Glioma-specific and cell cycle-regulated herpes simplex virus type 1 amplicon viral vector.

We have engineered a novel herpes simplex virus type 1 (HSV-1)-based amplicon viral vector, whereby gene expression is controlled by cell cycle events. In nondividing cells, trans-activation of the cyclin A promoter via interaction of the Gal4/NF-YA fusion protein with the Gal4-binding sites is prevented by the presence of a repressor protein, cell cycle-dependent factor 1 (CDF-1). CDF-1 is specifically expressed during the G(0)/G(1) phase of the cell cycle and its binding site is located within the cyclin A promoter. In actively proliferating cells, trans-activation could take place because of the absence of CDF-1. Our results showed that when all these cell cycle-specific regulatory elements are incorporated in cis into a single HSV-1 amplicon plasmid vector backbone (pC8-36), reporter luciferase activity is greatly enhanced. Transgene expression mediated by this series of HSV-1 amplicon plasmid vectors and amplicon viral vectors could be regulated in a cell cycle-dependent manner in a variety of cell lines. In a further attempt to target transgene expression to a selected group of actively proliferating cells such as glial cells, we have replaced the cytomegalovirus promoter of the pC8-36 amplicon plasmid with the glial cell-specific GFAP enhancer element. With this latter viral construct, cell type-specific and cell cycle-dependent transgene expression could subsequently be demonstrated specifically in glioma-bearing animals. Taken together, our results suggest that this series of cell cycle-regulatable HSV-1 amplicon viral vectors could potentially be adapted as useful tools for the treatment of human cancers.