代谢重编程通过稳定干扰素-γ诱导的IRF1来提示疫苗病毒感染的结果。

IF 5.5 1区 医学 Q1 MICROBIOLOGY PLoS Pathogens Pub Date : 2024-10-30 eCollection Date: 2024-10-01 DOI:10.1371/journal.ppat.1012673
Tyron Chang, Jessica Alvarez, Sruthi Chappidi, Stacey Crockett, Mahsa Sorouri, Robert C Orchard, Dustin C Hancks
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引用次数: 0

摘要

干扰素(IFN)的诱导活动是免疫反应和感染结果的关键性早期决定因素。IFN 反应的一个关键方面是上调数百种被称为干扰素刺激基因(ISG)的 mRNA,从而激活内在和细胞介导的防御功能。虽然初级干扰素信号传导已被明确界定,但其他层次的调控却鲜有探索,但许多疾病在没有感染的情况下都会出现异常的 ISG 表达特征。同样,我们对未感染人体组织和个体的强直性 ISG 水平的研究发现了三种 ISG 亚类。由于组织特征和许多病毒易感性增加的合并症都以新陈代谢的差异为特征,我们对在已知有利于有氧糖酵解(葡萄糖)或氧化磷酸化(补充半乳糖)的培养基中生长的细胞的 ISG 反应进行了研究。虽然随着时间的推移,这些条件对 ISG RNA 的表达产生了不同的影响,但不同处理之间的差异通常大于葡萄糖/半乳糖之间的差异。有趣的是,延长干扰素诱导会导致两种 ISG 蛋白的不同表达:在 IFN-γ/ 葡萄糖中,IRF1 上调;而在半乳糖中,IFITM3 在 IFN-α 和 IFN-γ 的作用下增加。葡萄糖/半乳糖对干扰素-γ诱导的IRF1的调节在无关的小鼠和猫细胞类型中是一致的,这与硬连接反应一致。在半乳糖条件下,蛋白酶体抑制可使干扰素-γ诱导的IRF1水平恢复到葡萄糖/干扰素-γ的水平。葡萄糖/干扰素-γ在低MOI和高MOI下都能减少模式痘病毒疫苗的复制。IRF1 KO 可恢复疫苗病毒的复制。相反,但与葡萄糖/半乳糖对 IRF1 蛋白的不同调节作用一致的是,无论 IFN-γ 是否起效,WT 和 IRF1 KO 细胞在半乳糖培养基中支持相似水平的疫苗病毒复制。同样与葡萄糖/半乳糖相关的是病毒复制后期似乎出现的第二个阻滞,它导致疱疹病毒和痘病毒滴度降低,但病毒蛋白表达却没有降低。总之,这些数据说明了由葡萄糖/半乳糖介导的对关键 ISG 蛋白 IRF1 的新的调节层,并暗示了干扰素反应中未被重视的子程序。原则上,这种细胞回路可以通过感知病毒复制和细胞增殖过程中消耗的代谢物水平的变化,迅速调整免疫反应。
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Metabolic reprogramming tips vaccinia virus infection outcomes by stabilizing interferon-γ induced IRF1.

Interferon (IFN) induced activities are critical, early determinants of immune responses and infection outcomes. A key facet of IFN responses is the upregulation of hundreds of mRNAs termed interferon-stimulated genes (ISGs) that activate intrinsic and cell-mediated defenses. While primary interferon signaling is well-delineated, other layers of regulation are less explored but implied by aberrant ISG expression signatures in many diseases in the absence of infection. Consistently, our examination of tonic ISG levels across uninfected human tissues and individuals revealed three ISG subclasses. As tissue identity and many comorbidities with increased virus susceptibility are characterized by differences in metabolism, we characterized ISG responses in cells grown in media known to favor either aerobic glycolysis (glucose) or oxidative phosphorylation (galactose supplementation). While these conditions over time had a varying impact on the expression of ISG RNAs, the differences were typically greater between treatments than between glucose/galactose. Interestingly, extended interferon-priming led to divergent expression of two ISG proteins: upregulation of IRF1 in IFN-γ/glucose and increased IFITM3 in galactose by IFN-α and IFN-γ. In agreement with a hardwired response, glucose/galactose regulation of interferon-γ induced IRF1 is conserved in unrelated mouse and cat cell types. In galactose conditions, proteasome inhibition restored interferon-γ induced IRF1 levels to that of glucose/interferon-γ. Glucose/interferon-γ decreased replication of the model poxvirus vaccinia at low MOI and high MOIs. Vaccinia replication was restored by IRF1 KO. In contrast, but consistent with differential regulation of IRF1 protein by glucose/galactose, WT and IRF1 KO cells in galactose media supported similar levels of vaccinia replication regardless of IFN-γ priming. Also associated with glucose/galactose is a seemingly second block at a very late stage in viral replication which results in reductions in herpes- and poxvirus titers but not viral protein expression. Collectively, these data illustrate a novel layer of regulation for the key ISG protein, IRF1, mediated by glucose/galactose and imply unappreciated subprograms embedded in the interferon response. In principle, such cellular circuitry could rapidly adapt immune responses by sensing changing metabolite levels consumed during viral replication and cell proliferation.

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PLoS Pathogens
PLoS Pathogens MICROBIOLOGY-PARASITOLOGY
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期刊介绍: Bacteria, fungi, parasites, prions and viruses cause a plethora of diseases that have important medical, agricultural, and economic consequences. Moreover, the study of microbes continues to provide novel insights into such fundamental processes as the molecular basis of cellular and organismal function.
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