Gene transfer of p19Arf and interferon-b in melanoma cells.

Malignant melanoma is a type of cancer with high death rates, in part, because of a lack of efficient treatments and its tendency to generate metastases. Our group has developed viral vectors for the gene transfer of anticancer factors and, initially, we constructed an adenoviral vector, AdPG, in which transgene expression is controlled by p53, a tumor suppressor and transcription factor. As 90% of melanoma cases maintain wild-type p53, it was proposed that this could be used as a tool to drive transgene expression encoded by the AdPG vector, as evidenced by previous studies from our group. For example, transduction of B16 cells (mouse melanoma, wild-type p53, p19Arf-null) with vectors encoding p19Arf or interferon-<font face=\"Symbol\">b (IFN<font face=\"Symbol\">b) resulted in massive death cell, while transfer of just one of these factors alone did not cause the same effect. The work described here includes two critical technologic advances in comparison with our previous work. First, transgenes of interest (eGFP, p19Arf and IFN<font face=\"Symbol\">b) were inserted into an adenoviral vector which presents the RGD tripeptide in its fiber. This vector modification allows efficient transduction in a wide range of target cells without dependence on the wild type adenovirus receptor, CAR. In addition, a bicistronic vector was constructed which contains the combination of both therapeutic genes, ensuring the transfer of both factors to the target cells at the same time. Use of p19Arf, a tumor suppressor and MDM2 inhibitor, as a therapeutic gene should complement endogenous p53 activities and, as a consequence, promote expression from the AdPG vector and inhibit tumor cell proliferation. However, p19Arf gene transfer alone should have an effect only in transduced cells and, therefore, its effect would be limited. For this reason, we describe, in addition to p19Arf, the application IFN<font face=\"Symbol\">b, a secreted protein with antitumor functions, including inhibition of angiogenesis, induction of apoptosis and activation of immunologic response. This strategy involves several mechanistic levels related with the gene transfer process, including transduction efficiency, control over transgene expression and transgene activity. Therefore, it was proposed that the combination of p19Arf and IFN<font face=\"Symbol\">b could be an interesting strategy to induce primary tumor death and an immunologic response against metastatic cells. In this project, the construction of new vectors optimized for gene transfer in melanoma cells was initiated. (AU)