Abstract Amphotropic retroviral replicating vector (RRV) Toca 511, expressing the yeast cytosine deaminase (CD) prodrug activator gene, showed promising evidence of therapeutic benefit and increased survival in early-phase trials for recurrent high-grade glioma. While a multi-center Phase 3 trial did not meet its overall endpoints, highly statistically significant survival was observed within predetermined patient subgroups compared to matched randomized control patients, and clinical investigation is on-going. Hence it is worthwhile to consider strategies aimed at enhancing therapeutic efficacy, such as delivering combinations of multiple transgenes. However, RRVs encoated with the same envelope compete for the same cancer cell surface receptors. We have now developed novel RRV encoated (‘pseudotyped’) with a heterologous envelope derived from Gibbon ape leukemia virus (GALV), which utilizes a different cell surface receptor from the native amphotropic retrovirus envelope for cellular entry. RRV(GALV) vectors expressing either GFP or HSV thymidine kinase (TK) were constructed, and efficient replication and transgene expression was observed in > 90% of both established and primary human glioblastoma cells within 14 days after initial infection at 0.01 (1%) multiplicity of infection (MOI). Genomic stability of RRV(GALV) vectors was also confirmed over prolonged propagation. Established and primary human glioblastoma cells infected with RRV(GALV)-TK vector showed ≥ 50%-90% reduction in cell viability after exposure to Ganciclovir prodrug in the range of 1µM-100µM for 5 days, as compared to uninfected control cells or cells infected with RRV(GALV)-GFP control vector. Furthermore, dual infection with RRV(GALV)-TK and amphotropic RRV-CD (Toca 511) resulted in synergistic cytotoxicity upon simultaneous exposure to their respective prodrugs. Further data will be presented from on-going studies evaluating these vectors in intracerebral glioblastoma models. These results indicate that GALV envelope-pseudotyped RRV can efficiently deliver prodrug activator gene therapy in experimental glioma models, and open the door to combinatorial gene therapy regimens with this vector platform.
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