Abstract 1932: Mutations in ATRX increase genetic instability and sensitivity to PARP inhibitors in paediatric glioblastoma cells

Abstract

Abstract Paediatric glioblastomas (pGBM) are amongst the most common causes of cancer-related deaths in children, and are defined by highly recurrent mutations in H3 histones. Mutations affecting the chromatin remodeling protein ATRX have been reported in 30% of pGBM cases, and are strongly associated with the alternative lengthening of telomeres (ALT) phenotype, but their precise interaction with histone mutations and their role in tumorigenesis remain unclear. We collected sequence data from 262 published and 64 unpublished cases of pGBM and identified somatic ATRX mutations in 54/326 (17%) of cases. ATRX mutations are mainly loss of function mutations, with the majority of frameshift mutations (37/54, 68,5%) found upstream of the helicase domain resulting in truncation of the main functional domain of ATRX. Missense mutations (16/54, 29,6%) reside almost exclusively in the helicase domain (11/54, 20,4%), whereas nonsense mutations are a less common event (7/54, 13%) but present in both the helicase (4/7, 57,1%) and ADD domains (3/7, 42,9%). ATRX mutations commonly co-segregate with H3.3 G34 (16/54) and TP53 (42/54) mutations, and define a subgroup of patients with a longer overall survival (16 months median overall survival in mutant ATRX cases versus 11 months in wild-type ATRX cases, COXPH p = 0.079), though with a greater number of somatic mutations (MWU p = 0.023) and copy number alterations (MWU p = 0.0011) than wild-type cases. We screened a series of 21 primary patient-derived pGBM cell cultures for histone and ATRX mutation status in addition to ATRX protein expression and ALT, and subjected the panel to a high-throughput in vitro cell viability screen of >400 chemotherapeutics and small molecules. We identified a specific genetic dependency for ATRX mutation and sensitivity to distinct PARP inhibitor chemotypes, including olaparib and rucaparib (PARP catalytic inhibitors), and talazoparib (PARP trapper inhibitor). These data were validated using CRISPR-Cas9-engineered ATRX knockout, targeting either the ADD or helicase domain, in SF188 pGBM cells. Gene editing was confirmed by IonTorrent sequencing and Western blot. ATRX mutant clones were also more sensitive to drugs targeting DNA damage response pathways such as bleomycin and sapacitabine. Gene expression analysis of ATRX mutant pGBM samples confirmed an intact homologous recombination pathway and overexpression of PARP1, suggesting an underlying mechanism distinct from that observed in BRCA-mutant breast and ovarian cancers. Ongoing work is aimed at unravelling the specific pathways involved, and evaluating the utility of PARP inhibition in orthotopic pGBM xenografts in vivo. These data suggest a synthetic lethality for PARP inhibitors in ATRX-deficient pGBM cells, and may represent a novel therapeutic strategy for these highly aggressive tumours in children. Citation Format: Janat Fazal-Salom, Mara Vinci, Diana Carvalho, Helen Pemberton, Stephen J. Pettitt, Christopher J. Lord, Alan Mackay, Lynn Bjerke, Chris Jones. Mutations in ATRX increase genetic instability and sensitivity to PARP inhibitors in paediatric glioblastoma cells [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 1932. doi:10.1158/1538-7445.AM2017-1932