Human IFN-κ Inhibited Respiratory RNA Virus Replication Dependent on Cell-to-Cell Interaction in the Early Phase

Infectious diseases & immunity Pub Date : 2021-03-24 DOI:10.1097/ID9.0000000000000049

Weihui Fu, P. Sun, Jun Fan, Longfei Ding, S. Yuan, Guanxing Zhai, Miaomiao Zhang, C. Qiu, Shuye Zhang, Xiaoyan Zhang, Jianqing Xu

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引用次数: 1

Abstract

Abstract Background: Interferon kappa (IFN-κ) is a type I interferon (IFN-I) that inhibits virus replication by evoking interferon-stimulated genes (ISGs). However, as an evolutionarily ancient interferon, IFN-κ may function differently from the later emerged interferon-α and β. Methods: Conventional molecular biology methods were used to determine the localization of IFN-κ and its structure and function. In addition, we employed RT-PCR, western blot, and RNA-Seq technologies to characterize the ISGs expression profile and antiviral activities exerted by IFN-κ or IFN-α2. Results: Human IFN-κ exists in two forms upon ectopic expression, one located on the cell membrane and the other secreted outside the cells. The membrane-anchored IFN-κ showed the ability to induce ISGs and curtail RNA virus replication, whereas the secreted IFN-κ failed to do so. Structural analyses indicated that 1-27aa at the N-terminus was the signal peptide, and 28-37aa was predicted as the transmembrane region. However, our data demonstrated that both of them were not associated with membrane localization of IFN-κ; the former influenced the expression and secretion of IFN-κ, and the latter had an impact on the induction of ISGs. In addition, prokaryotic purified soluble mature human IFN-κ was also capable of inducing ISGs and inhibiting RNA virus replication. Importantly, human IFN-κ induced a faster ISG response but with a lower intensity and a shorter half-life than the response of IFN-α2. In contrast, IFN-α2 started to function later but was stronger and more durable than IFN-κ. Conclusions: Human IFN-κ-induced ISG response and inhibited respiratory RNA virus replication dependent on cell-to-cell interactions. In addition, compared with IFN-α2, IFN-κ exerted effects more rapidly in the early phase, with less intensity and a shorter half-life. Therefore, IFN-κ may constitute the first line of IFN-I against respiratory virus infections.

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人IFN-κ在早期依赖细胞间相互作用抑制呼吸道RNA病毒复制

摘要背景：干扰素-κ（IFN-κ）是一种I型干扰素（IFN-I），通过激发干扰素刺激基因（ISG）来抑制病毒复制。然而，作为一种进化上古老的干扰素，IFN-κ的功能可能与后来出现的干扰素-α和β不同。方法：采用常规分子生物学方法对IFN-κ的定位及其结构和功能进行测定。此外，我们采用RT-PCR、蛋白质印迹和RNA-Seq技术来表征ISGs的表达谱和IFN-κ或IFN-α2的抗病毒活性。结果：人IFN-κ在异位表达时以两种形式存在，一种位于细胞膜上，另一种分泌于细胞外。膜锚定的IFN-κ显示出诱导ISGs和抑制RNA病毒复制的能力，而分泌的IFN-NF-κ则不能做到这一点。结构分析表明，N末端的1-27aa是信号肽，28-37aa被预测为跨膜区。然而，我们的数据表明，它们都与IFN-κ的膜定位无关；前者影响IFN-κ的表达和分泌，后者影响ISGs的诱导。此外，原核纯化的可溶性成熟人IFN-κ也能诱导ISG并抑制RNA病毒复制。重要的是，与IFN-α2的反应相比，人类IFN-κ诱导了更快的ISG反应，但强度更低，半衰期更短。相反，IFN-α2开始发挥作用的时间较晚，但比IFN-κ更强、更持久。结论：人IFN-κ诱导ISG反应并抑制呼吸道RNA病毒的复制依赖于细胞间的相互作用。此外，与IFN-α2相比，IFN-κ在早期发挥作用更快，强度更小，半衰期更短。因此，IFN-κ可能构成IFN-Ⅰ对抗呼吸道病毒感染的第一条线。

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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Infectious diseases & immunity

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