Recombinant Vaccinia Virus Promising for Melanoma Treatment

Melanoma is a tumor that forms as a result of malignant transformation of melanin-producing pigment cells (melanocytes). It is the most aggressive form of skin cancer and is characterized by high resistance to chemotherapeutic drugs, which results in a need to explore alternative methods for this disease therapy. Currently, new approaches to cancer treatment are being intensely developed, oncolytic immunotherapy being one of them. This approach consists in using viruses as targeted tumor-specific cytolytic agents capable of stimulating both tumor-specific and nonspecific immune responses. A considerable body of research is currently aimed on improving the immunostimulatory properties of viruses by inserting the genes encoding immunomodulatory proteins or tumor-specific antigenic determinants into viral genomes. For melanoma, the highest number of tumor-associated antigens (TAAs) has been identified, which serve as the basis for the development of anti-tumor DNA vaccines. The immunogenicity and efficacy of these drugs, however, remain low. The bottlenecks in using DNA vaccines to treat cancer are considered to be imperfect design of polyepitope constructs, as well as inefficient delivery of therapeutic molecules directly to the target cells. A partial solution to these problems may be represented by the use of oncolytic viruses as vectors for the delivery of artificial immunogens. The recombinant vaccinia virus was obtained by transient dominant selection. The cytolytic activity of the obtained virus was tested using the MTT assay. The oncolytic activity of the virus was assessed in the mouse xenograft model obtained using malignant SK-Mel-28 cells. This paper reports the production of a recombinant L-IVP_oncoM virus, the oncolytic virus for the delivery of anticancer therapeutic genes into the cells, on the basis of the vaccinia virus strain L-IVP. Toward this end, the gene encoding the Granulocyte-macrophage colony-stimulating factor (GM-CSF) and the artificial gene encoding a polyepitope immunogen containing the epitopes of the antigens over-expressed in melanoma cells were inserted into the virus genome. These insertions were located in the proximity of the genes encoding thymidine kinase (J2R) and viral growth factor (C11L), respectively. The properties of L-IVP_oncoM were studied in in vitro experiments using cell cultures of various origin and in the in vivo experiments using the mouse xenograft model. The basic experiments to assess the biological properties of the obtained L-IVP_oncoM, which are necessary to characterize the oncolytic virus, have been carried out.