Douam Florian, Soto Albrecht Yentli E, Hrebikova Gabriela, Sadimin Evita, Davidson Christian, Kotenko Sergei V, Ploss Alexander
Department of Molecular Biology, Princeton University, Princeton, New Jersey, USA.
Department of Pathology, Rutgers Cancer Institute of New Jersey, Rutgers Robert Wood Johnson Medical School, New Brunswick, New Jersey, USA.
mBio. 2017 Aug 15;8(4):e00819-17. doi: 10.1128/mBio.00819-17.
Yellow fever virus (YFV) is an arthropod-borne flavivirus, infecting ~200,000 people worldwide annually and causing about 30,000 deaths. The live attenuated vaccine strain, YFV-17D, has significantly contributed in controlling the global burden of yellow fever worldwide. However, the viral and host contributions to YFV-17D attenuation remain elusive. Type I interferon (IFN-α/β) signaling and type II interferon (IFN-γ) signaling have been shown to be mutually supportive in controlling YFV-17D infection despite distinct mechanisms of action in viral infection. However, it remains unclear how type III IFN (IFN-λ) integrates into this antiviral system. Here, we report that while wild-type (WT) and IFN-λ receptor knockout (λR) mice were largely resistant to YFV-17D, deficiency in type I IFN signaling resulted in robust infection. Although IFN-α/β receptor knockout (α/βR) mice survived the infection, mice with combined deficiencies in both type I signaling and type III IFN signaling were hypersusceptible to YFV-17D and succumbed to the infection. Mortality was associated with viral neuroinvasion and increased permeability of the blood-brain barrier (BBB). α/βR λR mice also exhibited distinct changes in the frequencies of multiple immune cell lineages, impaired T-cell activation, and severe perturbation of the proinflammatory cytokine balance. Taken together, our data highlight that type III IFN has critical immunomodulatory and neuroprotective functions that prevent viral neuroinvasion during active YFV-17D replication. Type III IFN thus likely represents a safeguard mechanism crucial for controlling YFV-17D infection and contributing to shaping vaccine immunogenicity. YFV-17D is a live attenuated flavivirus vaccine strain recognized as one of the most effective vaccines ever developed. However, the host and viral determinants governing YFV-17D attenuation and its potent immunogenicity are still unknown. Here, we analyzed the role of type III interferon (IFN)-mediated signaling, a host immune defense mechanism, in controlling YFV-17D infection and attenuation in different mouse models. We uncovered a critical role of type III IFN-mediated signaling in preserving the integrity of the blood-brain barrier and preventing viral brain invasion. Type III IFN also played a major role in regulating the induction of a potent but balanced immune response that prevented viral evasion of the host immune system. An improved understanding of the complex mechanisms regulating YFV-17D attenuation will provide insights into the key virus-host interactions that regulate host immune responses and infection outcomes as well as open novel avenues for the development of innovative vaccine strategies.
黄热病病毒(YFV)是一种节肢动物传播的黄病毒,每年在全球感染约20万人,并导致约3万例死亡。减毒活疫苗株YFV-17D在控制全球黄热病负担方面做出了重大贡献。然而,病毒和宿主对YFV-17D减毒的作用仍不清楚。I型干扰素(IFN-α/β)信号传导和II型干扰素(IFN-γ)信号传导在控制YFV-17D感染方面已显示出相互支持的作用,尽管它们在病毒感染中的作用机制不同。然而,尚不清楚III型干扰素(IFN-λ)如何融入这一抗病毒系统。在此,我们报告,虽然野生型(WT)和IFN-λ受体敲除(λR)小鼠对YFV-17D基本具有抗性,但I型干扰素信号传导缺陷会导致严重感染。尽管IFN-α/β受体敲除(α/βR)小鼠在感染后存活下来,但I型信号传导和III型干扰素信号传导均有缺陷的小鼠对YFV-17D高度敏感,并死于感染。死亡率与病毒神经侵袭和血脑屏障(BBB)通透性增加有关。α/βR λR小鼠在多种免疫细胞谱系的频率、T细胞活化受损以及促炎细胞因子平衡的严重紊乱方面也表现出明显变化。综上所述,我们的数据表明,III型干扰素具有关键的免疫调节和神经保护功能,可在YFV-17D活跃复制期间防止病毒神经侵袭。因此,III型干扰素可能代表一种对控制YFV-17D感染和形成疫苗免疫原性至关重要的保护机制。YFV-17D是一种减毒活黄病毒疫苗株,被认为是有史以来开发的最有效的疫苗之一。然而,控制YFV-17D减毒及其强大免疫原性的宿主和病毒决定因素仍然未知。在此,我们分析了III型干扰素(IFN)介导的信号传导(一种宿主免疫防御机制)在不同小鼠模型中控制YFV-17D感染和减毒中的作用。我们发现III型干扰素介导的信号传导在维持血脑屏障完整性和防止病毒脑侵袭方面起着关键作用。III型干扰素在调节有效但平衡的免疫反应诱导中也发挥了主要作用,该免疫反应可防止病毒逃避宿主免疫系统。更好地理解调节YFV-17D减毒的复杂机制将为调节宿主免疫反应和感染结果的关键病毒-宿主相互作用提供见解,并为开发创新疫苗策略开辟新途径。
