在缺氧性肺动脉高压中,糖酵解增强会导致细胞外酸化并激活酸感应离子通道 1a。

IF 3.6 2区 医学 Q1 PHYSIOLOGY
Megan N Tuineau, Lindsay M Herbert, Selina M Garcia, Thomas C Resta, Nikki L Jernigan
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引用次数: 0

摘要

在肺动脉高压(PHTN)患者中,有氧糖酵解的代谢转变促进了肺动脉平滑肌细胞(PASMC)的过度增殖和抗凋亡表型。糖酵解增强会诱导细胞外酸中毒,从而激活质子感应膜受体和离子通道。我们以前曾报道过,质子门控阳离子通道--酸感应离子通道 1a(ASIC1a)--的激活有助于缺氧性 PHTN 的形成。因此,我们假设糖酵解的增强和随后 PASMC 细胞外微环境的酸化激活了缺氧性 PHTN 中的 ASIC1a。我们在慢性缺氧(CH)诱导的 PHTN 大鼠的 PASMC 中观察到耗氧率降低和细胞外酸化率升高,这表明有氧糖酵解发生了转变。此外,我们还发现,PASMC 在慢性缺氧和体外缺氧后会出现细胞内碱化和细胞外酸化,而用 2-D 葡萄糖(2-DG)抑制糖酵解可防止这种现象。通过碳酸酐酶 IX、Na+/H+ 交换子 1 或空泡型 H+-ATP 酶抑制 H+ 的转运/分泌并不能阻止缺氧后的 pH 值变化。尽管推测的单羧酸盐转运体 1(MCT1)和-4(MCT4)抑制剂西罗新君碱阻止了 pH 值的改变;但特异性 MCT1 抑制剂 AZD3965 和/或 MCT4 抑制剂 VB124 却没有效果,这表明西罗新君碱针对的是糖酵解途径,而与 H+ 的输出无关。此外,2-DG 和 syrosingopine 还能阻止 CH 大鼠 PASMC 中 ASIC1a 介导的储存操作 Ca2+ 输入的增强。这些数据表明,多种 H+ 转运机制导致了细胞外酸中毒,而抑制糖酵解而不是特定的 H+ 转运体能更有效地防止细胞外酸化和 ASIC1a 激活。这些数据共同揭示了缺氧性 PHTN 中糖酵解和 ASIC1a 激活之间的新型病理关系。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Enhanced glycolysis causes extracellular acidification and activates acid-sensing ion channel 1a in hypoxic pulmonary hypertension.

In pulmonary hypertension (PHTN), a metabolic shift to aerobic glycolysis promotes a hyperproliferative, apoptosis-resistant phenotype in pulmonary arterial smooth muscle cells (PASMCs). Enhanced glycolysis induces extracellular acidosis, which can activate proton-sensing membrane receptors and ion channels. We previously reported that activation of the proton-gated cation channel acid-sensing ion channel 1a (ASIC1a) contributes to the development of hypoxic PHTN. Therefore, we hypothesize that enhanced glycolysis and subsequent acidification of the PASMC extracellular microenvironment activate ASIC1a in hypoxic PHTN. We observed decreased oxygen consumption rate and increased extracellular acidification rate in PASMCs from chronic hypoxia (CH)-induced PHTN rats, indicating a shift to aerobic glycolysis. In addition, we found that intracellular alkalization and extracellular acidification occur in PASMCs following CH and in vitro hypoxia, which were prevented by the inhibition of glycolysis with 2-deoxy-d-glucose (2-DG). Inhibiting H+ transport/secretion through carbonic anhydrases, Na+/H+ exchanger 1, or vacuolar-type H+-ATPase did not prevent this pH shift following hypoxia. Although the putative monocarboxylate transporter 1 (MCT1) and -4 (MCT4) inhibitor syrosingopine prevented the pH shift, the specific MCT1 inhibitor AZD3965 and/or the MCT4 inhibitor VB124 were without effect, suggesting that syrosingopine targets the glycolytic pathway independent of H+ export. Furthermore, 2-DG and syrosingopine prevented enhanced ASIC1a-mediated store-operated Ca2+ entry in PASMCs from CH rats. These data suggest that multiple H+ transport mechanisms contribute to extracellular acidosis and that inhibiting glycolysis-rather than specific H+ transporters-more effectively prevents extracellular acidification and ASIC1a activation. Together, these data reveal a novel pathological relationship between glycolysis and ASIC1a activation in hypoxic PHTN.NEW & NOTEWORTHY In pulmonary hypertension, a metabolic shift to aerobic glycolysis drives a hyperproliferative, apoptosis-resistant phenotype in pulmonary arterial smooth muscle cells. We demonstrate that this enhanced glycolysis induces extracellular acidosis and activates the proton-gated ion channel, acid-sensing ion channel 1a (ASIC1a). Although multiple H+ transport/secretion mechanisms are upregulated in PHTN and likely contribute to extracellular acidosis, inhibiting glycolysis with 2-deoxy-d-glucose or syrosingopine effectively prevents extracellular acidification and ASIC1a activation, revealing a promising therapeutic avenue.

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来源期刊
CiteScore
9.20
自引率
4.10%
发文量
146
审稿时长
2 months
期刊介绍: The American Journal of Physiology-Lung Cellular and Molecular Physiology publishes original research covering the broad scope of molecular, cellular, and integrative aspects of normal and abnormal function of cells and components of the respiratory system. Areas of interest include conducting airways, pulmonary circulation, lung endothelial and epithelial cells, the pleura, neuroendocrine and immunologic cells in the lung, neural cells involved in control of breathing, and cells of the diaphragm and thoracic muscles. The processes to be covered in the Journal include gas-exchange, metabolic control at the cellular level, intracellular signaling, gene expression, genomics, macromolecules and their turnover, cell-cell and cell-matrix interactions, cell motility, secretory mechanisms, membrane function, surfactant, matrix components, mucus and lining materials, lung defenses, macrophage function, transport of salt, water and protein, development and differentiation of the respiratory system, and response to the environment.
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