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Surface expression of Tim-3 inhibitory molecule on antigen-specific CD8+ T cells expanded in vitro using dendritic cells for cell-based cancer immunotherapy
Svobodová, Hana ; Smrž, Daniel (advisor) ; Funda, David (referee)
Cancer is the second most common cause of death in the world, and the number of people with the disease increases each year. The therapy of the disease currently stands on four pillars; surgery, chemotherapy, radiotherapy, and immunotherapy. Through the past few years, immunotherapy has become the fastest developing treatment modality. However, despite its unprecedented efficacy in some patients, the majority of patients still does not respond to the therapy. Therefore, there is a need to investigate the mechanisms that make immunotherapy inefficient. Cell-based cancer immunotherapy is the treatment modality which uses live ex vivo-produced tumor-targeting immune cells to treat cancer. One of the mechanisms that may compromise its therapeutic efficacy is the expression of inhibitory molecules on the surface of the produced immune cells. Tim-3 is the inhibitory molecule which attracts attention in recent years. Tim-3 expression in the tumor cells and the tumor-infiltrating immune cells is often associated with worse prognosis and more aggressive forms of the disease. However, its role in the in vitro or ex vivo-produced immune cells is difficult to predict. In this work, an in vitro study model which is based on in vitro-produced antigen-specific CD8+ T cells with high expression of Tim-3 has been...
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Tumor-infiltrating T cells and their role in adoptive cell immunotherapy of cancer
Střížová, Zuzana ; Smrž, Daniel (advisor) ; Vannucci, Luca Ernesto (referee) ; Posová, Helena (referee)
Cancer immunotherapy has become a leading treatment modality in metastatic diseases. Although this novel therapy has changed the therapeutic algorithms and patients' outcomes in multiple malignancies, certain proportions of patients still fail to respond to these approaches. In our studies, we aimed to address the main mechanisms of tumor resistance to cancer immunotherapy. We have systematically defined the main challenges in adoptive cell transfer. We have focused on two key mechanisms of the tumor resistance to immunotherapy: poor trafficking of adoptively transferred immune cells into tumors, and the death receptor-induced apoptosis of the tumor-infiltrating immune cells. In our work, we have gone beyond the tumor tissue and searched for the immune cell populations and novel targets that would help to challenge the two mechanisms of resistance. Our data uncovered the therapeutic potential of the paratumoral tissue compartments and, thus, provided new avenues on how to challenge solid tumors by immunotherapy.
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Surface expression of Tim-3 inhibitory molecule on antigen-specific CD8+ T cells expanded in vitro using dendritic cells for cell-based cancer immunotherapy
Svobodová, Hana ; Smrž, Daniel (advisor) ; Funda, David (referee)
Cancer is the second most common cause of death in the world, and the number of people with the disease increases each year. The therapy of the disease currently stands on four pillars; surgery, chemotherapy, radiotherapy, and immunotherapy. Through the past few years, immunotherapy has become the fastest developing treatment modality. However, despite its unprecedented efficacy in some patients, the majority of patients still does not respond to the therapy. Therefore, there is a need to investigate the mechanisms that make immunotherapy inefficient. Cell-based cancer immunotherapy is the treatment modality which uses live ex vivo-produced tumor-targeting immune cells to treat cancer. One of the mechanisms that may compromise its therapeutic efficacy is the expression of inhibitory molecules on the surface of the produced immune cells. Tim-3 is the inhibitory molecule which attracts attention in recent years. Tim-3 expression in the tumor cells and the tumor-infiltrating immune cells is often associated with worse prognosis and more aggressive forms of the disease. However, its role in the in vitro or ex vivo-produced immune cells is difficult to predict. In this work, an in vitro study model which is based on in vitro-produced antigen-specific CD8+ T cells with high expression of Tim-3 has been...
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