Absence of in vitro or in vivo bystander effects in a thymidine kinase-transduced murine T lymphoma

Introduction to the background, principles, and state of the art in suicide gene therapy

Gene therapy is defined as a technology that aims to modify the genetic component of cells to gain therapeutic benefits. Suicide gene therapy (or gene-directed enzyme prodrug therapy [GDEPT]) is a two-step treatment for cancer (especially, solid tumors). In the first step, a gene for a foreign enzyme is delivered to the tumor by a vector. Following the expression of the foreign enzyme, a prodrug is administered during the second step, which is selectively activated in the tumor. This article discusses the principles and the theorectical background of GDEPT. A special emphasis is put on enzyme/prodrug systems developed for GDEPT, the design of prodrugs and the kinetic of their activation, the types and the mechanisms of bystander effect and its immunological implications. The possible strategies to improve GDEPT are also discussed.

Electroporation-mediated and EBV LMP1-regulated gene therapy in a syngenic mouse tumor model

Latent membrane protein 1 (LMP1) is an Epstein-Barr virus (EBV)-encoded oncogene expressed in EBV-associated nasopharyngeal carcinoma (NPC). Previous studies indicate that a strategy combining LMP1-mediated NF-kappaB activation and the HSV thymidine kinase/Ganciclovir (HSVtk/GCV) prodrug system leads to regression of tumor growth in nude mice. To improve the efficacy of this strategy in immunocompetent hosts, we developed a therapeutic cassette, p6kappaB-EDL1E-tk, containing six copies of the NF-kappaB binding motif and an epithelial-specific EBV promoter, ED-L1E. The cassette was tested in a murine CT-26 carcinoma model in syngenic Balb/c mice. Coinjection of an LMP1-expressing vector and p6kappaB-EDL1E-tk by in vivo electroporation in mouse muscle revealed at least two-fold higher TK enzymatic activity than that of previously tested pLTR-tk. Furthermore, growth was attenuated in a group of mice containing LMP1-positive tumors that were intratumorally injected with the p6kappaB-EDL1E-tk cassette and GCV via in vivo electroporation, but not in mice treated with p6kappaB-EDL1E-tk or GCV alone. Similarly, no retardation of tumor growth was observed in mice containing LMP1-negative CT-26 tumors injected with both the p6kappaB-EDL1E-tk cassette and GCV. We propose that intratumoral injection of therapeutic agents, such as DNA of transcription-regulated cassette and GCV, via in vivo electroporation may be used as an alternative treatment for EBV LMP1-expressing cancers.

Gene therapy of lymphoma

Gene therapy offers new and promising treatment for patients with hematological malignancies. Tumor cells--lymphoma cells, for example--are possible targets for gene therapy. In general, gene therapeutic approaches require efficient gene transfer into host cells and sufficient transgene expression. Although many methods of gene transfer into mammalian cells exist, most do not allow efficient DNA transfer into primary lymphocytes. In contrast to gene transfer into tumor cells and many other cell types, which can be successfully performed using a variety of methods, the efficient expression of foreign DNA in lymphoma cells presents unique problems and challenges, requiring a careful selection of the mode of gene transfer. In this review, we discuss the current strategies for gene therapy in the treatment of lymphoma. We also summarize the current gene transfer methods for lymphoma cells and efficiency of transgene expression.

Suppression of murine mammary carcinoma growth and metastasis by HSVtk/GCV gene therapy using in vivo electroporation

The effectiveness of electroporation as a means of gene transfection, both in vitro and in vivo, was tested using the herpes simplex virus 1 thymidine kinase (HSVtk) gene in combination with ganciclovir (GCV) administration as therapy against murine mammary cancer. Approximately 80% of BJMC3879 metastatic mammary carcinoma cells, derived from MMTV-infected BALB/c mice, died as a result of HSVtk/GCV treatment 72 hours after the transfection; decreased DNA synthesis was also seen. Mammary tumors induced by inoculation of syngeneic mice with BJMC3879 cells were subsequently treated by direct injection of vector containing HSVtk (pHSVtk) alone, empty vector or saline alone twice a week. After each injection, the tumors were subjected to in vivo electroporation. Mice treated with pHSVtk or saline were intraperitoneally injected with GCV at 40 mg/kg five times a week. Significantly reduced tumor volumes were observed for the pHSVtk+GCV group in experimental week 2 and thereafter throughout the 2-month study. DNA synthesis was significantly decreased as well in the pHSVtk+GCV group compared with all other groups. Furthermore, metastasis to lymph nodes and lungs was significantly suppressed by HSVtk/GCV treatment. Expression of HSVtk in the tumors was confirmed by RT-PCR. Macrophage accumulations were frequently observed in the peripheries of necrotic regions in HSVtk/GCV-treated tumors, where levels of apoptosis were significantly higher than those observed in other groups. We therefore conclude that in vivo electroporation can result in efficient gene transfer and that the HSVtk/GCV prodrug system strongly suppresses tumor growth and metastases in this model.