Enhanced gene expression of replication fork and other E2F targets genes is associated with sensitivity and, paradoxically, also with acquired drug resistance, to the Chk1 inhibitor prexasertib

Abstract Many cancers are under replicative stress (RS) arising from the combined influence of oncogenic drivers (i.e. Cyclin E, E2F, Myc), genomic instability and/or deficiencies in DNA Damage Repair (DDR). Tumors survive RS by upregulating checkpoints such as those driven by the ATR/CHK1 pathway. Dependence of tumors under high RS on the Chk1 pathway is currently being explored in the clinic with the Chk1 kinase inhibitor prexasertib. Preclinical and clinical studies have demonstrated evidence of efficacy in various cancers supporting the notion that this drug has the potential to improve the standard of care for patients with these malignancies. Two pivotal steps to ultimately fulfill the promise of a novel therapeutic in the clinic are, 1) to enable a patient selection strategy via predictive biomarkers of drug response or de novo resistance; 2) to gain insight into mechanisms underlying the development of acquired resistance, a common phenomenon of cancer therapeutics that contributes to non-durable response. Two experimental objectives to address these challenges for prexasertib were set, 1) to profile a large pan-cancer tumor cell line panel for prexasertib response and explore the association between drug response and baseline molecular profile via transcriptomic profiling, (2) to establish an in vitro tumor line with acquired resistance to prexasertib and characterize it via transcriptomic and targeted proteomic profiling to probe the mechanism of acquired resistance to prexasertib. Key observations from this study: A) pathways corresponding to E2F targets, G2M checkpoint and the Spindle Assembly Checkpoint (SAC), with a distinct enrichment for replication fork genes emerged across three different studies, (a) across a pan-cancer tumor line panel associated with prexasertib sensitivity, (b) associated with resistance in a tumor cell line with acquired resistance to prexasertib and (c) as top hits in an unbiased functional shRNA screen aimed at identifying genes that upon knockdown sensitize the resistant tumor cell line to prexasertib. B)knockdown of specific replication fork components in the drug-resistant tumor line was associated with marked sensitization to prexasertib and concomitant evidence of RS and DNA damage.To explain these paradoxical observations, we postulate that tumors may upregulate the expression of E2F target/G2M/SAC genes to resist oncogene-induced RS and that they may rely on similar genes to survive prexasertib-induced RS. Based on this data, transcriptomic profiling may prove of utility in the identification of patient tailoring biomarkers for prexasertib and as tool to unravel mechanisms of acquired resistance. Citation Format: Wayne D. Blosser, Jack A. Dempsey, Ann M. McNulty, Wenjuan Wu, Philip J. Ebert, Jason C. Ting, Yue W. Webster, Trent R. Stewart, Xueqian Gong, Farhana F. Merzoug, Sean Buchanan, Ricardo Martinez. Enhanced gene expression of replication fork and other E2F targets genes is associated with sensitivity and, paradoxically, also with acquired drug resistance, to the Chk1 inhibitor prexasertib [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 2535.