The Epigenetic Regulation of Chemotherapy Resistance in Melanoma

Melanoma is rapidly increasing in incidence throughout the world. Early stages are curable with surgical approaches with excellent prognosis. However, a substantial proportion of patients progress to metastatic disease with survival rates of less than 5% making melanoma the culprit for over 65% of all skin-cancer related deaths. Novel agents targeting the immune system and the signaling pathways of melanoma are generating new promise, but chemotherapy remains an important therapeutic alternative, despite low response rates. The resistance of melanoma to chemotherapy is in part due to DNA repair mechanisms that allow cells to survive alkylation damage. Several novel agents targeting the abrogation of DNA repair pathways alone and in combination with cytotoxic agents have been developed with varying measures of success. In this dissertation, we first identified the epigenetic silencing of the DNA mismatch repair (MMR) gene MLH1 as a determinant of response and survival for melanoma patients treated with alkylator-based chemotherapy (dacarbazine/ temozolomide). We then determined the safe dosage of the epigenetic agent decitabine that can be administered in combination with temozolomide. The safety, tolerability and efficacy of the combination of decitabine and temozolomide were evaluated in a Phase II population. We finally determined the pharmacokinetic and pharmacodynamic effects of treatment with the combination of decitabine and temozolomide in the blood and tumor tissues of metastatic melanoma patients