Gene therapy of cancer.

Abstract

Gene therapy was initially thought of as a means to correct single gene defects in hereditary disease. Since then, cancer has become the most important indication for gene therapy in clinical trials. In the foreseeable future, the best way to achieve reasonable intratumoral concentrations of a transgene with available vectors will be direct intratumoral injection with or without the help of various techniques such as endoscopy or computed tomography guidance. At present, viral and nonviral methods of gene transfer are used either in vivo or ex vivo/in vitro. The most important viral vectors currently used in clinical trials are retroviruses, adenoviruses, adeno-associated viruses and herpes viruses. However, none of them satisfies all the criteria of an ideal gene therapeutic system, and vectors with only minimal residues of their parent viruses (gutless vectors) and completely synthetic viral vectors are gaining importance. Nonviral methods of gene therapy include liposomes, injection of vector-free (naked) DNA, protein-DNA complexes, delivery by gene gun, calcium-phosphate precipitation, electroporation and intracellular microinjection of DNA. The first clinical trial of human gene therapy was performed in 1990 and since then more than 5000 patients have been treated worldwide in over 400 clinical protocols. Side effects were rare and mostly mild in all of these studies and expression of the transgene was demonstrated in patients in vivo. Despite anecdotal reports of therapeutic responses in some patients, there is still no unequivocal proof of clinical efficacy of most approaches to gene therapy in cancer, primarily due to very low transduction and expression efficacy in vivo of available vectors. Strategies for gene therapy of cancer can be subdivided into four basic concepts: 1) strengthening of the immune response against a tumor, 2) repair of cell cycle defects caused by loss of tumor suppressor genes or inappropriate activation of oncogenes, 3) suicide gene strategies and 4) inhibition of tumor angiogenesis. Gene marker studies and gene protection of normal tissue are also discussed.