Terminal Loop Sequences in Viral Double-Stranded RNAs Modulate RIG-I Signaling

Detection of foreign RNAs is a crucial activation step for innate immunity pathways in response to viral infections. Retinoic acid-inducible gene I (RIG-I) is a cytoplasmic RNA sensor that triggers type I and III interferon (IFN) expression and activates the antiviral response. The activating ligand for RIG-I has been shown to be 5’-triphosphated blunt-ended double stranded(ds) RNA, but questions remain on the molecular mechanisms for RIG-I activation during viral infections. Here we show that immune-activating copy-back viral genomes (cbVGs) contain RNA stem loops away from the 5’ end of the RNA that enhance RIG-I signaling and IFN expression. Importantly, the sequence of the terminal loops of the activating motifs impacts the strength of IFN expression. Additionally, we show that synthetic versions of these cbVG-derived stem loops trigger innate immune responses in mice demonstrating their potential as immunostimulants in vivo .