Exploiting patient-derived xenografts and organoids to tackle apoptotic dependencies in EGFRinhibited colorectal tumours

Abstract Treatment with EGFR-targeted therapies, such as the EGFR monoclonal antibody cetuximab, has improved the outcome of patients with metastatic colorectal cancer (mCRC). However, EGFR inhibition is mainly cytostatic and does not lead to tumor eradication: subsets of drug-tolerant cancer cells often persist even after maximal response to therapy and foster residual disease, leading to relapse. Importantly, drug-tolerant cells are less prone to undergo apoptosis, and thus constitute a reservoir of treatment-refractory persisters that are difficult to extinguish. Here we aimed to investigate the mechanisms by which apoptosis escape mediates survival of cetuximab-tolerant mCRC cells as a means to find new therapeutic strategies for limiting residual disease and delaying disease recurrence. By performing an innovative functional assay named Dynamic BH3 Profiling in cetuximab-sensitive patient-derived organoids (PDOs), we found that antibody treatment increased the “apoptotic priming”, i.e. decreased the distance of cells from the apoptotic threshold without eliciting overt cell death. To start investigating the mechanisms of this increased apoptotic priming, protein levels of the major anti-apoptotic molecules (BCL2, BCL-XL, MCL1) and the pro-apoptotic molecule BIM were evaluated by Western blot in cetuximab-treated PDOs. BIM was consistently upregulated by cetuximab in all tested models. Increased BIM was sequestered by the anti-apoptotic BCL-XL, suggesting that EGFR blockade may render mCRC residual cells dependent on BCL-XL to elude cell death and, consequently, more susceptible to its inhibition. We therefore challenged a panel of 14 PDOs with different BH3 mimetics currently in preclinical or clinical development and found that only the combination of cetuximab with BH3 mimetics against BCL-XL strongly reduced cell viability and induced apoptosis. BCL-XL blockade enhanced cetuximab efficacy also in mCRC patient-derived xenografts, which displayed more durable tumor regression that was maintained also after treatment discontinuation. Notably, the combination of cetuximab with BCL-XL inhibitors was effective in vivo in all tested models except for one, which was characterized by low basal expression of BIM. Mechanistically, unleashed apoptosis by combination therapy was due to cetuximab-induced BIM upregulation concomitantly with its displacement from BCL-XL by the BH3 mimetic. Overall, this study offers new insights into the molecular mechanisms assisting residual disease after cetuximab treatment in mCRC, providing hints to design rational strategies that may convert the cytostatic effect of cetuximab into a cytotoxic, fully apoptotic outcome. Basal expression of BIM could be exploited as a predictive biomarker to enrich for potential responders to the combination of cetuximab and BH3 mimetics. Citation Format: Simonetta Maria Leto, Irene Catalano, Martina Ferri, Valentina Vurchio, Francesca Cottino, Eugenia Rosalinda Zanella, Francesco Sassi, Giorgia Migliardi, Andrea Bertotti, Livio Trusolino. Exploiting patient-derived xenografts and organoids to tackle apoptotic dependencies in EGFR-inhibited colorectal tumours [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 3697.