Itaconate reduces viral endocytosis by targeting Cys128 of the adaptor-related protein complex 1 gamma 1 subunit in the host, providing a novel target for antiviral drug development.
Xinqi Deng, Heng Chen, Zhixing Huang, Rongge He, Qinling Rao, Luni Xu, Zijian Xu, Naixuan Zhao, Yeqing Peng, Muxuan Li, Xi Liu, Tao Ma, Xiaolan Cui, Chunguo Wang
Abstract
Open AccessTraditional antiviral strategies primarily rely on vaccines and virus protein-targeting drugs, which adopt a virus-targeting approach. However, the rapid mutation of viruses often leads to vaccine failure and drug resistance, highlighting the limitations of these conventional methods. Consequently, the development of novel broad-spectrum, host-targeting antiviral strategies has become a major research focus. Itaconate, an endogenous immunomodulatory metabolite, inhibits viral replication via post-translational modifications; however, its mechanism in suppressing viral endocytosis remains unclear. This study demonstrates that itaconate inhibits viral endocytosis by covalently modifying the Cys128 site of the adaptor-related protein complex 1 gamma 1 subunit (AP1G1), thereby providing a new target for host-directed antiviral drug development. It was found that itaconate binds to AP1G1 at Cys128, impairing its interaction with clathrin, which inhibits clathrin-mediated viral particle uptake and reduces cellular susceptibility to infection (i.e., the likelihood of cells being infected by viruses and undergoing infection). Furthermore, the natural product Licochalcone B was identified as targeting the same site as itaconate. In both BEAS-2B cell models and mouse infection models, Licochalcone B reduced pulmonary viral loads by over 95%. This study is the first to propose and validate the feasibility of inhibiting broad-spectrum viral infection by targeting AP1G1, elucidating a novel molecular mechanism of itaconate-mediated regulation, offering a new target for broad-spectrum antiviral drug development, and identifying Licochalcone B as a promising broad-spectrum antiviral agent.