Endothelial PHD2 deficiency induces apoptosis resistance and inflammation via AKT activation and AIP1 loss independent of HIF2α.

IF 3.6 2区 医学 Q1 PHYSIOLOGY
Shuibang Wang, Keytam S Awad, Li-Yuan Chen, Mohammad A H Siddique, Gabriela A Ferreyra, Caroline L Wang, Thea Joseph, Zu-Xi Yu, Kazuyo Takeda, Cumhur Y Demirkale, You-Yang Zhao, Jason M Elinoff, Robert L Danner
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引用次数: 0

Abstract

In hypoxic and pseudohypoxic rodent models of pulmonary hypertension (PH), hypoxia-inducible factor (HIF) inhibition attenuates disease initiation. However, HIF activation alone, due to genetic alterations or use of inhibitors of prolyl hydroxylase domain (PHD) enzymes, has not been definitively shown to cause PH in humans, indicating the involvement of other mechanisms. Given the association between endothelial cell dysfunction and PH, the effects of pseudohypoxia and its underlying pathways were investigated in primary human lung endothelial cells. PHD2 silencing or inhibition, while activating HIF2α, induced apoptosis-resistance and IFN/STAT activation in endothelial cells, independent of HIF signaling. Mechanistically, PHD2 deficiency activated AKT and ERK, inhibited JNK, and reduced AIP1 (ASK1-interacting protein 1), all independent of HIF2α. Like PHD2, AIP1 silencing affected these same kinase pathways and produced a similar dysfunctional endothelial cell phenotype, which was partially reversed by AKT inhibition. Consistent with these in vitro findings, AIP1 protein levels in lung endothelial cells were decreased in Tie2-Cre/Phd2 knockout mice compared with wild-type controls. Lung vascular endothelial cells from patients with pulmonary arterial hypertension (PAH) showed IFN/STAT activation. Lung tissue from both SU5416/hypoxia PAH rats and patients with PAH all showed AKT activation and dysregulated AIP1 expression. In conclusion, PHD2 deficiency in lung vascular endothelial cells drives an apoptosis-resistant and inflammatory phenotype, mediated by AKT activation and AIP1 loss independent of HIF signaling. Targeting these pathways, including PHD2, AKT, and AIP1, holds the potential for developing new treatments for endothelial dysfunction in PH.NEW & NOTEWORTHY HIF activation alone does not conclusively lead to human PH, suggesting that HIF-independent signaling may also contribute to hypoxia-induced PH. This study demonstrated that PHD2 silencing-induced pseudohypoxia in human lung endothelial cells suppresses apoptosis and activates STAT, effects that persist despite HIF2α inhibition or knockdown and are attributed to AKT and ERK activation, JNK inhibition, and AIP1 loss. These findings align with observations in lung endothelial cells and tissues from PAH rodent models and patients.

内皮 PHD2 缺乏可通过 AKT 激活和 AIP1 丢失诱导凋亡抵抗和炎症,而与 HIF2α 无关。
在肺动脉高压(PH)的缺氧和假缺氧啮齿类动物模型中,抑制缺氧诱导因子(HIF)可减轻疾病的发生。然而,由于基因改变或使用脯氨酰羟化酶域(PHD)酶抑制剂,仅激活 HIF 并未明确显示会导致人类 PH,这表明还有其他机制参与其中。鉴于内皮细胞功能障碍与 PH 之间的关联,研究人员在原代人类肺内皮细胞中研究了假缺氧及其潜在途径的影响。在激活 HIF2α 的同时,PHD2 的沉默或抑制诱导了内皮细胞的凋亡抵抗和 IFN/STAT 激活,与 HIF 信号无关。从机制上讲,PHD2 缺乏会激活 AKT 和 ERK、抑制 JNK 并减少 AIP1(ASK1-交互蛋白 1),所有这些都与 HIF2α 无关。与 PHD2 一样,沉默 AIP1 也会影响这些相同的激酶通路,并产生类似的功能障碍内皮细胞表型,而抑制 AKT 可部分逆转这些表型。与这些体外研究结果一致的是,与野生型对照组相比,Tie2-Cre/Phd2 基因敲除小鼠肺血管内皮细胞中的 AIP1 蛋白水平降低了。肺动脉高压(PAH)患者的肺血管内皮细胞显示出 IFN/STAT 激活。来自 SU5416/缺氧 PAH 大鼠和 PAH 患者的肺组织均显示 AKT 激活和 AIP1 表达失调。总之,肺血管内皮细胞中 PHD2 的缺乏会导致抗凋亡和炎症表型,这种表型由 AKT 激活和 AIP1 丢失介导,与 HIF 信号无关。以这些通路(包括 PHD2、AKT 和 AIP1)为靶点,有望开发出治疗 PH 内皮功能障碍的新疗法。
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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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