Sir Peter MacCallum Department of Oncology - Theses
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ItemInvestigating the role of Mucosal-Associated Invariant T (MAIT) cells in cancer( 2021)The success of immunotherapy in patients has highlighted the importance of the anti-tumour role of the immune system. The function of conventional T cells within the tumour microenvironment (TME) have been intensively studied, while the role of mucosal-associated invariant T (MAIT) cells is yet to be determined. MAIT cells are abundant in humans and enriched in mucosal tissues, such as the colon and lung, and have been found within primary and metastatic tumours. Upon activation, MAIT cells exert rapid effector functions and can secrete both the anti-tumour cytokines (IFNg and TNF) and pro-tumour cytokines (IL-17 and IL-22). MAIT cells also produce granzyme B and perforin, suggesting they are capable of killing target cells. Although direct evidence of MAIT cells precise function in cancer is limited, some studies show that increased numbers of MAIT cells within tumours are correlated with a good prognosis, whilst other studies have indicated MAIT cells are associated with a poorer prognosis. These divergent results have made it difficult to interpret whether MAIT cells have an anti-tumour or pro-tumour role. Therefore, this thesis investigated the role of MAIT cells in cancer and the potential for MAIT cells to be exploited for adoptive cellular therapy. The first results chapter of this thesis explores the anti-tumour role of MAIT cells in both murine and ex vivo human models. It was observed that at steady-state, MAIT cells negatively regulate NK cell maturation and anti-tumour activity. Conversely, activating MAIT cells through either pulsing of tumour targets or intranasal administration of free MAIT cell antigen, led to robust protection against the development of lung metastases. Upon further investigation, it was discovered that activated MAIT cells enhance NK cell maturation and anti-tumour activity in an IFNg-dependent manner. This chapter proposes the existence of a MAIT-NK cell axis that can control NK cell mediated anti-tumour efficacy. The second results chapter aims to further improve the anti-tumour efficacy of activated MAIT cells, by combining this therapy with additional immunotherapies. The additional immunotherapies tested in combination with MAIT cell activation were selected on the basis of their ability to activate MAIT cells and/or NK cells. Notably, additional therapies that increased both MAIT cell and NK cell activity were most promising. This chapter also found that intravenous administration of MAIT cell antigen led to systemic expansion of MAIT cells and an increase in MAIT cells within the tumour tissue, broadening the application of activating MAIT cells in the clinic. The third results chapter aims to investigate the potential of MAIT cells in the context of Chimeric antigen receptor (CAR) T cell therapy. CAR T cell therapy is currently ineffective in solid tumours, due to the immunosuppressive TME, antigen heterogeneity, poor trafficking to solid tumours and decreased persistence. Furthermore, this therapy requires autologous generation of CAR cells in order to avoid graft versus host disease (GVHD). Excitingly, MAIT cells represent an allogeneic source of CAR cells as they are not restricted to conventional MHC. Chapter 5 demonstrates that MAIT cells are able to be efficiently transduced with CAR and upon target recognition CAR MAIT cells produce cytokines and directly kill tumour cells. Collectively, this data illustrates the potential anti-tumour activity of MAIT cells through a MAIT-NK cell axis. Furthermore, this thesis demonstrates the potential for MAIT cells to be used in adoptive cellular therapy, namely as CAR MAIT cells.