Catera L Wilder, Diane Lefaudeux, Raisa Mathenge, Kensei Kishimoto, Alma Zuniga Munoz, Minh A Nguyen, Aaron S Meyer, Quen J Cheng, Alexander Hoffmann
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引用次数: 0
摘要
I 型干扰素(IFN)通过转录因子 IFN 刺激基因因子(ISGF3)诱导强大的抗病毒和先天性免疫反应。然而,在某些病理情况下,I 型干扰素会加剧炎症。在这里,我们发现高剂量的 IFN-β 也能激活炎症基因表达程序,而 IFN-λ3(一种 III 型 IFN)只能激发普通的抗病毒基因程序。我们的研究表明,炎症基因程序取决于 ISGF3 激活过程中的第二个增效阶段。通过数学建模和实验分析,我们发现 ISGF3 激活网络可能与其亚基 IRF9 和 STAT2 形成正反馈回路。这种网络模式介导了刺激特异性 ISGF3 动态,这种动态依赖于配体、剂量和暴露持续时间,一旦参与就会激活炎症基因表达程序。我们的研究结果揭示了以前未被重视的 JAK-STAT/IRF 信号转导网络的动态控制,它可能会产生不同的生物反应,并表明对 I 型 IFN 失调的研究以及治疗方法可能会侧重于其中的反馈调节因子。
A stimulus-contingent positive feedback loop enables IFN-β dose-dependent activation of pro-inflammatory genes.
Type I interferons (IFN) induce powerful antiviral and innate immune responses via the transcription factor, IFN-stimulated gene factor (ISGF3). However, in some pathological contexts, type I IFNs are responsible for exacerbating inflammation. Here, we show that a high dose of IFN-β also activates an inflammatory gene expression program in contrast to IFN-λ3, a type III IFN, which elicits only the common antiviral gene program. We show that the inflammatory gene program depends on a second, potentiated phase in ISGF3 activation. Iterating between mathematical modeling and experimental analysis, we show that the ISGF3 activation network may engage a positive feedback loop with its subunits IRF9 and STAT2. This network motif mediates stimulus-specific ISGF3 dynamics that are dependent on ligand, dose, and duration of exposure, and when engaged activates the inflammatory gene expression program. Our results reveal a previously underappreciated dynamical control of the JAK-STAT/IRF signaling network that may produce distinct biological responses and suggest that studies of type I IFN dysregulation, and in turn therapeutic remedies, may focus on feedback regulators within it.
期刊介绍:
Systems biology is a field that aims to understand complex biological systems by studying their components and how they interact. It is an integrative discipline that seeks to explain the properties and behavior of these systems.
Molecular Systems Biology is a scholarly journal that publishes top-notch research in the areas of systems biology, synthetic biology, and systems medicine. It is an open access journal, meaning that its content is freely available to readers, and it is peer-reviewed to ensure the quality of the published work.
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