Abstract 1700: Metabolic adaptations confer immunotherapy resistance in melanoma

Abstract

Abstract Background: Despite the success of T-cell checkpoint blockade antibodies in treating an array of cancers, the majority of patients still fail to respond to these therapies, or respond transiently and then relapse. The molecular mechanisms that drive lack of response to checkpoint blockade, whether pre-existing or evolved on therapy, remain unclear. Materials and Methods: To address this critical gap in clinical knowledge, we established a mouse model of melanoma designed to elucidate the molecular mechanisms underlying immunotherapy resistance. Through multiple in vivo passages, we selected a B16 melanoma tumor line that evolved complete resistance to combination blockade of CTLA-4, PD-1, and PD-L1, which cures ~75% of mice of the parental tumor. Using gene expression analysis, proteomics, and immunogenomics, we determined the adaptations engaged by this melanoma to become completely immunotherapy resistant. NMR spectroscopy, Seahorse XF Analysis, flow cytometry, confocal microscopy and Western blot analysis provided further insight into the mechanisms driving checkpoint blockade resistance. Results: Acquisition of immunotherapy resistance by these melanomas was driven by acquisition of a hypermetabolic state through coordinate upregulation of both glycolysis and oxidative phosphorylation (OxPhos). Depletion of essential nutrients from the tumor microenvironment by these resistant tumors functionally compromises infiltrating T cells to an extent that cannot be rescued by even triple checkpoint blockade. The glycolysis and OxPhos-associated genes most highly induced by these resistant melanomas were capable of conferring enhanced resistance to checkpoint blockade when reintroduced monogenically into the parental tumor. We have validated upregulation of these pathways in a unique cohort of melanoma patients who failed dual checkpoint blockade. Additionally, we employed a novel MRI imaging technique to visualize metabolic changes acquired by resistant tumors in live mice. Clinical application of this technique could provide a much-needed noninvasive tool to predict immunotherapeutic sensitivity of patient cancers. Conclusion: Acquisition of a hypermetabolic state by melanoma tumor cells cripples T cells in the microenvironment and confers complete resistance to checkpoint blockade. Citation Format: Ashvin R. Jaiswal, Shivanand Pudakalakatti, Dutta Prasanta, Arthur Liu, Todd Bartkowiak, Casey Ager, Michael A. Davies, Richard E. Davis, Jennifer Wargo, Pratip K. Bhattacharya, David S. Hong, Michael A. Curran. Metabolic adaptations confer immunotherapy resistance in melanoma [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 1700.