Abstract
Abstract Lynch syndrome (LS) is an inherited predisposition for developing cancer caused by germline variants in mismatch repair (MMR) genes. It is estimated that LS is responsible for 1 out of every 35 colorectal cancers and 1 out of every 56 endometrial cancers. Loss of MMR is also seen in many sporadic cancers. Still, the mechanism of tumorigenesis in these patients is unknown. Loss of MMR increases genomic mutation rate, but it is unclear if increased mutational burden alone leads to tumorigenesis. Recent studies of LS patient colon samples show fields of morphologically normal tissue in which cells have lost expression of an MMR protein, suggesting that loss of MMR in these cells is sufficient to confer an advantage over heterozygous cells still proficient in MMR. However, whether MMR loss provides a direct advantage to cell types associated with cancer in LS has not been directly tested. We hypothesize that loss of MMR is sufficient to confer a selective advantage to colonic stem cells and is the first step towards tumorigenesis in LS patients. To test this, we use a human colonic organoid model to examine competition between MMR-deficient (dMMR) and MMR-proficient (pMMR) cells over time. The colonic organoids are differentiated from human embryonic stem cells. To track cell populations, dMMR stem cells are labeled with mCherry and pMMR stem cells are labeled with GFP. We have initially observed that dMMR stem cells are much more efficient at generating colonic organoids. Thus, the cells are mixed so that resulting organoids initially contain a small population of dMMR cells in order to mimic the spontaneous loss of heterozygosity that occurs in LS patients’ colonic crypts. Live fluorescent imaging of individual organoids is used to quantify changes in cell population over time. Preliminary data indicate that dMMR cells can outgrow pMMR cells resulting in a shift in the ratio of green to red cells over a two-week time period. These results suggest that loss of MMR function imparts an immediate selective advantage. Furthermore, this assay could be used to find conditions or compounds that decelerate population shifts with the ultimate goal of finding a way to reduce dMMR fields in LS patients. In these ways, this assay can be leveraged for gaining new insights into MMR function, pathogenesis of LS, and potential therapies for LS. Citation Format: Caroline Guild, Kirby Madden-Hennessey, Chris Heinen. An organoid model for understanding the pathogenesis of Lynch syndrome [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 149.
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