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巨噬细胞Dvl2缺乏促进nod1驱动的焦亡，加重炎症性肝损伤

IF 10.7 1区生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY

Redox Biology Pub Date : 2025-02-01 DOI:10.1016/j.redox.2024.103455

Xiaoye Qu , Dongwei Xu , Tao Yang , Yizhu Tian , Christopher T. King , Xiao Wang , Mingwei Sheng , Yuanbang Lin , Xiyun Bian , Changyong Li , Longfeng Jiang , Qiang Xia , Douglas G. Farmer , Bibo Ke

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引用次数: 0

摘要

disheveled 2 （Dvl2）是调节细胞增殖、迁移和免疫功能的无翼/Wnt信号通路的关键介质。然而，在氧化应激诱导的炎症性肝损伤中，巨噬细胞Dvl2在调节nod1介导的焦亡和肝细胞死亡中的作用知之甚少。在氧化应激诱导的肝脏炎症小鼠模型中，骨髓特异性Dvl2M - KO敲除小鼠随着血清ALT水平、氧化应激和促炎介质的增加，表现出缺血/再灌注（IR）应激诱导的肝细胞损伤加剧。与Dvl2FL/FL对照不同，IR后，Dvl2M−KO增强了肝巨噬细胞NOD1、caspase-1、GSDMD和NF-κB的激活。有趣的是，IR应激增强了Dvl2FL/FL巨噬细胞中YAP与HSF1的共定位，而巨噬细胞Dvl2缺乏则降低了炎症条件下细胞核中YAP和HSF1的共定位。重要的是，Dvl2缺失减少了核YAP与HSF1相互作用，增强了NOD1/caspase-1和GSDMD在炎症刺激下的激活。然而，Dvl2的激活增加了YAP与HSF1的相互作用，激活了HSF1靶基因eEF2，抑制了NOD1/caspase-1、GSDMD和NF-κB的活性。此外，巨噬细胞eEF2缺失增加了巨噬细胞/肝细胞共培养后NOD1-caspase-1相互作用、GSDMD激活、HMGB1释放和肝细胞LDH释放。在Dvl2M−KO小鼠中过继转移表达eef2的巨噬细胞可减轻ir引发的肝脏炎症和肝细胞损伤。因此，巨噬细胞Dvl2缺乏通过破坏YAP-HSF1轴，促进nod1介导的焦亡，并加剧ir诱导的肝细胞死亡。eEF2对于调节nod1驱动的焦亡、炎症反应和肝细胞死亡至关重要。我们的研究结果强调了巨噬细胞Dvl2在调节肝脏炎症损伤中的新作用，并暗示了器官IRI和移植受体的治疗潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Macrophage Dvl2 deficiency promotes NOD1-Driven pyroptosis and exacerbates inflammatory liver injury

查看原文本刊更多论文

Macrophage Dvl2 deficiency promotes NOD1-Driven pyroptosis and exacerbates inflammatory liver injury

Dishevelled 2 (Dvl2) is a key mediator of the Wingless/Wnt signaling pathway that regulates cell proliferation, migration, and immune function. However, little is known about the role of macrophage Dvl2 in modulating NOD1-mediated pyroptosis and hepatocyte death in oxidative stress-induced inflammatory liver injury. In a mouse model of oxidative stress-induced liver inflammation, mice with myeloid-specific Dvl2 knockout (Dvl2^M−KO) displayed exacerbated ischemia/reperfusion (IR) stress-induced hepatocellular damage with increased serum ALT levels, oxidative stress, and proinflammatory mediators. Unlike in Dvl2^FL/FL controls, Dvl2^M−KO enhanced NOD1, caspase-1, GSDMD, and NF-κB activation in liver macrophages after IR. Interestingly, IR stress enhanced YAP colocalized with HSF1 in Dvl2^FL/FL macrophages, while macrophage Dvl2 deficiency reduced YAP and HSF1 colocalization in the nucleus under inflammatory conditions. Importantly, Dvl2 deletion diminished nuclear YAP interacted with HSF1 and augmented NOD1/caspase-1 and GSDMD activation in response to inflammatory stimulation. However, Dvl2 activation increased YAP interaction with HSF1 and activated HSF1 target gene eEF2, inhibiting NOD1/caspase-1, GSDMD, and NF-κB activity. Moreover, macrophage eEF2 deletion increased the NOD1-caspase-1 interaction, GSDMD activation, HMGB1 release, and hepatocyte LDH release after macrophage/hepatocyte co-culture. Adoptive transfer of eEF2-expressing macrophages in Dvl2^M−KO mice alleviated IR-triggered liver inflammation and hepatocellular damage. Therefore, macrophage Dvl2 deficiency promotes NOD1-mediated pyroptosis and exacerbates IR-induced hepatocellular death by disrupting the YAP-HSF1 axis. eEF2 is crucial for modulating NOD1-driven pyroptosis, inflammatory response, and hepatocyte death. Our findings underscore a novel role of macrophage Dvl2 in modulating liver inflammatory injury and imply the therapeutic potential in organ IRI and transplant recipients.

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来源期刊

Redox Biology

Redox Biology BIOCHEMISTRY & MOLECULAR BIOLOGY-

CiteScore

19.90

自引率

3.50%

发文量

318

审稿时长

25 days

期刊介绍： Redox Biology is the official journal of the Society for Redox Biology and Medicine and the Society for Free Radical Research-Europe. It is also affiliated with the International Society for Free Radical Research (SFRRI). This journal serves as a platform for publishing pioneering research, innovative methods, and comprehensive review articles in the field of redox biology, encompassing both health and disease. Redox Biology welcomes various forms of contributions, including research articles (short or full communications), methods, mini-reviews, and commentaries. Through its diverse range of published content, Redox Biology aims to foster advancements and insights in the understanding of redox biology and its implications.

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