Inhibition of growth of human prostate cancer xenograft by transfection of p53 gene: gene transfer by electroporation.

To date, there is no effective therapy for hormone-independent prostate cancer. Therefore, as a new strategy for refractory cancer, gene therapy is showing increasing promise. In this study, we attempted to use a nonviral gene transfer system, in vivo electroporation, in prostate cancer cell PC-3 xenografts with the wild-type p53 (wt-p53) gene, as gene therapy for hormone-independent prostate cancer. To evaluate this in vivo gene transfer method, the beta-galactosidase gene was transfected into xenografts by electroporation. Then, the efficiency of transfection of exogenous p53 gene by electroporation was confirmed by reverse transcription-PCR, which indicated that p53 mRNA was present in samples from xenografts. Next, to estimate the reduction of prostate cancer xenografts by this method, we measured the size of PC-3 xenografts in nude mice after electroporation with the wt-p53 gene. The growth of tumors was markedly suppressed by wt-p53 gene transfection by electroporation compared with transfection of mutated type p53 gene (P = 0.0027) or vector only (P = 0.0015). Furthermore, histological specimens revealed increased apoptotic cell death in p53-transfected tumors. These results suggest that it is possible to transfer wt-p53 into prostate cancer xenografts using electroporation and to suppress the growth of tumors; they, furthermore, suggest that this system might be used for local advanced hormone-independent prostate cancer.