Abstract The epithelial monolayer of the intestine is one of the fastest renewing tissues of the human body. Every week, the entire epithelium is replaced by intestinal stem cells (ISCs) that reside in crypt-like structures within the monolayer. Within these crypts, a small number of ISCs continuously divide to provide all specialized cell types necessary to maintain normal intestinal homeostasis, while simultaneously competing with each other for a position within the crypt bottom. This competition, characterized by neutral loss-and-replacement events, can be drastically disturbed when one of the ISCs acquires a mutation that confers a competitive advantage. As a result, mutant ISCs will replace all normal ISCs, colonize the intestinal crypt, and facilitate the initiation of colorectal cancer (CRC). CRC development is a stepwise process characterized by the accumulation of mutations in cancer driver genes over time. Almost 80% of all CRCs present with early mutations in the tumor suppressor gene APC, leading to constitutive activation of the Wnt pathway and the formation of pre-malignant adenomas. We have previously demonstrated that, within individual crypts, Apc-mutant ISCs have a competitive advantage over normal ISCs, although the mechanism underlying this unequal competition remained unclear. Recently, we revealed that Apc-mutant ISCs in fact act as "supercompetitors" by secreting Wnt antagonists such as NOTUM, WIF1 and DKK2, that actively disadvantage neighboring wild type ISCs by forcing them do differentiate. We demonstrated that boosting wild type fitness by downstream pharmacological activation of the Wnt signaling pathway by GSK3β-inhibitor lithium rendered wild type ISCs resistant to the Wnt antagonists, reduced the number of Apc-mutant crypts, and prevented adenoma formation. Together, this work highlights that modulating cell competition between normal and mutant cells within the crypt can provide a novel approach to prevent CRC development. Our findings are particularly relevant for familial adenomatous polyposis (FAP) patients, that carry germline mutations in APC and are predisposed to the development of CRC. Based on our fundamental discoveries, we are currently performing a clinical trial to assess the chemopreventive effect of lithium on the expansion of APC-mutant clones in FAP patients [ClinicalTrials.gov: NCT05402891]. Importantly, it is becoming increasingly evident that intestinal adenomas do not form from a single Apc-mutant crypt, but require fields of multiple mutant crypts to facilitate tumor initiation. Although field cancerization by enhanced crypt fission has been observed for several oncogenic mutants in the gut (e.g. KrasG12D, PIK3CAH1047R), Apc-mutant cells are often contained within individual crypts. This indicates that multiple independent mutant clones may act cooperatively to facilitate tumorigenesis, thereby pointing towards a polyclonal origin of intestinal adenomas. Our current work investigates how Apc-mutant clones interact by modifying their local environment through reciprocal signalling with stromal and epithelial cells to escape the anatomical constraints of the crypt, thereby unlocking their oncogenic potential in the gut. Ultimately, unravelling the molecular mechanisms underlying clonal cooperation will inform potential chemoprevention strategies for CRC. Citation Format: Sanne van Neerven. Cell competition vs cell cooperation: Unlocking oncogenic potential of mutant clones in the gut [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 2 (Late-Breaking, Clinical Trial, and Invited Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(7_Suppl):Abstract nr SY07-02.
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