Neutrophil NADPH oxidase breaks the inflammatory IL-1beta/IL-17A circuit to enhance pathogen clearance during respiratory virus infections.

Aderonke Sofoluwe, Angelos Petropoulos, Abhilesh Salil Goomanee, Zehra Fatima Ali-Khan, Annika Warnatsch
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Abstract

Respiratory virus infections are invariably accompanied by an increase in oxidative stress, characterised by elevated production of Reactive Oxygen Species (ROS) in the lung, which plays a pivotal role in both pathogenesis and host defence. Using a mouse model, neutrophil NADPH Oxidase 2 (Nox2) emerges as a key player, primarily responsible for generation of ROS during the early phases of Influenza A Virus (IAV) infection. Neutrophil Nox2-derived ROS display a multifaceted role, not only unleashing oxidative stress but in turn curbing Neutrophil-derived IL-1beta signalling. Absence of neutrophil Nox2 triggered heightened production of IL-1β, promoting the proliferation of IL-17-producing gamma delta (gamma delta) T cells. This early self-amplified augmentation of the IL-beta/IL-17 axis counteracted the antiviral interferon response against IAV infection in mice. We extended our findings to humans. Similar patterns of ROS production and cytokine regulation were observed in human neutrophils when exposed to virus analogue poly(I:C) and SARS-CoV-2. Our discovery highlights that ROS, often associated with harm, play a dual role by regulating cytokine signalling and thus influencing the immune response against respiratory viruses.
中性粒细胞 NADPH 氧化酶打破了炎症 IL-1beta/IL-17A 循环,从而增强了呼吸道病毒感染期间的病原体清除能力。
呼吸道病毒感染总是伴随着氧化应激的增加,其特点是肺部活性氧(ROS)的产生增加,这在致病机理和宿主防御中都起着关键作用。通过小鼠模型,中性粒细胞 NADPH 氧化酶 2(Nox2)成为一个关键角色,主要负责在甲型流感病毒(IAV)感染的早期阶段产生 ROS。中性粒细胞 Nox2 衍生的 ROS 发挥着多方面的作用,不仅释放氧化应激,还反过来抑制中性粒细胞衍生的 IL-1beta 信号。中性粒细胞 Nox2 的缺失会导致 IL-1β 生成增加,促进产生 IL-17 的γ-δ(γ-δ)T 细胞的增殖。这种IL-β/IL-17轴的早期自我增强抵消了小鼠对IAV感染的抗病毒干扰素反应。我们将研究结果推广到人类。当人类中性粒细胞暴露于病毒类似物 poly(I:C) 和 SARS-CoV-2 时,也观察到了类似的 ROS 生成和细胞因子调节模式。我们的发现突出表明,ROS 通常与危害相关,但它通过调节细胞因子信号发挥双重作用,从而影响对呼吸道病毒的免疫反应。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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