的振荡 48 小时,没有静态拉伸被认为是对照。在存在或不存在 Yoda1(PZ1 激动剂)或 GsMTx4(PZ1 抑制剂)的情况下,测定胶原 I、纤连蛋白、α-平滑肌肌动蛋白 (α-SMA) 和 Piezo 1 (PZ1) 的表达。拉伸和 Yoda1 增加了胶原 I、纤连蛋白和 α-SMA 的表达,而 GsMTx4 的预处理或 siRNA 敲低 PZ1 则削弱了这种作用。存在和不存在 Yoda1 的急性拉伸显示 ERK 途径的激活,但没有 Smad。测量组胺引起的 [Ca] 反应表明拉伸后反应明显增强,而 PZ1 的敲低则削弱了这种反应。我们的发现确定了 PZ1 在机械拉伸诱导的肺成纤维细胞 ECM 产生中的重要作用,该作用通过 ERK 磷酸化和 Ca 内流介导。靶向成纤维细胞中的 PZ 通道可能是通过减少 ECM 沉积来改善气道重塑的一种新方法。肺是一种固有机械敏感的器官,可以以适应性或失调性的方式对机械力做出反应,包括通过重塑导致纤维化增加。我们使用人肺成纤维细胞探索了将机械力与重塑联系起来的机制。我们发现,机械敏感的 Piezo 通道随拉伸而增加,并介导与拉伸相关的细胞外基质形成和成纤维细胞向肌成纤维细胞的转化。我们的数据强调了 Piezo 通道在肺机械转导向重塑中的重要性。
