A Novel Oncolytic Herpes Capable of Cell-Specific Transcriptional Targeting of CD133± Cancer Cells Induces Significant Tumor Regression.

The topic of cancer stem cells (CSCs) is of significant importance due to its implications in our understanding of the tumor biology as well as the development of novel cancer therapeutics. However, the question of whether targeting CSCs can hamper the growth of tumors remains mainly unanswered due to the lack of specific agents for this purpose. To address this issue, we have developed the first mutated version of herpes simplex virus-1 that is transcriptionally targeted against CD133+ cells. CD133 has been portrayed as one of the most important markers in CSCs involved in the biology of a number of human cancers, including liver, brain, colon, skin, and pancreas. The virus developed in this work, Signal-Smart 2, showed specificity against CD133+ cells in three different models (hepatocellular carcinoma, colorectal cancer, and melanoma) resulting in a loss of viability and invasiveness of cancer cells. Additionally, the virus showed robust inhibitory activity against in vivo tumor growth in both preventive and therapeutic mouse models as well as orthotopic model highly relevant to potential clinical application of this virus. Therefore, we conclude that targeting CD133+ CSCs has the potential to be pursued as a novel strategy against cancer. Stem Cells 2018;36:1154-1169.

Inhibition of mesothelin as a novel strategy for targeting cancer cells.

Mesothelin, a differentiation antigen present in a series of malignancies such as mesothelioma, ovarian, lung and pancreatic cancer, has been studied as a marker for diagnosis and a target for immunotherapy. We, however, were interested in evaluating the effects of direct targeting of Mesothelin on the viability of cancer cells as the first step towards developing a novel therapeutic strategy. We report here that gene specific silencing for Mesothelin by distinct methods (siRNA and microRNA) decreased viability of cancer cells from different origins such as mesothelioma (H2373), ovarian cancer (Skov3 and Ovcar-5) and pancreatic cancer (Miapaca2 and Panc-1). Additionally, the invasiveness of cancer cells was also significantly decreased upon such treatment. We then investigated pro-oncogenic signaling characteristics of cells upon mesothelin-silencing which revealed a significant decrease in phospho-ERK1 and PI3K/AKT activity. The molecular mechanism of reduced invasiveness was connected to the reduced expression of ß-Catenin, an important marker of EMT (epithelial-mesenchymal transition). Ero1, a protein involved in clearing unfolded proteins and a member of the ER-Stress (endoplasmic reticulum-stress) pathway was also markedly reduced. Furthermore, Mesothelin silencing caused a significant increase in fraction of cancer cells in S-phase. In next step, treatment of ovarian cancer cells (OVca429) with a lentivirus expressing anti-mesothelin microRNA resulted in significant loss of viability, invasiveness, and morphological alterations. Therefore, we propose the inhibition of Mesothelin as a potential novel strategy for targeting human malignancies.

Immunogenicity of a lentiviral-based DNA vaccine driven by the 5'LTR of the naturally attenuated caprine arthritis encephalitis virus (CAEV) in mice and macaques.

Increasing the safety and the efficacy of existing HIV vaccines is one of the strategies that could help to promote the development of a vaccine for human use. We developed a HIV DNA vaccine (Δ4-SHIVKU2) that has been shown to induce potent polyfunctional HIV-specific T cell responses following a single dose immunization of mice and macaques. Δ4-SHIVKU2 also induced protection when immunized macaques were challenged with homologous pathogenic viruses. In the present study, our aim was to examine whether a chimeric HIV DNA vaccine (CAL-Δ4-SHIVKU2) whose genome is driven by the LTR of the goat lentivirus, caprine arthritis encephalitis (CAEV) expresses efficiently the vaccine antigens and induces potent immune responses in animal models for HIV vaccine. Data of radioimmunoprecipitation assays clearly show that this chimeric genome drives efficient expression of all HIV antigens in the construct. In addition, evaluation of the p24 Gag protein in the supernatant of HEK-293-T cells transfected in parallel with Δ4-SHIVKU2 and CAL-Δ4-SHIVKU2 showed no difference suggesting that these two LTRs are inducing equally the expression of the viral genes. Immunization of mice and macaques using our single dose immunization regimen resulted in induction of similar IFN-γ ELISPOT responses in Δ4-SHIVKU2- and CAL-Δ4-SHIVKU2-treated mice. Similar profiles of T cell responses were also detected both in mice and macaques when multiparametric flow cytometry analyses were performed. Since CAEV LTR is not dependent of Tat to drive viral gene expression and is not functional for integration with HIV integrase, this new vector increases the safety and efficacy of our vaccine vectors and vaccination strategy.

Pro-oncogenic cell signaling machinery as a target for oncolytic viruses.

Viruses function in close harmony with the signaling machinery of their host. Upon exposure to the cell, a battery of viral products become engaged in boosting friendly signaling elements of the host or suppressing harmful ones. The efficiency of viral replication is indeed the biological outcome of this interaction between cellular and host signaling molecules. Oncolytic viruses, natural or man-made, follow the same set of rules of engagement. Pro-oncogenic cell signaling machinery, therefore, is undoubtedly the most important area influencing the development of the next generation of effective, specific and rationally designed oncolytic viruses. Ras signaling, with its central role in what is known today as molecular oncology, is an attractive topic for studying the behavior of viruses versus cancer cells and to develop strategies to target cancer cells on the basis of such platform. This work reviews the development of oncolytic herpes viruses capable of targeting Ras signaling pathway along with a few other examples of viruses which are developed to contain specificity for certain pro-oncogenic characteristics of their host cells.

Characterization of T-cell responses in macaques immunized with a single dose of HIV DNA vaccine.

The optimization of immune responses (IR) induced by HIV DNA vaccines in humans is one of the great challenges in the development of an effective vaccine against AIDS. Ideally, this vaccine should be delivered in a single dose to immunize humans. We recently demonstrated that the immunization of mice with a single dose of a DNA vaccine derived from pathogenic SHIV(KU2) (Delta4SHIV(KU2)) induced long-lasting, potent, and polyfunctional HIV-specific CD8(+) T-cell responses (G. Arrode, R. Hegde, A. Mani, Y. Jin, Y. Chebloune, and O. Narayan, J. Immunol. 178:2318-2327, 2007). In the present work, we expanded the characterization of the IR induced by this DNA immunization protocol to rhesus macaques. Animals immunized with a single high dose of Delta4SHIV(KU2) DNA vaccine were monitored longitudinally for vaccine-induced IR using multiparametric flow cytometry-based assays. Interestingly, all five immunized macaques developed broad and polyfunctional HIV-specific T-cell IR that persisted for months, with an unusual reemergence in the blood following an initial decline but in the absence of antibody responses. The majority of vaccine-specific CD4(+) and CD8(+) T cells lacked gamma interferon production but showed high antigen-specific proliferation capacities. Proliferative CD8(+) T cells expressed the lytic molecule granzyme B. No integrated viral vector could be detected in mononuclear cells from immunized animals, and this high dose of DNA did not induce any detectable autoimmune responses against DNA. Taken together, our comprehensive analysis demonstrated for the first time the capacity of a single high dose of HIV DNA vaccine alone to induce long-lasting and polyfunctional T-cell responses in the nonhuman primate model, bringing new insights for the design of future HIV vaccines.

Longitudinal study to assess the safety and efficacy of a live-attenuated SHIV vaccine in long term immunized rhesus macaques.

Live-attenuated viruses derived from SIV and SHIV have provided the most consistent protection against challenge with pathogenic viruses, but concerns regarding their long-term safety and efficacy have hampered their clinical usefulness. We report a longitudinal study in which we evaluated the long-term safety and efficacy of DeltavpuSHIV(PPC), a live virus vaccine derived from SHIV(PPC). Macaques were administered two inoculations of DeltavpuSHIV(PPC), three years apart, and followed for eight years. None of the five vaccinated macaques developed an AIDS-like disease from the vaccine. At eight years, macaques were challenged with pathogenic SIV and SHIV. None of the four macaques with detectable cellular-mediated immunity prior to challenge had detectable viral RNA in the plasma. This study demonstrates that multiple inoculations of a live vaccine virus can be used safely and can significantly extend the efficacy of the vaccine, as compared to a single inoculation, which is efficacious for approximately three years.