Abstract 232: Comprehensive metabolic profiling and vulnerabilities to metabolic inhibitors among small cell lung cancer subtypes

Abstract

Abstract Small cell lung cancer (SCLC) is an aggressive neuroendocrine tumor that constitutes approximately 14% of all lung cancers diagnosed in the United States. Despite recent advances in treatment options, recurrence is a major challenge and long-term survival remains poor underscoring the importance of investigating mechanisms of treatment resistance and therapeutic strategies. Interestingly, our laboratory has recently uncovered evidence for the classification of SCLC into distinct subtypes, each with unique gene expression patterns and therapeutic vulnerabilities. These subtypes are characterized by differential expression of the transcription factors ASCL1, NEUROD1, or POU2F3. A fourth subtype is negative for all three transcription factors and has prominent expression of immune genes, thus is termed the Inflamed subtype. These subtypes are associated with differences in drug sensitivity, biomarker signatures, and mechanisms of cellular growth. One facet of tumor biology that has not been explored across the subtypes, or in SCLC in general, is the metabolic mechanisms of energy generation. Although metabolic reprogramming from mitochondrial respiration to glycolysis is considered a major hallmark of cancer, increasing evidence suggests that mitochondrial or amino acid dependencies may also contribute to treatment resistance. Therefore, understanding the metabolic demand, particularly among the subtypes, is critical for the development of new therapies. To address this, gene set enrichment analysis was applied to 81 human SCLC tumors categorized by subtype, and revealed differential gene expression correlating to pathways such as fatty acid metabolism in POU2F3 and reactive oxygen species in Inflamed that was confirmed by reverse phase protein analysis (RPPA). Further, we evaluated nutrient requirements, glycolysis dependence, and mitochondrial function in human SCLC cell lines and found differences in glucose uptake and subsequent lactate generation between the subtypes suggesting that glycolysis inhibition may be effective in particular subsets. Based on this, we then tested the efficacy of PFK-158 (glycolysis inhibitor) on cellular proliferation and metabolic function in these cell lines, which revealed variations in susceptibility dependent on subtype classification. Together, this data serves to enhance the current understanding of SCLC mechanisms of growth and provides evidence for metabolic inhibition as a potential therapeutic opportunity. Citation Format: Kasey R. Cargill, Carl M. Gay, Robert J. Cardnell, You-Hong Fan, Qi Wang, Lixia Diao, Jing Wang, Lauren A. Byers. Comprehensive metabolic profiling and vulnerabilities to metabolic inhibitors among small cell lung cancer subtypes [abstract]. In: Proceedings of the Annual Meeting of the American Association for Cancer Research 2020; 2020 Apr 27-28 and Jun 22-24. Philadelphia (PA): AACR; Cancer Res 2020;80(16 Suppl):Abstract nr 232.