Abstract
Abstract Despite an enhanced interest, the origin of cancer stem cells (CSCs) remains equivocal. A strong body of evidence suggests that, in some adult carcinomas, CSC may originate from normal mature differentiated cells through a dedifferentiation process and the acquisition of stem-like properties. At the crux of this concept is the epithelial-mesenchymal transition (EMT), an embryonic transdifferentiation process that can be abnormally reactivated over the course of tumor development as a result of oncogenic or microenvironmental cues. High expression of EMT genes and stemness features are hallmarks of claudin-low (CL) breast cancers, a rare subtype of breast malignancies, generally considered as the most primitive breast cancers. We have recently reported that this molecular subtype of breast cancers exhibits a significant diversity, comprising three main subgroups (CL1, CL2 and CL3), that emerge from unique evolutionary processes. Genetic and epigenetic analyses support the hypothesis that CL1 tumors generate from the transformation of a normal mammary stem cells, whereas CL2 and CL3 arise from the reactivation of an EMT process over the course of tumor progression. Interestingly, CL tumors share the frequent activation of the RAS-MAPK pathway, suggesting a potent role for the RAS pathway in the development of CL tumors. Based on these findings, we wondered whether RAS pathway activation could induce the reactivation of EMT-TFs allowing the emergence of CSCs displaying CL2 and CL3 characteristics. By expressing an oncogenic form of RAS in differentiated epithelial cells (HME), we observed a phenotypic switch towards a CD24-/low/CD44+ phenotype, associated with CSC properties, and suggesting an acquisition of cellular plasticity after RAS activation. By using CRISPR/Cas9 knock-down experiments we have shown i) the emergence of CD24-/low/CD44+ cells, ii) the acquisition of transformation and stemness features, and iii) that the cellular plasticity acquired after RAS activation in differentiated HME strongly rely on ZEB1. Single-cell RNA sequencing analyses after RAS activation in HME-RAS cells suggested two different outcomes: senescence or EMT. Treatment with a senolytic drug resulted in reduction of RAS-induced senescent cells associated with a decrease in the emergence of CD24-/low/CD44+ cells and ZEB1 expression. Finally, a co-culture reporter system and a depletive approach with cytokine-neutralizing antibodies highlighted a paracrine effect of IL-6 and IL-1α, produced by senescent RAS-expressing cells on their neighboring differentiated cells, leading to the acquisition of ZEB1-dependent cellular plasticity. Hence, we unveiled a new paracrine process, in which cytokines secreted by cells undergoing oncogene-induced senescence drive ZEB1 expression, thus promoting cellular plasticity correlated with the emergence of CSCs. Citation Format: ALAIN PUISIEUX, Hadrien De Blander, Laurie Tonon, Frédérique Fauvet, Roxane Pommier, Christelle Lamblot, Rahma Benhassoun, Benjamin Gibert, Maria Ouzounova, Anne-Pierre Morel. RAS-induced transformation of mammary epithelial cells relies upon a ZEB1-dependent cellular reprogramming through a paracrine process [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr 2667.
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