Abstract
RNA vaccines have emerged as a breakthrough technology, and one promising modality employs alphavirus-derived self-replicating RNA (repRNA) to express vaccine antigens. However, both the lipid nanoparticles (LNP) commonly used to deliver RNA and virus-like amplification of repRNAs trigger innate immune recognition, especially via type I interferon (IFN) signaling. To modulate IFN responses during vaccination, we formulated LNPs co-delivering antigen-encoding RNA together with siRNA targeting the interferon-α/β receptor-1 (IFNAR1). siRNA-mediated repression of IFNAR1 increased antigen expression from repRNAs by >10-fold, increased immune cell infiltration, and increased antigen presenting cell activation in the injection site and draining lymph nodes. Compared to repRNA alone, siRNA/repRNA co-delivery increased serum antibody titers >10-fold, dramatically augmented antigen-specific germinal center (GC) B cell responses, and primed 4.4-fold more antigen-specific T cells. Ifnar1 silencing by siRNA co-delivery similarly enhanced mRNA vaccines. Thus, siRNA co-delivery is a readily translatable approach to substantially enhance the immunogenicity of RNA vaccines.
Competing Interest Statement
BJK and DJI are inventors on a patent filed by MIT related to this work (number PCT/US24/23210). DJI is a co-founder and equity holder in Strand Therapeutics. YD is an inventor on a patent filed by The Ohio State University related to the TT3 lipid used in this work (number PCT/US2016/033514). The other authors declare no conflicts.
