Oncolytic Viruses in the Therapy of Lymphoproliferative Diseases.

Cancer is a leading causes of death. Despite significant success in the treatment of lymphatic system tumors, the problems of relapse, drug resistance and effectiveness of therapy remain relevant. Oncolytic viruses are able to replicate in tumor cells and destroy them without affecting normal, healthy tissues. By activating antitumor immunity, viruses are effective against malignant neoplasms of various nature. In lymphoproliferative diseases with a drug-resistant phenotype, many cases of remissions have been described after viral therapy. The current level of understanding of viral biology and the discovery of host cell interaction mechanisms made it possible to create unique strains with high oncoselectivity widely used in clinical practice in recent years.

[Oncolytic Viruses in the Therapy of Lymphoproliferative Diseases].

Cancer is a leading causes of death. Despite significant success in the treatment of lymphatic system tumors, the problems of relapse, drug resistance and effectiveness of therapy remain relevant. Oncolytic viruses are able to replicate in tumor cells and destroy them without affecting normal, healthy tissues. By activating antitumor immunity, viruses are effective against malignant neoplasms of various nature. In lymphoproliferative diseases with a drug-resistant phenotype, many cases of remissions have been described after viral therapy. The current level of understanding of viral biology and the discovery of host cell interaction mechanisms made it possible to create unique strains with high oncoselectivity widely used in clinical practice in recent years.

[The State of The Jak/Stat Pathway Affects the Sensitivity of TumorCells to Oncolytic Enteroviruses].

A test of the sensitivity of seven colon cancer cell lines to a panel of 12 nonpathogenic human enteroviruses revealed significant differences in the ability of tumor cells to become infected and replicate different viral strains. Among the factors that can affect the sensitivity of cells to viruses are differences in the state of the mechanisms of antiviral protection, associated with a reaction to type I interferons. Using the two colon cancer cell lines CaCo2 and LIM1215 as a model, significant differences were revealed in the ability of cells to defend themselves against virus infection after 16 hours of treatment with 1000 units/mL of interferon-alpha. To study the effect of the state of the interferon response system, represented by the Jak/STAT signaling pathway, on the sensitivity of cells to different strains of enteroviruses, HEK293T cell lines were used. These are capable of supporting replication of each of the tested enteroviruses, as well as maintaining the ability to protect against viral infection after the treatment with interferon. Using the CRISPR/Cas9 system, HEK293T sublines with knockouts of the IFNAR1 and STAT2 genes were obtained. The sensitivity of control and knockout cells to infection with five strains of enteroviruses and the vesicular stomatitis virus was analyzed. It was noted that knockout of the IFNAR1 and STAT2 genes resulted in an increased sensitivity to all tested viruses. In knockout cells, the levels of reproduction of the vaccine derived of poliovirus type 1, Echoviruses 7 and 30, and Coxsackie viruses B5 and A7 were also significantly increased in comparison with the control HEK293T cells. Thus, deficiencies in the Jak/STAT signaling pathway in tumor cells lead to an overall increase in the sensitivity to oncolytic viruses.

Oncolytic Activity of the Vaccine Strain of Type 3 Poliovirus on the Model of Rat Glioma C6 Cells.

Rat glioma cell line C6 expressing human poliovirus receptor (PVR) and susceptible to polioviruses (C6-PVR-BFP) was used to produce a clone with knockout of IFNα/ß (Ifnar1) receptor subunit 1 gene (Ifnar1). The sensitivity of C6-PVR-BFP cells to the vaccine strain of poliovirus type 3 (PV3) depended on the signaling pathways of the cell response to type 1 IFN. Using the model of subcutaneous tumor xenografts, we demonstrated oncolytic activity of PV3 against C6-PVR-BFP cells that depended on the expression of PVR and increased considerably upon disturbances in IFN response pathways.

Relationship between Cell Receptors and Tumor Cell Sensitivity to Oncolytic Enteroviruses.

Replicative ability of 5 oncolytic enterovirus strains was evaluated on a panel of 18 human normal and tumor cells. The capacity of each cell line to support replication of enterovirus strains varied. Cell lines weakly replicating one virus could be highly sensitive to another viral strain. Differences in the expression of CXADR cell receptor did not correlate with susceptibility to infection and replication of Coxsackie B virus, but complete inactivation of CXADR gene and poliovirus receptor gene (PVR) led to loss of the sensitivity to Coxsackie B5 and poliovirus, respectively. Detection of additional expression markers will contribute to understanding the causes of different sensitivity of tumor cells to viruses.

Negative-sense virion RNA of segment 8 (NS) of influenza a virus is able to translate in vitro a new viral protein.

It was shown that full-length virion RNA of segment 8 of influenza virus A/Aichi/2/68 (H3N2) can initiate the synthesis of two major polypeptides with molecular weights of 23 and 13 kD and a minor polypeptide with a molecular weight of 19 kDa, which specifically reacted with the antibodies to the 30-membered peptide of the central part of the NSP protein of influenza A virus. Thus, the genomic-polarity RNA of segment 8 of influenza virus A has a translational template function. These data provide further confirmation of the concept of the bipolar (ambisens) strategy of functioning of the influenza A virus genome.

[Biomarkers of prostate cancer sensitivity to the Sendai virus].

Metastatic prostate cancer is often associated with either primary or intractable castration-resistant prostate cancer (CRPC), thus justifying the search for entirely new ways of treatment. Oncolytic viruses are able to selectively induce the death of tumor cells without affecting normal cells. A murine Sendai virus has potential to be used as an oncolytic agent. However, tumors vary in their sensitivity to different viruses, prompting us to attempt to identify corresponding biomarkers that reflect the interaction of cancer cells and the virus. Here, we show that the sensitivity of primary prostatic adenocarcinoma cell lines to Sendai virus strain (SeVM) vary substantially. Using quantitative PCR, we evaluated expression levels of genes that encode RIG-1-like and Toll-like receptors (TLRs) in cell lines and showed that the levels of mRNAs that encode TLR3 and TLR7 correlate with a degree of sensitivity of the cells to Sendai virus. The lines with lower levels of TLR3 and TLR7 expression are more sensitive to the virus.

Sensitivity of C6 Glioma Cells Carrying the Human Poliovirus Receptor to Oncolytic Polioviruses.

A humanized line of rat C6 glioma cells expressing human poliovirus receptor was obtained and tested for the sensitivity to oncolytic effects of vaccine strains of type 1, 2, and 3 polioviruses. Presentation of the poliovirus receptor on the surface of C6 glioma cells was shown to be a necessary condition for the interaction of cells with polioviruses, but insufficient for complete poliovirus oncolysis.

[Oncolytic viruses for therapy of malignant glioma]. / Onkoliticheskie virusy v terapii zlokachestvennykh gliom.

Effective treatment of malignant brain tumors is still an open problem. Location of tumor in vital areas of the brain significantly limits capasities of surgical treatment. The presence of tumor stem cells resistant to radiation and anticancer drugs in brain tumor complicates use of chemoradiotherapy and causes a high rate of disease recurrence. A technological improvement in bioselection and production of recombinant resulted in creation of viruses with potent oncolytic properties against glial tumors. Recent studies, including clinical trials, showed, that majority of oncolytic viruses are safe. Despite the impressive results of the viral therapy in some patients, the treatment of other patients is not effective; therefore, further improvement of the methods of oncolytic virotherapy is necessary. High genetic heterogeneity of glial tumor cells even within a single tumor determines differences in individual sensitivity of tumor cells to oncolytic viruses. This review analyses the most successful oncolytic virus strains, including those which had reached clinical trials, and discusses the prospects for new approaches to virotherapy of gliomas.