Metabolic reprogramming driven by TFE3 fusions unveils novel vulnerabilities in translocation renal cell carcinoma [ChIP-Seq]

Translocation renal cell carcinoma (tRCC) is an aggressive subtype of kidney cancer driven by TFE3 gene fusions, which act via poorly characterized downstream mechanisms. Here we report that TFE3 fusions transcriptionally rewire tRCCs toward oxidative phosphorylation (OXPHOS), contrasting with the highly glycolytic metabolism of most other RCCs. The transcriptional program driven by TFE3 fusions sustains high NRF2 signaling and glutathione production, which offsets reactive oxygen species generated by OXPHOS but renders tRCC cells sensitive to reductive stress. Genome-scale CRISPR screening identifies tRCC-selective vulnerabilities linked to maintaining this metabolic balance, including EGLN1, which hydroxylates HIF-1a and targets it for proteolysis. Inhibition of EGLN1compromises tRCC cell growth by stabilizing HIF-1a and promoting glycolytic reprogramming. Our study defines a distinctive tRCC-essential metabolic program driven by TFE3 fusions and nominates EGLN1inhibition as a therapeutic strategy to counteract fusion-induced metabolic rewiring. Overall design: To investigate the epigenomics in tRCC, we performed H3K27ac ChIP-Seq in tRCC. And to investigate the role of TFE3 fusion in tRCC, we performed TFE3 ChIP-Seq in three tRCC cell lines.