TRLS-14. TARGETING REPLICATIVE STRESS IN BRAIN TUMORS BY COMBINING ATR AND PARP INHIBITION

Pediatric brain tumors like MYC-amplified Medulloblastomas (MB) and Atypical Teratoid and Rhabdoid Tumors (AT/RT) continue to have poor survival rates despite recent advances in understanding tumor biology. MYC is an oncogenic transcription factor often expressed in MB and AT/RT at high levels. While direct inhibition of MYC by small molecules is an active area of research, such approaches lack clinical validation and are not yet actionable. Strategies to target MYC-driven brain tumors that are immediately translatable are urgently needed. Replication stress has been identified as a prominent source of tumorigenesis over the past decade and is a potential target for cancer therapy. Specific oncogenes induce elevated levels of replicative stress through aberrant activation of transcription and dysregulation of DNA replication. In these instances, replicative stress could be rescued by either metabolic supplementation or MYC expression. The activation of ATR and PARP are critical events in response to replicative stress. PARP inhibitors stall replication forks and promote the generation of single-strand DNA, which activates ATR. Genetic and pharmacological evidence suggests the sensitization of MYC-induced tumors to PARP inhibitors. Preclinical studies in diverse tumor backgrounds have demonstrated that the combination of ATR and PARP inhibition is synergistic and leads to premature entry into mitosis, enhanced replicative stress and cell death, and tumor regression. Additionally, a reduction in ATR activity can be lethal in oncogene-induced replication stress. Using high throughput drug screening across MB and AT/RT cell lines, we found that the CNS penetrant PARP inhibitor AZD9754 significantly potentiated the cytotoxicity of ATR inhibition. This emerging synergistic combination therapy reveals new therapeutic targets in MYC-driven replicative stress. Studies are ongoing to validate in vitro findings in vivo.