2026-04-17T06:06:52Zhttps://recercat.cat/oai/requestoai:recercat.cat:2445/2082552025-12-04T19:31:10Zcom_2072_1057col_2072_478908col_2072_478917col_2072_478933
RECERCAT
author
Barbosa, Bárbara M. G.
author
Sfyaki, Aikaterini
author
Rafael, Sergi
author
José-Duran, Ferran
author
Pous, Joan
author
Sánchez Zarzalejo, Carolina
author
Perez-Lopez, Carles
author
Vilanova, Mar
author
Cigler, Marko
author
Gay i Marín, Marina
author
Vilaseca Casas, Marta
author
Winter, Georg E.
author
Riera i Escalé, Antoni
author
Mayor-Ruiz, Cristina
2024-03-01T13:32:00Z2024-12-27T06:10:09Z2023-12-282024-03-01T13:32:00Z
Degraders hold the promise to efficiently inactivate previously intractable disease-relevant targets. Unlike traditional inhibitors, degraders act substoichiometrically and rely on the hijacked proteolysis machinery, which can also act as an entry point for resistance. To fully harness the potential of targeted protein degradation, it is crucial to comprehend resistance mechanisms and formulate effective strategies to overcome them. We conducted a chemical screening to identify synthetic lethal vulnerabilities of cancer cells that exhibit widespread resistance to degraders. Comparative profiling followed by tailored optimization delivered the small molecule RBS-10, which shows preferential cytotoxicity against cells pan-resistant to degraders. Multiomics deconvolution of the mechanism of action revealed that RBS-10 acts as a prodrug bioactivated by the oxidoreductase enzyme NQO1, which is highly overexpressed in our resistance models. Collectively, our work informs on NQO1 as an actionable vulnerability to overcome resistance to degraders and as a biomarker to selectively exploit bioactivatable prodrugs in cancer.
(c) Wiley-VCH, 2023 info:eu-repo/semantics/openAccess
Proteïnes
Cèl·lules canceroses
Proteins
Cancer cells
Discovery and Mechanistic Elucidation of NQO1-Bioactivatable Small Molecules That Overcome Resistance to Degraders.
info:eu-repo/semantics/article info:eu-repo/semantics/acceptedVersion