SMARCAL1 is a targetable synthetic lethal therapeutic vulnerability in ATRX-deficient gliomas that use Alternative Lengthening of Telomeres.

BACKGROUND: Approximately 10% of cancers achieve replicative immortality through a telomerase-independent mechanism of telomere maintenance, termed Alternative Lengthening of Telomeres (ALT). ALT is particularly prevalent in certain subtypes of malignant gliomas, such as IDH-mutant astrocytoma and pediatric glioblastoma, and frequently co-occurs with ATRX inactivating mutations. Although ALT is an adaptive mechanism through which cancer cells achieve proliferative immortality, the elevated levels of replication stress observed in ALT tumors constitute a potential therapeutic vulnerability. METHODS: Leveraging CRISPR/Cas9 screening data from the Cancer Dependency Mapping Project, coupled with patient-derived cell lines and xenografts, we identified SMARCAL1 as a novel synthetic lethal vulnerability in ATRX-deficient glioma models that engage ALT. Using complementary molecular assays for DNA damage, telomere maintenance, and telomeric replication stress, we define the mechanisms underlying cytotoxicity induced by SMARCAL1 depletion in ALT-positive glioma cells. RESULTS: Our data demonstrate the annealing helicase SMARCAL1 is a highly specific synthetical lethal vulnerability in cancers that use ALT. SMARCAL1 localizes to ALT-associated PML bodies in ALT-positive glioma cell lines, including IDH-mutant astrocytomas. SMARCAL1 depletion, via doxycycline-induced RNAi, led to a hyperactivation of the ALT phenotype, high levels of DNA double-strand breaks in G2 phase, and cell death via mitotic catastrophe. In mice bearing intracranial xenografts derived from high-grade IDH-mutant astrocytoma, inducible SMARCAL1 depletion prolonged animal survival. CONCLUSIONS: Our findings demonstrate that the molecular processes orchestrating ALT-mediated telomere maintenance constitute a targetable synthetic lethal vulnerability that can be exploited by SMARCAL1 inhibition, thus supporting the future development of small molecule inhibitors of SMARCAL1 as anti-cancer therapeutics.

Duke Scholars

Author Lee Zou Pharmacology & Cancer Biology

Author Roger Edwin McLendon Pathology

Author Zachary James Reitman Radiation Oncology

Author David Michael Ashley Neurosurgery