Discovery and Clinical Proof-of-Concept of RLY-2608, a First-in-Class Mutant-Selective Allosteric PI3Kα Inhibitor That Decouples Antitumor Activity from Hyperinsulinemia

Andreas Varkaris; Ermira Pazolli; Hakan Günaydin; Qi Wang; Levi Pierce; Alessandro A. Boezio; Artemisa Bulku; Lucian DiPietro; Cary Fridrich; Adam Frost; Fabrizio Giordanetto; Erika Hamilton; Katherine Harris; Michael Holliday; Tamieka L. Hunter; Amanda Iskandar; Yongli Ji; Alexandre Larivée; Jonathan R. LaRochelle; André Lescarbeau; Fabien Llambi; Brenda Lormil; Mary M. Mader; Brenton G. Mar; Iain Martin; Thomas H. McLean; Klaus Michelsen; Yakov Pechersky; Erika Puente-Poushnejad; Kevin Raynor; Dipali Rogala; Ramin Samadani; Alison M. Schram; Kelley Shortsleeves; Sweta Swaminathan; Shahein Tajmir; Gege Tan; Yong Tang; Roberto Valverde; Bryan Wehrenberg; Jeremy Wilbur; Bret R. Williams; Hongtao Zeng; Hanmo Zhang; W. Patrick Walters; Beni B. Wolf; David E. Shaw; Donald A. Bergstrom; James Watters; James S. Fraser; Pascal D. Fortin; D. Randal Kipp

doi:10.1158/2159-8290.cd-23-0944

Discovery and Clinical Proof-of-Concept of RLY-2608, a First-in-Class Mutant-Selective Allosteric PI3Kα Inhibitor That Decouples Antitumor Activity from Hyperinsulinemia

Andreas Varkaris(Massachusetts General Hospital), Ermira Pazolli(Xilio Therapeutics (United States)), Hakan Günaydin(Relay Therapeutics (United States)), Qi Wang(D. E. Shaw Research), Levi Pierce(Xilio Therapeutics (United States)), Alessandro A. Boezio(Relay Therapeutics (United States)), Artemisa Bulku(Xilio Therapeutics (United States)), Lucian DiPietro(Relay Therapeutics (United States)), Cary Fridrich(Xilio Therapeutics (United States)), Adam Frost(QB3), Fabrizio Giordanetto(D. E. Shaw Research), Erika Hamilton(Sarah Cannon), Katherine Harris(North Shore Community College), Michael Holliday(Relay Therapeutics (United States)), Tamieka L. Hunter(Relay Therapeutics (United States)), Amanda Iskandar(Relay Therapeutics (United States)), Yongli Ji(Exeter Hospital), Alexandre Larivée(Paraza Pharma (Canada)), Jonathan R. LaRochelle(Relay Therapeutics (United States)), André Lescarbeau(Relay Therapeutics (United States)), Fabien Llambi(Relay Therapeutics (United States)), Brenda Lormil(Massachusetts General Hospital), Mary M. Mader(Indiana Biosciences Research Institute), Brenton G. Mar(Relay Therapeutics (United States)), Iain Martin(Relay Therapeutics (United States)), Thomas H. McLean(Relay Therapeutics (United States)), Klaus Michelsen(Relay Therapeutics (United States)), Yakov Pechersky(D. E. Shaw Research), Erika Puente-Poushnejad(Relay Therapeutics (United States)), Kevin Raynor(Xilio Therapeutics (United States)), Dipali Rogala(Xilio Therapeutics (United States)), Ramin Samadani(Relay Therapeutics (United States)), Alison M. Schram(Memorial Sloan Kettering Cancer Center), Kelley Shortsleeves(Relay Therapeutics (United States)), Sweta Swaminathan(Relay Therapeutics (United States)), Shahein Tajmir(Harvard University), Gege Tan(Relay Therapeutics (United States)), Yong Tang(Relay Therapeutics (United States)), Roberto Valverde(Relay Therapeutics (United States)), Bryan Wehrenberg(Relay Therapeutics (United States)), Jeremy Wilbur(Relay Therapeutics (United States)), Bret R. Williams(Relay Therapeutics (United States)), Hongtao Zeng(Relay Therapeutics (United States)), Hanmo Zhang(Xilio Therapeutics (United States)), W. Patrick Walters(Massachusetts General Hospital), Beni B. Wolf(Xilio Therapeutics (United States)), David E. Shaw(D. E. Shaw Research), Donald A. Bergstrom(Relay Therapeutics (United States)), James Watters(Relay Therapeutics (United States)), James S. Fraser(QB3), Pascal D. Fortin(Relay Therapeutics (United States)), D. Randal Kipp(Relay Therapeutics (United States))

Cancer Discovery

November 2, 2023

10.1158/2159-8290.cd-23-0944

Cited by 90Open Access

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Abstract

Abstract PIK3CA (PI3Kα) is a lipid kinase commonly mutated in cancer, including ∼40% of hormone receptor–positive breast cancer. The most frequently observed mutants occur in the kinase and helical domains. Orthosteric PI3Kα inhibitors suffer from poor selectivity leading to undesirable side effects, most prominently hyperglycemia due to inhibition of wild-type (WT) PI3Kα. Here, we used molecular dynamics simulations and cryo-electron microscopy to identify an allosteric network that provides an explanation for how mutations favor PI3Kα activation. A DNA-encoded library screen leveraging electron microscopy-optimized constructs, differential enrichment, and an orthosteric-blocking compound led to the identification of RLY-2608, a first-in-class allosteric mutant-selective inhibitor of PI3Kα. RLY-2608 inhibited tumor growth in PIK3CA-mutant xenograft models with minimal impact on insulin, a marker of dysregulated glucose homeostasis. RLY-2608 elicited objective tumor responses in two patients diagnosed with advanced hormone receptor–positive breast cancer with kinase or helical domain PIK3CA mutations, with no observed WT PI3Kα-related toxicities. Significance: Treatments for PIK3CA-mutant cancers are limited by toxicities associated with the inhibition of WT PI3Kα. Molecular dynamics, cryo-electron microscopy, and DNA-encoded libraries were used to develop RLY-2608, a first-in-class inhibitor that demonstrates mutant selectivity in patients. This marks the advance of clinical mutant-selective inhibition that overcomes limitations of orthosteric PI3Kα inhibitors. See related commentary by Gong and Vanhaesebroeck, p. 204 . See related article by Varkaris et al., p. 227 . This article is featured in Selected Articles from This Issue, p. 201

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