Browsing by Subject "immunovirotherapy"

Cancer immunotherapy refers to therapy strategies that utilise the mechanisms of the immune system to treat cancer patients. The benefits of the approach include the possibility for specific targeting and utilisation of the host immune system. The treatment methods include cancer vaccines, oncolytic viruses (OVs), cell-based immunotherapies and antibodies. The interplay between the cancer and the immune system has been observed crucial for the progress of the cancer and the success of immunotherapies. An immune inflamed tumour microenvironment has been observed beneficial for the success of several therapy methods. Many immunotherapy methods rely on detecting tumour specific antigens that are used to guide the therapy agent to the target site. This strategy poses challenges when considering tumour immune evasion mechanisms, which can cause downregulation of target antigens, and heterogeneity of tumour cells and patients. OVs have the advantage of not requiring predetermined target structures to exert their effect to the tumour cells. They cause direct tumour cell lysis and induce immune responses, and may be modified to express additional genes, including immunostimulatory agents. However, virus-related immunosuppressive mechanisms and a rapid viral clearance may limit their effects. A Western Reserve (WR) Vaccinia virus (VACV) is a highly oncolytic virus strain but the virus has been observed to suppress the function of the cyclic guanosine monophosphate adenosine monophosphate synthase – stimulator of interferon genes (cGAS STING) innate immune pathway which has been shown to have a significant role in anti-tumour immune responses. The aim of this study was to create a WR VACV encoding a dominantly active (D A) STING and to determine whether the virus is capable of activating the cGAS STING pathway. The effects were compared to a corresponding virus vvdd tdTomato that does not have the STING encoding gene. The pathogenicity of viruses was controlled by a double deletion of the thymidine kinase and vaccinia growth factor genes which restricts the virus replication to tumour cells. Transgene fragments were cloned from template plasmids by polymerase chain reactions (PCRs) and joined together in a Gibson Assembly (GA) reaction to form a STING-P2A-eGFP gene insert. The insert was attached to a shuttle vector pSC65-tdTomato by restriction enzyme digestion, ligation and transformation in Escherichia coli. The correct transgene plasmid construct was verified by Sanger sequencing and PCRs. The transgene was inserted to a modified WR VACV vvdd-tdTomato-hDAI by a homologous recombination. The newly created VVdd STING-P2A-eGFP virus was purified by plaque purification. The STING protein expression was studied by an immunocytochemistry (ICC) assay. The immune signalling pathway activation was examined by testing nuclear factor kappa-light chain-enhancer of activated B cells (NF-κB) activation in RAW-Blue cells and dendritic cell activation and maturation in JAWS II cells. The cell viability after iinfection was studied with four cell lines; A549, B16-F10, HEK293 and MB49. The D-A STING expressing virus was produced successfully. The ICC experiment verified the capability of the VVdd STING-P2A eGFP to produce the STING protein in the infected cells. The preliminary findings indicate that the VVdd STING-P2A-eGFP virus activates the NF-κB signalling in the RAW-Blue cells and that the activation is dependent on the STING expression. The activation level is relative to the infection concentration at MOI range 0,001 to 0,1. The findings suggest that the VVdd-STING-eGFP virus can induce innate immune signalling via the STING pathway. The reference virus did not activate the signalling. The in vitro experiments also indicated that the STING virus may induce DC activation and maturation. We observed a trend of CD86 and CD40 expression upregulation on the JAWS II DCs. The effects to the cell viability were inconclusive. More studies should be conducted to verify the results. The effects of the virus should be studied in more advanced cancer models that take into account the complexity of the immune system. These preliminary results indicate the that the VVdd-STING-P2A-eGFP virus could stimulate the immune signalling through the STING pathway.

Background and objectives: Cancer is one of the leading causes of death worldwide, and resistance to current treatments demands the continuous development of novel cancer therapies. Cancer immunotherapy aims to induce anticancer immune responses that selectively target cancer cells. Viruses can also be harnessed to elicit tumor-specific immune responses and to improve the response rates of other concomitant cancer therapies. The purpose of this study was to develop a novel viral vector-based cancer vaccine for intratumoral immunotherapy. By using the previously developed PeptiENV cancer vaccine platform, the vector viruses were coated with cell-penetrating peptide (CPP) sequence-containing tumor peptides in an attempt to further drive the immune responses elicited by the vector against cancer cells. The efficacy of the PeptiENV complex as a cancer vaccine was assessed by following its effects on tumor growth and the development of local and systemic antitumor immune responses. Methods: The PeptiENV complex formation was assessed by a surface plasmon resonance (SPR) analysis. Dendritic cell (DC) activation and antigen cross-presentation were studied using the murine JAWS II dendritic cell line. The development of cellular immune responses against tumor antigens was first studied by immunizing mice with the PeptiENV complex. The antitumor efficacy and immunity of intratumoral PeptiENV administration were then studied using the murine melanoma models B16.OVA and B16.F10.9/K1. In addition to intratumoral PeptiENV treatment, some of the B16.F10.9/K1-implanted mice were also treated with an anti-PD-1 immune checkpoint inhibitor (ICI) to study the PeptiENV complex as a biological adjuvant for ICIs. Results: The SPR analysis confirmed that CPP-containing peptides can be stably anchored onto the viral envelope of the viral vector. The in vitro results showed that the PeptiENV complex does not hamper the presentation of antigens at the surface of DCs. Additionally, the viral vector was found to activate DCs seen as a change in the cells’ morphology and surface protein expression. Immunizing mice with the PeptiENV complex induced a robust antigen-specific cytotoxic T cell response. Upon intratumoral administration in vivo, the PeptiENV cancer vaccine was not capable of inducing tumor growth control against B16.OVA melanoma, although it did still elicit robust systemic and local antitumor T cell responses. In the treatment of B16.F10.9/K1 melanoma, however, the PeptiENV complex induced efficient tumor growth control, which resulted in a significant survival benefit. Additionally, co-administration of anti-PD-1 resulted in an additive therapeutic effect. Discussion and conclusions: The present study describes a novel, highly immunogenic viral vector-based cancer vaccine that has the potential to be used as an adjuvant treatment for ICI therapy. Subsequent studies could be conducted to gain a deeper understanding of the immunological mechanisms underlying the antitumor efficacy of the cancer vaccine complex. Moreover, this novel PeptiENV complex could also be further developed as an infectious disease vaccine platform against emerging pandemics. However, the effects of pre-existing antiviral immunity on the efficacy of the cancer vaccine should be explored in future studies.