A major obstacle in the implementation of adoptive cell therapy (ACT) for solid tumors is CD8+ T cell quantity and functional quality. In order to address this issue, the ACT field has directed considerable effort toward the generation of less-differentiated memory T cells (Tm), which demonstrate superior effector function and engraftment over effector T cells. An obstacle in using Tm for ACT is their requirement for in vivo activation before full effector function can be acquired. We sought to determine if a rhabdovirus expressing a defined tumor antigen (i.e. a rhabdoviral oncolytic vaccine) could activate adoptively-transferred Tm in vivo and eliminate established tumors. We used ex vivo cultured DUC18 TCR-transgenic Tm combined with a rhabdoviral oncolytic vaccine to target established CMS5 fibrosarcomas in both balb/c and NRG mice, and we compared the efficacy of the combination treatment versus monotherapies. Our data demonstrate that the rhabdoviral oncolytic vaccine was capable of expanding adoptively-transferred Tm in order to eliminate established tumors. Furthermore, synergy between ACT and oncolytic vaccination was required for optimal therapeutic outcome. Interestingly, we observed a population of endogenous, tumor-primed lymphocytes which appeared to be required for complete tumor elimination and subsequent memory formation. This was in contrast to the current consensus in the ACT field which is that endogenous lymphocytes are detrimental to therapeutic outcome, thus necessitating lymphodepletion prior to the commencement of therapy. Our data suggest that endogenous lymphocytes may be a beneficial cell population which is overlooked by current approaches to ACT. / Thesis / Master of Science (MSc) / Current approaches to the T cell therapy of cancer are hindered by poor cell quality. It is simple to grow higher quality T cells, but it is difficult to grow very large numbers of them. Furthermore, higher quality T cells need a signal in order to “switch on” before they can start killing cancer cells. Here, we use a cancer-targeting virus as a signal for these cells to activate, grow to very large numbers in the patient, and destroy their tumor. Our vaccine also switches on other immune cells in the patient, which help guarantee the destruction of the tumor. The significance of this work is that it will improve T cell therapy for cancer by opening the possibility of using higher-quality T cells which are much better at killing cancer than the currently used type of T cells.
Identifer | oai:union.ndltd.org:mcmaster.ca/oai:macsphere.mcmaster.ca:11375/20441 |
Date | January 2016 |
Creators | Simovic, Boris |
Contributors | Wan, Yonghong, Medical Sciences |
Source Sets | McMaster University |
Language | en_US |
Detected Language | English |
Type | Thesis |
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