Cancer stem cells (CSCs) are a subpopulation of cancer cells that are responsible for disease recurrence and chemoresistance. The mechanisms by which CSCs arise in endometrial cancer are not fully understood and elucidating key molecular events may provide insight into therapeutic targets. CD73, a cell surface 5’nucleotidase that generates adenosine, is frequently downregulated in endometrial tumorigenesis, and CD73 loss is associated with aggressive disease and poor patient outcomes. In developing and characterizing CRISPR/Cas-9 models for CD73, we discovered CD73 deletion (CD73−/−) in HEC-1-A cells causes growth arrest and prolonged survival which are features suggestive of a stemness phenotype. Thus, we hypothesized that loss of CD73 is critical for promoting CSCs in endometrial cancer. To evaluate CSC characteristics, we performed MTT and spheroid assays and interrogated CSC marker protein expression (e.g., CD44 and NOTCH3). CD73−/− HEC-1-A cells formed larger spheroids and expressed high levels of CD44 and NOTCH3 compared to wild-type (CD73+/+) cells. To assess whether loss of CD73 enzymatic activity is responsible for the enrichment of CSCs, CD73+/+ HEC-1-B and HEC-50 cells were treated with AoPCP, a catalytic inhibitor of CD73. Similar to genetic deletion of CD73 in HEC-1-A cells, AoPCP treatment resulted in HEC-1-B and HEC-50 cells forming larger spheroids and expressing high CD44 and NOTCH3. These data indicate that loss of CD73 enzyme activity is important to the enrichment of CSCs. In contrast, HEYA8 ovarian cancer cells showed the opposite effects, wherein treatment with AoPCP decreased spheroid size. These differences support the emerging paradigm that CD73 has tissue- and cancer-specific roles. As CD73 is a major node in purine metabolic signaling, we further hypothesized that loss of CD73 activity may be promoting CSC enrichment via changes to metabolic pathways. Mass spectrometry metabolomics revealed significantly different profiles of CD73+/+ and CD73−/− HEC-1-A cells. Conditioned media experiments showed CD73−/−-conditioned media induces growth arrest in HEC-1-A wild-type cells, whereas the growth arrest and CSC marker expression enrichment of CD73−/− cells was abrogated by CD73+/+-conditioned media or daily media replenishment. Metabolomic profiling of CD73+/+ and CD73−/− HEC-1-A cells with/without daily media replenishment revealed metabolic pathways, such as NAD+ biosynthesis, lipid metabolism, and sugar alcohol synthesis, are up-regulated by CD73 deficiency and parallels the enrichment of CSCs. Current studies are dissecting these metabolic dependencies in supporting endometrial cancer cell stemness. Altogether, these studies provide novel insight into how CSCs arise in endometrial cancer and why CD73 loss is detrimental in this disease.

Citation Format: Emily M. Rabjohns, Blake R. Rushing, Sayali Joseph, Cyrus Vaziri, Jessica L. Bowser. Evidence for CD73 loss promoting cancer cell stemness via metabolic reprogramming in endometrial cancer [abstract]. In: Proceedings of the AACR Special Conference on Endometrial Cancer: Transforming Care through Science; 2023 Nov 16-18; Boston, Massachusetts. Philadelphia (PA): AACR; Clin Cancer Res 2024;30(5_Suppl):Abstract nr B035.