Characterizing the immunogenic cell death induced by Semliki Forest Virus in glioblastoma cell lines

Abstract: Glioblastoma is the most common primary brain tumor in humans and has a poor prognosis. Current therapies are not curative. Oncolytic viruses (OVs) are being investigated as tools to induce immunogenic cell death (ICD), cell death capable of activating the immune system. Semliki Forest Virus (SFV) strain 4 is an OV being investigated to treat glioblastoma. Previous studies in our lab have shown that SFV4 can induce ICD in human osteosarcoma (HOS) cells and ongoing in vivo studies show that SFV4 infected GL261 cell vaccination providesprotective immunity in mouse models. This study aimed to characterize the ICD induced by SFV4in glioblastoma cell lines, namely GL261, SB28 and CT2A, and to explain some of our in vivoobservations, namely why vaccination with SFV infected GL261 provides protective immunity but vaccination with infected CT2A and SB28 does not. Our in vitro studies found that GL261 is resistant to SFV4 while SB28 and CT2A are susceptible. We show that the virus can replicate in all three cell lines as seen by the presence of dsRNA, but that viral translation is delayed or inhibited in GL261 cells as not all cells positive for dsRNA were positive for SFV4 protein. Additionally, the type I interferon (IFN) pathway, responsible for antiviral defense, was highly upregulated in CT2A and SB28 but not as much in GL261 after infectionas seen by surveying IFIT1, IFITM3 and IFN-beta genes. Interferon stimulated genes (ISG) like CXCL10, a chemoattractant, was highly upregulated in GL261 after infection and might account for the protective immunity seen in vivo after vaccination. PDL1, an interferon stimulated gene responsible for self-tolerance, was highly upregulated in CT2A after infection. The IFN-beta ELISA revealed that both infected and uninfected GL261 cells produce IFN-beta suggesting a constitutively active pathway. Our DC phagocytosis assay showed that SFV4 infection of CT2A and SB28 cells induced a significant increase in DC phagocytosis and SFV4 infection of all three cell lines significantly increased DC maturation. We conclude that SFV4 infection of GL261 cells may induce ICD in vivo through a persistent viral infection and increased expression of CXCL10.