1. RB/E2F1 as a Master Regulator of Cancer Cell Metabolism in Advanced Disease
- Author
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Beshara Sheehan, Josep Domingo-Domenech, Amy C. Mandigo, Alec Paschalis, Wei Yuan, Talya S. Laufer, Yi Fang Guan, Denisa Bogdan, Jennifer J. McCann, Robert B. Den, Christopher McNair, Angel Pang, Peter A. McCue, Johann S. de Bono, Jeff Holst, Karen E. Knudsen, Kexin Xu, Nicolas Gordon, Ayesha A. Shafi, Emanuela Dylgjeri, Peter Gallagher, Chellappagounder Thangavel, Matthew J. Schiewer, Saswati N. Chand, and Irina A. Vasilevskaya
- Subjects
Retinal Neoplasms ,Biology ,Retinoblastoma Protein ,Article ,law.invention ,Transcriptome ,Mice ,law ,Cell Line, Tumor ,medicine ,Animals ,Humans ,E2F1 ,Neoplasm Metastasis ,Retinoblastoma ,Cancer ,medicine.disease ,Xenograft Model Antitumor Assays ,Oncology ,Cistrome ,Cancer cell ,Cancer research ,Suppressor ,Reprogramming ,E2F1 Transcription Factor ,Signal Transduction - Abstract
Loss of the retinoblastoma (RB) tumor suppressor protein is a critical step in reprogramming biological networks that drive cancer progression, although mechanistic insight has been largely limited to the impact of RB loss on cell-cycle regulation. Here, isogenic modeling of RB loss identified disease stage–specific rewiring of E2F1 function, providing the first-in-field mapping of the E2F1 cistrome and transcriptome after RB loss across disease progression. Biochemical and functional assessment using both in vitro and in vivo models identified an unexpected, prominent role for E2F1 in regulation of redox metabolism after RB loss, driving an increase in the synthesis of the antioxidant glutathione, specific to advanced disease. These E2F1-dependent events resulted in protection from reactive oxygen species in response to therapeutic intervention. On balance, these findings reveal novel pathways through which RB loss promotes cancer progression and highlight potentially new nodes of intervention for treating RB-deficient cancers. Significance: This study identifies stage-specific consequences of RB loss across cancer progression that have a direct impact on tumor response to clinically utilized therapeutics. The study herein is the first to investigate the effect of RB loss on global metabolic regulation and link RB/E2F1 to redox control in multiple advanced diseases. This article is highlighted in the In This Issue feature, p. 2113
- Published
- 2021
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