RIPK3和Caspase-8解读细胞因子信号,调节肠道中ILC3的存活。

IF 7.9 2区 医学 Q1 IMMUNOLOGY
Ann M Joseph, Anees Ahmed, Jeremy Goc, Veronika Horn, Brooke Fiedler, Dario Garone, John B Grigg, Jazib Uddin, Fei Teng, Melanie Fritsch, Eric Vivier, Gregory F Sonnenberg
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引用次数: 0

摘要

第 3 组先天性淋巴细胞(ILC3s)在发育中或健康的肠道中含量丰富,能在微生物定植时为组织稳态提供重要支持。然而,在慢性感染、结直肠癌或炎症性肠病(IBD)期间,肠道 ILC3s 会减少,而驱动这些变化的机制仍不甚明了。在这里,我们对来自 IBD 患者的 ILC3s 进行了 RNA 测序,观察到在肠道炎症期间,坏死的核心调节因子 RIPK3 有显著上调。我们在小鼠中建立了这一模型,发现肠道 ILC3s 表达 RIPK3,相对于淋巴组织诱导剂(LTi)类 ILC3s,传统(c)ILC3s 表现出高 RIPK3 和低水平的促生存基因。ILC3特异性RIPK3受肠道微生物群的促进,在肠道感染后进一步上调,并依赖于IL-23R和STAT3信号。然而,行系特异性缺失 RIPK3 发现在 ILC3 存活过程中起着多余的作用,这是因为 RIPK3 介导的坏死被 caspase 8 阻断,而 caspase 8 也在肠道感染时被激活。与此相反,在肠道感染期间,caspase 8 的系特异性缺失会导致健康肠道和所有 ILC3 亚群中的 cILC3 损失,从而增加病原体负担和肠道炎症。Caspase 8的这种功能需要TNF或TL1A诱导的催化活性,如果同时删除RIPK3,这种功能就不存在了。Caspase 8的激活和细胞死亡与ILC3上Fas的增加有关,肠道感染期间cILC3s上调了Fas-FasL通路,这可能会抑制肠道ILC3的数量。总之,这些数据揭示了关键细胞因子信号的解释控制着微生物挑战后 ILC3 的存活,而这些通路的失衡,如在 IBD 或不同 ILC3 亚群中,会导致炎症肠道中组织保护性 ILC3 的耗竭。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
RIPK3 and caspase-8 interpret cytokine signals to regulate ILC3 survival in the gut.

Group 3 innate lymphoid cells (ILC3s) are abundant in the developing or healthy intestine to critically support tissue homeostasis in response to microbial colonization. However, intestinal ILC3s are reduced during chronic infections, colorectal cancer, or inflammatory bowel disease (IBD), and the mechanisms driving these alterations remain poorly understood. Here we employed RNA sequencing of ILC3s from IBD patients and observed a significant upregulation of RIPK3, the central regulator of necroptosis, during intestinal inflammation. This was modeled in mice where we found that intestinal ILC3s express RIPK3, with conventional (c)ILC3s exhibiting high RIPK3 and low levels of pro-survival genes relative to lymphoid tissue inducer (LTi)-like ILC3s. ILC3-specific RIPK3 is promoted by gut microbiota, further upregulated following enteric infection, and dependent upon IL-23R and STAT3 signaling. However, lineage-specific deletion of RIPK3 revealed a redundant role in ILC3 survival, due to a blockade of RIPK3-mediated necroptosis by caspase 8, which was also activated in response to enteric infection. In contrast, lineage-specific deletion of caspase 8 resulted in loss of cILC3s from the healthy intestine and all ILC3 subsets during enteric infection, which increased pathogen burdens and gut inflammation. This function of caspase 8 required catalytic activity induced by TNF or TL1A and was dispensable if RIPK3 was simultaneously deleted. Caspase 8 activation and cell death were associated with increased Fas on ILC3s, and the Fas-FasL pathway was upregulated by cILC3s during enteric infection, which could restrain the abundance of intestinal ILC3s. Collectively, these data reveal that interpretation of key cytokine signals controls ILC3 survival following microbial challenge, and that an imbalance of these pathways, such as in IBD or across ILC3 subsets, provokes depletion of tissue-protective ILC3s from the inflamed intestine.

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来源期刊
Mucosal Immunology
Mucosal Immunology 医学-免疫学
CiteScore
16.60
自引率
3.80%
发文量
100
审稿时长
12 days
期刊介绍: Mucosal Immunology, the official publication of the Society of Mucosal Immunology (SMI), serves as a forum for both basic and clinical scientists to discuss immunity and inflammation involving mucosal tissues. It covers gastrointestinal, pulmonary, nasopharyngeal, oral, ocular, and genitourinary immunology through original research articles, scholarly reviews, commentaries, editorials, and letters. The journal gives equal consideration to basic, translational, and clinical studies and also serves as a primary communication channel for the SMI governing board and its members, featuring society news, meeting announcements, policy discussions, and job/training opportunities advertisements.
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