C J San Felipe, Jyoti Batra, Monita Muralidharan, Shivali Malpotra, Durga Anand, Rachel Bauer, Kliment A Verba, Danielle L Swaney, Nevan J Krogan, Michael Grabe, James S Fraser
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引用次数: 0
摘要
Open Reading Frame 9b (Orf9b)是SARS-CoV和-2的辅助蛋白,通过与线粒体受体外膜70转座酶(Tom70)结合参与先天免疫抑制。先前对Orf9b的分离结构研究揭示了一个富含β-薄片的同型二聚体;然而,Orf9b与Tom70的配合物结构显示为单体螺旋褶皱。在这里,我们开发了一个生物物理模型,量化Orf9b如何在这些构象之间切换并与Tom70结合,这是抑制1型干扰素反应的必要条件。我们使用该模型来表征脂质结合和突变对Orf9b:Tom70平衡的影响。我们发现脂质与Orf9b同型二聚体的结合使Orf9b单体与二聚体的平衡倾向于二聚体,使二聚体的解离率降低了约100倍。我们还发现,相关变异的突变可以改变不同的微观速率常数,而不会显著影响与Tom70的结合。总之,我们的研究结果强调了对这些耦合平衡中不同步骤的扰动如何影响Orf9b对Tom70的表观亲和力,并对冠状病毒感染中的干扰素信号传导具有潜在的下游影响。
Coupled equilibria of dimerization and lipid binding modulate SARS Cov 2 Orf9b interactions and interferon response.
Open Reading Frame 9b (Orf9b), an accessory protein of SARS-CoV and -2, is involved in innate immune suppression through its binding to the mitochondrial receptor Translocase of Outer Membrane 70 (Tom70). Previous structural studies of Orf9b in isolation revealed a β-sheet-rich homodimer; however, structures of Orf9b in complex with Tom70 revealed a monomeric helical fold. Here, we developed a biophysical model that quantifies how Orf9b switches between these conformations and binds to Tom70, a requirement for suppressing the type 1 interferon response. We used this model to characterize the effect of lipid binding and mutations in variants of concern to the Orf9b:Tom70 equilibrium. We found that the binding of a lipid to the Orf9b homodimer biases the Orf9b monomer:dimer equilibrium towards the dimer by reducing the dimer dissociation rate ~100 fold. We also found that mutations in variants of concern can alter different microscopic rate constants without significantly affecting binding to Tom70. Together, our results highlight how perturbations to different steps in these coupled equilibria can affect the apparent affinity of Orf9b to Tom70, with potential downstream implications for interferon signaling in coronavirus infection.
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