Molecular mechanism by which SARS-CoV-2 Orf9b suppresses the Tom70-Hsp90 interaction to evade innate immunity

The Tom70-Hsp90 interaction is critical for activating MAVS-mediated interferon (IFN) production. Upon RNA virus infection, cytosolic Hsp90 recruits key innate immune signaling proteins to MAVS on mitochondria through its interaction with Tom70. To evade this innate immune response, the SARS-CoV-2 protein Orf9b binds to Tom70, thereby disrupting the Tom70-Hsp90 interaction and suppressing IFN production. Despite its importance, the molecular mechanism underlying Orf9b-mediated inhibition of IFN signaling remains unclear. Here, using an integrative approach combining cryo-electron microscopy, ¹⁹ F NMR spectroscopy, and isothermal titration calorimetry (ITC), we show that Orf9b inhibits Hsp90 binding to Tom70 through a bipartite mechanism. The helix and intrinsically disordered tail of Orf9b sterically block the access of two distinct structural units of Hsp90 to Tom70. We also find that Orf9b-mediated allosteric conformational changes in Tom70 do not contribute to the inhibition of the Hsp90 binding. Comprehensive structural, thermodynamic, and kinetic analyses further reveal that Orf9b primarily slows the association kinetics between Hsp90 and Tom70. Collectively, our results provide a high-resolution mechanistic framework for understanding Orf9b-mediated suppression of the host innate immune response.