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PROTAR Vaccine 2.0 generates influenza vaccines by degrading multiple viral proteins

Chunhe Zhang, Jihuan Hou, Zhen Li, Quan Shen, Haiqing Bai, Li Chen, Jinying Shen, Ping Wang, Yinlei Su, Jing Li, Qisi Zhang, Chengyao Liu, Xuetong Xi, Fei Qi, Yuting Chen, Xin Xie, Adam Yongxin Ye, Xiaoheng Liu, Roberto Plebani, George M. Church, Longlong Si

2025Nature Chemical Biology12 citationsDOIOpen Access PDF

Abstract

Manipulating viral protein stability using the cellular ubiquitin-proteasome system (UPS) represents a promising approach for developing live-attenuated vaccines. The first-generation proteolysis-targeting (PROTAR) vaccine had limitations, as it incorporates proteasome-targeting degrons (PTDs) at only the terminal ends of viral proteins, potentially restricting its broad application. Here we developed the next-generation PROTAR vaccine approach, referred to as PROTAR 2.0, which enabled flexible incorporation of PTDs at various genomic loci of influenza viruses, including internal regions and terminal ends. The PROTAR 2.0 influenza viruses maintained efficient replication in UPS-deficient cells for large-scale production but were attenuated by PTD-mediated proteasomal degradation of viral proteins in conventional cells. Incorporation of multiple PTDs into one virus generated optimized PROTAR 2.0 vaccine candidates. In animal models, PROTAR 2.0 vaccine candidates were highly attenuated and a single-dose intranasal immunization induced robust and broad immune responses that provided complete cross-reactive protection against both homologous and heterologous viral challenges. A next-generation proteolysis-targeting vaccine approach (PROTAR vaccine 2.0) was developed that attenuated influenza viruses by degrading multiple viral proteins and showed promising safety and efficacy in animal models with viral challenge.

Topics & Concepts

VirologyInfluenza vaccineCoronavirus disease 2019 (COVID-19)Computational biologyMicrobiologyBiologyVaccinationMedicineInfectious disease (medical specialty)DiseasePathologyinterferon and immune responsesVirus-based gene therapy researchInfluenza Virus Research Studies
PROTAR Vaccine 2.0 generates influenza vaccines by degrading multiple viral proteins | Litcius