Browsing by Subject "immunoterapia"
Now showing items 1-2 of 2
-
(2018)During the past few decades, the explosion of discovery in cancer and immunological research has led to the increased understanding of the interactions between the immune system and tumors. These developments have provided vital information about the immune system’s role in cancer development. It is evidenced that the immunity system is capable to distinguish tumor cells from normal tissue by recognizing tumor antigens that are exclusively expressed on tumor cells or are presented in greater amounts on tumor cells than normal cells. Consequently, the immune cells start to attack tumors for protecting the host. The possibility to use the immune system as a weapon against cancer cells leaded to the promising innovation – cancer immunotherapy – which aims to activate the body’s own immune system and its components to mount antitumor immune responses for eliminating cancer cells. The antitumor efficacy and high safety profile of several immunotherapeutic strategies have already been demonstrated thereby resulting in their integration into clinical practice. However, most patients have not benefited from cancer immunotherapy as a single treatment. In this regard, new innovative methods are clearly needed to overcome the obstacles hindering the clinical success of this field. Therapeutic cancer vaccines are emerging as attractive immunotherapies currently being evaluated in both pre-clinical and clinical studies. The purpose of cancer vaccines is to eradicate tumor cells by eliciting antitumor CD8+ T cell responses against the injected tumor antigens. Due to the ability to specifically kill tumor cells and simultaneously trigger immune responses against tumor antigens via direct oncolysis and by encoding transferred tumor antigens, oncolytic viruses are of significant interest for being used as in situ cancer vaccines. Despite these unique properties, several factors such as tumor immunosuppression and immune tolerance to targeted tumor antigens resembling antigens of normal tissues hamper the use of oncolytic vaccines in clinic. Instead of focusing only on CD8+ T cells, it has been suggested that giving more attention to CD4+ T helper cells, which are required for priming and expansion of CD8+ T cell responses, could be the key to improve the efficacy of cancer vaccines. Researchers have also demonstrated that an ongoing antigen-specific CD4+ T cell response can lead to the bystander activation of surrounding T cells with unrelated antigen specificities. Based on this theory, the hypothesis of this study was to employ the pre-existing immunological CD4+ memory against infectious pathogens in generating bystander CD8+ immunity against solid tumors. In this study, mice transplanted with poorly immunogenic B16-OVA tumors were pre-immunized with the chosen vaccine to induce immunological CD4+ memory against an infectious pathogen. Tumors were then treated with already developed cancer vaccine, which was peptide-coated conditionally replicating adenovirus (PeptiCRAd) complex. PeptiCRAd was constructed by electrostatically coating adenovirus with both pathogen-derived and tumor-derived peptide. The intratumorally injected double-coated PeptiCRAd complex was assumed to activate peptide-specific T cells and thus, result in anti-pathogen CD4+ T cell recall responses and the following bystander activation of antitumor CD8+ T cells, which can then mount an effective immune response to destroy cancer cells. The efficacy of this treatment was observed in pre-immunized mice by measuring the growth of injected tumors. The experiment was repeated identically with non-immunized naïve mice to see the difference in the results. The immunological background of this treatment approach was investigated by analyzing mouse tissue samples with standard immunological techniques including ELISA, IFN-γ ELISPOT and flow cytometry. This study showed that long-term immunological memory against the pathogen was successfully accomplished and the strongest inhibition of tumor growth in pre-immunized mice was achieved with double-coated PeptiCRAd, whereas the antitumor efficacy was not seen in naïve mice. Additionally, a new ex vivo method to detect pathogen-specific CD4+ T cells from spleen was developed and the stimulation of cell-mediated immunity by this treatment was supported by finding the highest levels of pathogen-specific CD4+ Th1 cells from mice treated with double-coated PeptiCRAd. Some encouraging results concerning the beneficial immune cell composition of tumors and tumor draining lymph nodes were also obtained from other performed experiments. Though further immunological analyses are required for understanding the precise mechanisms of action behind the treatment, the increased immunogenicity and antitumor efficacy of double-coated PeptiCRAd can still be considered as a consequence of the bystander effect, which can possibly be utilized for developing improved strategies to win the fight against cancer.
-
(2018)Cancer immunotherapies aim to target the immune defence mechanisms of the body specifically and efficiently against the tumour tissue. Cancer vaccines and oncolytic viruses are forms of active immunotherapies, which require patients having a properly functioning immune system. The vaccines are based on the administration of tumour antigens into the body to which the immune system reacts. However, often the response is not robust enough. The oncolytic viruses in turn kill the cancer cells which causes the release of antigens from the tumour tissue. Viruses usually elicit a strong immune response but sometimes it is targeted too much against the virus instead of the tumour. Oncolytic vaccine is a composition of an oncolytic virus and a cancer vaccine. Tumour antigens can be coded to the genome of the virus therefore, when the virus invades tumour cells they start to produce the antigens. Eventually the cancer cells are also destroyed due to viral replication. The antigens can be tumour-associated that is, they are expressed in healthy tissues too. Their usage is not always efficient which is why an interest towards utilizing tumour-specific antigens has been increased. Considering the expression of antigens, tumour tissue is very heterogenous and distinctive between patients. Hence, utilizing mutated patient unique neoantigens would enable the development of personalized tumour-specific oncolytic vaccines. Genetic modification of viruses is complicated thus, an easier way to insert the neoantigens to the virus has been invented. The developed oncolytic vaccine platform is called PeptiENV, and it is designed to use with enveloped viruses. The idea is to fuse tumour-specific antigens onto the envelope of the virus and eliminate the need of gene insertion. The aim of this study is to investigate in vivo the efficacy of PeptiENV in preventing tumour growth and eliciting a tumour-specific immune response. An object is also to observe survival times of the treated animals. Furthermore, the preservation of infectivity is studied in vitro. The research was executed with two potential oncolytic viruses, vaccinia virus (VACV) and herpes simplex virus type 1 (HSV-1). The PeptiENV complex was formed by using an artificial tumour antigen, ovalbumin epitope SIINFEKL, which was attached to the viral envelope with cell penetrating peptide (CPP) or cholesterol anchor. The preservation of infectivity was examined by measuring cell viability of PeptiENV infected cells. Animal experiments instead were performed with a mouse melanoma model created with B16-OVA cells, which express ovalbumin and therefore the antigen epitope SIINFEKL. PeptiENV was compared to control treatments which were virus, SIINFEKL peptide and complexation medium only. Treatments were administered as intratumoural injections. Tumour growth was followed by measuring the size of implanted tumours every other day. With flow cytometry, tumour-specific immune response was assessed by acquiring the relative amount of SIINFEKL-specific CD8+ T cells in the tumour tissue. Euthanizing dates were registered in order to observe the survival of the mice. According to the in vitro results, conjugation of peptides to the virus does not affect infectivity. In addition, the in vivo studies show that PeptiENV VACV CPP prevents tumour growth the most. Difference in tumour growth between PeptiENV VACV CPP and control treatments is significant. Mice injected with the same treatment also lived considerably longer than mice injected with virus, peptide or medium only. Also, PeptiENV HSV-1 hinders tumour growth distinctly more than virus only and slightly more than SIINFEKL only, but unfortunately it did not have an evident impact on the survival time. In both experiments, the PeptiENV treatment elicits the largest proportional amount of SIINFEKL-specific CD8+ T cells. In other words, PeptiENV engenders a tumour-specific immune response. In the PeptiENV VACV study the difference to control treatments is clearer than in the PeptiENV HSV-1 study. At present, the PeptiENV platforms performs better with VACV than HSV-1. With further investigations however, the results can be verified and improved. All in all, the results are encouraging. The PeptiENV platform shows great promise for being a part of personalized cancer immunotherapy developments in the future.
Now showing items 1-2 of 2