Transcriptional response of immune-related genes after endogenous expression of VP1 and exogenous exposure to VP1-based VLPs and CPV virions in lepidopteran cell lines.

In insects, RNAi is considered the major antiviral immune defense pathway. DsRNAs produced during viral infection are processed by Dicer enzymes into small RNAs that function as specificity determinants to silence viral genes. By contrast, in mammals, recognition of molecules associated with viral infection, such as dsRNA, by pattern recognition receptors (PRRs) initiates a signaling cascade that culminates in the production and release of signaling proteins with antiviral function such as interferons. However, in insects, the hypothesis that components of virions can be recognized as pathogen-activated molecular patterns (PAMPs) to activate the innate immune response has not been investigated systematically. In this study, the potential of VP1, that constitutes the major capsid protein of cytoplasmic polyhedrosis virus (CPV; Reoviridae), to activate a collection of immune-related genes was examined in silkworm-derived Bm5 cells. Two different methods of VP1 administration were tested, either through endogenous expression in transformed cell lines, or through addition of purified VP1-based viral-like particles to the extracellular medium. In addition, exposure to CPV virions isolated from purified polyhedra was also performed. In general, our results do not show a robust transcriptional response of immune-related genes to VP1 or CPV virions, but two exceptions were noted. First, the expression of the antimicrobial peptide (AMP) gene Attacin was strongly induced after 24 h of exposure to VP1-based VLPs. Second, the expression levels of dcr-2, an essential gene in the RNAi pathway, were greatly increased in VP1-expressing transformed Sf21 cells but not transformed Bm5 cells, indicating the existence of species-specific effects. However, the increased expression of dcr-2 did not result in increased silencing efficiency when tested in an RNAi reporter assay. Our study indicates that the capsid protein VP1 of CPV has the potential to act as a PAMP and to induce a transcriptional response in insect cells that relate both to RNAi and protein effectors such as AMPs. The identity of the PRRs and the signaling cascade that are potentially triggered by VP1 remain to be elucidated in future experiments. While this study was performed on a small scale, it can encourage more comprehensive studies with high-throughput approaches (microarray, deep sequencing) to search more systematically whether viral capsid proteins can act as PAMPs in insects and whether their production results in the induction of immune-related genes with potential antiviral function.