Quantification and characterization of autotransduction in retroviral vector producer cells.

Gene therapy has evolved into a tempting strategy for the management of cancer and other life-threatening diseases. Various approaches employ retroviral vectors to deliver the therapeutic gene. The profound knowledge about retrovirus biology allows the generation of increasingly advanced vector systems as well as an accurate assessment and management of potential safety risks. This study focuses on the genetic stability of retrovirus producer cells as a basic safety requirement and its compromise by autotransduction. It has been shown previously that protection of retroviral packaging systems by superinfection interference is not guaranteed. The current study provides insight into the extent of autotransduction and the time point at which it occurs, and examines strategies to antagonize it. Therefore, a reconstituting vector system was used that obviates transgene expression in virus producer cells by physically separating transgene and promoter. Just on infection two functional expression cassettes are reconstituted, causing highly efficient transgene expression in transduced cells. Equipped with an enhanced green fluorescent protein-encoding gene, this vector allowed accurate quantification of autotransduced cells, which were then isolated by fluorescence-activated cell sorting and further characterized. Sequencing of recloned integrated vector copies demonstrated that high transgene expression levels were strictly associated with the presence of reverse-transcribed vector copies. Envelope protein expression levels, however, were found to be equal in autotransduced and noninfected virus producer cells. Finally, the occurrence of autotransduction could be assigned to an early time point after transfection and was successfully blocked by azidothymidine treatment, yielding a stable and homogeneous population of noninfected retrovirus producer cells.

Reconstituting retroviral (ReCon) vectors facilitating delivery of cytotoxic genes in cancer gene therapy approaches.

BACKGROUND: We have previously described the generation of reconstituting retroviral (ReCon) vectors designed for cancer gene therapy using cytotoxic gene products. The unique vector structure with a promoter physically separated from the transgene allows generation of stable virus producer cells irrespective of the toxic gene. The mechanism of synthesis of DNA from retroviral RNA dictates that infection leads to the reconstitution of functional expression cassettes in the target cell. METHODS: To improve vector titres, a cytomegalovirus enhancer was inserted upstream of the 5'-long-terminal repeat (LTR); the Woodchuck hepatitis virus post-transcriptional regulatory element and an elongated attachment site upstream of the 3'-LTR were included. In addition, a bacterial origin of replication was deleted and a functional internal polyadenylation signal mutated. Transcriptional targeting was attempted by introducing mammary tissue-specific promoters such as the U3 region of mouse mammary tumour virus or the promoter of the whey acidic protein encoding gene. All modifications were analysed in detail with respect to virus production and infectivity. Finally, the vector was armed with the lambda-holin encoding gene and transduced cells were analysed for cytotoxic effects. RESULTS: Distinct modifications of the vector resulted in a titre improvement of more than 560-fold. Compatibility of the optimized vector with targeted cellular promoters was demonstrated. When equipped with the cytotoxic gene, stable producer cells could be successfully established and high titre virus infection resulted in rigorous target cell killing. CONCLUSIONS: The ReCon vector in its optimized form is an attractive tool for cancer gene therapy approaches.