Harnessing synthetic lethality to predict the response to cancer treatment

Joo Sang Lee; Avinash Das; Livnat Jerby‐Arnon; Rand Arafeh; Noam Auslander; Matthew Davidson; Lynn McGarry; Daniel James; Arnaud Amzallag; Seung Gu Park; Kuoyuan Cheng; Welles Robinson; Dikla Atias; Chani Stossel; Ella Buzhor; Gidi Stein; Joshua J. Waterfall; Paul S. Meltzer; Talia Golan; Sridhar Hannenhalli; Eyal Gottlieb; Cyril H. Benes; Yardena Samuels; Emma Shanks; Eytan Ruppin

doi:10.1038/s41467-018-04647-1

Harnessing synthetic lethality to predict the response to cancer treatment

Joo Sang Lee(National Cancer Institute), Avinash Das(University of Maryland, College Park), Livnat Jerby‐Arnon(Tel Aviv University), Rand Arafeh(Weizmann Institute of Science), Noam Auslander(National Cancer Institute), Matthew Davidson(Cancer Research UK Scotland Institute), Lynn McGarry(Cancer Research UK Scotland Institute), Daniel James(Cancer Research UK Scotland Institute), Arnaud Amzallag(Harvard University), Seung Gu Park(University of Maryland, College Park), Kuoyuan Cheng(National Cancer Institute), Welles Robinson(National Cancer Institute), Dikla Atias(Sheba Medical Center), Chani Stossel(Sheba Medical Center), Ella Buzhor(Sheba Medical Center), Gidi Stein(Tel Aviv University), Joshua J. Waterfall(National Institutes of Health), Paul S. Meltzer(National Institutes of Health), Talia Golan(Tel Aviv University), Sridhar Hannenhalli(University of Maryland, College Park), Eyal Gottlieb(Cancer Research UK Scotland Institute), Cyril H. Benes(Harvard University), Yardena Samuels(Weizmann Institute of Science), Emma Shanks(Cancer Research UK Scotland Institute), Eytan Ruppin(Tel Aviv University)

Nature Communications

June 25, 2018

10.1038/s41467-018-04647-1

Cited by 141Open Access

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Abstract

While synthetic lethality (SL) holds promise in developing effective cancer therapies, SL candidates found via experimental screens often have limited translational value. Here we present a data-driven approach, ISLE (identification of clinically relevant synthetic lethality), that mines TCGA cohort to identify the most likely clinically relevant SL interactions (cSLi) from a given candidate set of lab-screened SLi. We first validate ISLE via a benchmark of large-scale drug response screens and by predicting drug efficacy in mouse xenograft models. We then experimentally test a select set of predicted cSLi via new screening experiments, validating their predicted context-specific sensitivity in hypoxic vs normoxic conditions and demonstrating cSLi's utility in predicting synergistic drug combinations. We show that cSLi can successfully predict patients' drug treatment response and provide patient stratification signatures. ISLE thus complements existing actionable mutation-based methods for precision cancer therapy, offering an opportunity to expand its scope to the whole genome.

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