A Bacterial mRNA‐Lysis‐Mediated Cargo Release Vaccine System for Regulated Cytosolic Surveillance and Optimized Antigen Delivery

• Published in: Advanced science Vol. 10; no. 33; pp. e2303568 - n/a
• Main Authors: Li, Yu‐an, Sun, Yanni, Zhang, Yuqin, Li, Quan, Wang, Shifeng, Curtiss, Roy, Shi, Huoying
• Format: Journal Article
• Language: English
• Published: Germany John Wiley & Sons, Inc 01.11.2023; Wiley
• Subjects: Animals; Antigens; Antigens, Bacterial - genetics; Antigens, Bacterial - metabolism; Bacteria; Bacterial Vaccines - genetics; Cell Death; Cell growth; cGAS‐STING; cytosolic surveillance; E coli; Genes; Lymphatic system; MazF interferase; Mice; Mutation; Proteins; RNA, Messenger; Salmonella; Swine; Vaccines; Salmonella; cytosolic surveillance; cGAS-STING; MazF interferase
• ISSN: 2198-3844; 2198-3844
• DOI: 10.1002/advs.202303568

Engineered vector‐based in vivo protein delivery platforms have made significant progress for both prophylactic and therapeutic applications. However, the lack of effective release strategies results in foreign cargo being trapped within the vector, restricting the provision of significant performance benefits and enhanced therapeutic results compared to traditional vaccines. Herein, the development of a Salmonella mRNA interferase regulation vector (SIRV) system is reported to overcome this challenge. The genetic circuits are engineered that (1) induce self‐lysis to release foreign antigens into target cells and (2) activate the cytosolic surveillance cGAS‐STING axis by releasing DNA into the cytoplasm. Delayed synthesis of the MazF interferase regulates differential mRNA cleavage, resulting in a 36‐fold increase in the delivery of foreign antigens and modest activation of the inflammasome, which collectively contribute to the marked maturation of antigen‐presenting cells (APCs). Bacteria delivering the protective antigen SaoA exhibits excellent immunogenicity and safety in mouse and pig models, significantly improving the survival rate of animals challenged with multiple serotypes of Streptococcus suis. Thus, the SIRV system enables the effective integration of various modular components and antigen cargos, allowing for the generation of an extensive range of intracellular protein delivery systems using multiple bacterial species in a highly efficient manner. The SIRV system enhances the safety and immunogenicity of Salmonella vectors through the following mechanisms: (1) induce self‐lysis to release foreign antigens; (2) activate the cytosolic surveillance cGAS‐STING axis; (3) reduce inflammasome activation by impairing flagellin production; (4) promote APC‐maturity, thus improving antigen presentation and immunoresponse elicitation.