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Merkel cell carcinoma (MCC) is a rare and aggressive skin cancer with an increasing incidence. The majority of MCC cases (approximately 80%) are associated with the Merkel cell polyomavirus (MCPyV). This virus encodes for the MCPyV T antigens (small T (sT) and large T (LT)), which are oncoproteins that drive MCC carcinogenesis. However, the precise cells of the skin that are transformed by the T antigens are not known i.e., the cells of origin of MCC are yet to be discovered. Therefore, the first part of this study involved the generation and evaluation of a vector system that could be used to study MCC oncogenesis. To this end, a set of lentiviral vectors was cloned that allows independent, inducible expression of potential key factors in MCC oncogenesis. In addition, a CRISPR/Cas9 knock in was established that allows the coding sequence for a fluorescent protein to be placed under the control of the promoter of KRT20, one of the most crucial markers of MCC. The functionality of this KRT20 reporter was proven in the MCPyV-positive MCC cell line, WaGa. The different inducible vector systems (doxycycline-inducible MCPyV T antigens or MCPyV sT, RheoSwitch-inducible ATOH1 and IPTG-inducible dnMAML1 and GLI1) were found to have different efficacies in various cellular systems and in particular, a considerable reduction in efficiency was observed at times upon the interaction of several vectors in one cell. In the second and more important part of this study, the role of the well-established anti-malarial drug, artesunate, which possesses additional anti-tumor and anti-viral activity, in the treatment of MCPyV-positive MCC was analyzed. In our study, artesunate was found to be cytotoxic towards MCPyV-positive MCC cell lines in vitro and repressed tumor growth in vivo in a mouse model. Artesunate was also found to downregulate T antigen expression, which is critical for the proliferation of MCPyV-positive MCC cells. The repression of T antigen expression, however, was not the sole mechanism of artesunate’s cytotoxic action; instead, the MCPyV-positive MCC cell line, WaGa, was found to be even less sensitive to artesunate after shRNA knockdown of the T antigens. Since loss of membrane integrity occurred more rapidly than degradation/loss of genomic DNA under the influence of artesunate in four of five MCPyV-positive MCC cell lines examined, apoptosis, although widely described as a modus operandi for artesunate, did not appear to be a determinant of the cytotoxicity of artesunate against MCPyV-positive MCC cells. Instead, we were able to demonstrate that artesunate induced the recently described iron-dependent and lipid peroxide-associated form of cell death known as "ferroptosis". This was achieved primarily through the use of inhibitors that can suppress specific individual steps of the ferroptotic process. Thus, artesunate-induced cell death of MCPyV-positive MCC cells could be suppressed by iron chelators and by the inhibition of lipid peroxidation and lysosomal transport. Surprising results were obtained from the analysis of two proteins associated with the ferroptotic process, namely, ferroptosis suppressor protein 1 (FSP1) and tumor suppressor protein p53. Here, we showed that ectopically- 2 expressed FSP1 cannot suppress artesunate-induced ferroptosis in MCPyV-positive MCC cells and that p53 does not play a pro-ferroptotic role in artesunate-induced cell death of MCPyV-positive MCCs. Since artesunate did not suppress the interferon-γ-induced expression of immune-related molecules such as HLA and PD-L1 on the surface of MCPyV-positive MCCs, our study also provided the first positive evidence for its use in combinatorial immunotherapy. Overall, this study showed that artesunate appears to be an effective drug for the treatment of MCPyV-positive MCC and might also be considered for its use in combinatorial MCC immunotherapy in the future.
Melanoma and Merkel cell carcinoma (MCC) are highly aggressive cancers of the skin that frequently escape immune recognition and acquire resistance to chemotherapeutic agents, which poses a major obstacle to successful cancer treatment. Recently, a new class of therapeutics targeting the programmed cell death-1 (PD-1) immune checkpoint receptor has shown remarkable efficacy in the treatment of both cancers. Blockade of PD-1 on T cells activates cancer-specific immune responses that can mediate tumor regression. The data presented in this Ph.D. thesis demonstrates that PD-1 is also expressed by subsets of cancer cells in melanoma and MCC. Moreover, this work identifies PD-1 as a novel tumor cell-intrinsic growth receptor, even in the absence of T cell immunity. PD-1 is expressed by tumorigenic cell subsets in melanoma patient samples and established human and murine cell lines that also co-express ABCB5, a marker of immunoregulatory tumor- initiating cells in melanoma. Consistently, melanoma-expressed PD-1 downmodulates T effector cell functions and increases the intratumoral frequency of tolerogenic myeloid- derived suppressor cells. PD-1 inhibition on melanoma cells by RNA interference, blocking antibodies, or mutagenesis of melanoma-PD-1 signaling motifs suppresses tumor growth in immunocompetent, immunocompromised, and PD-1-deficient tumor graft recipient mice. Conversely, melanoma-specific PD-1 overexpression enhances tumorigenicity, including in mice lacking adaptive immunity. Engagement of melanoma- PD-1 by its ligand PD-L1 promotes tumor growth, whereas melanoma-PD-L1 inhibition or knockout of host-PD-L1 attenuates growth of PD-1-positive melanomas. Mechanistically, the melanoma-PD-1 receptor activates mTOR signaling mediators, including ribosomal protein S6. In a proof-of-concept study, tumoral expression of phospho-S6 in pretreatment tumor biopsies correlated with clinical responses to anti-PD-1 therapy in melanoma patients. In MCC, PD-1 is similarly co-expressed by ABCB5+ cancer cell subsets in clinical tumor specimens and established human cell lines. ABCB5 renders MCC cells resistant to the standard-of-care chemotherapeutic agents, carboplatin and etoposide. Antibody-mediated ABCB5 blockade reverses chemotherapy resistance and inhibits tumor xenograft growth by enhancing chemotherapy-induced tumor cell killing. Furthermore, engagement of MCC-expressed PD-1 by its ligands, PD-L1 and PD-L2, promotes proliferation and activates MCC-intrinsic mTOR signaling. Consistently, antibody- mediated PD-1 blockade inhibits MCC tumor xenograft growth and phosphorylation of mTOR effectors in immunocompromised mice. In summary, these findings identify cancer cell-intrinsic functions of the PD-1 pathway in tumorigenesis and suggest that blocking melanoma- and MCC-expressed PD-1 might contribute to the striking clinical efficacy of anti-PD-1 therapy. Additionally, these results establish ABCB5 as a previously unrecognized chemoresistance mechanism in MCC.