Therapy resistance remains a major barrier to improving outcomes in HER2-positive breast cancer, with dormant tumor cells (DTCs) and cancer stem cells (CSCs) playing critical roles in recurrence and treatment failure. Herein, we investigated the interplay between dormancy and CSCs features in HER2-amplified breast cancer cell models and evaluated the role of the JAK1-STAT3 axis in sustaining these therapy-resistant phenotypes. Using an in vitro dormancy model induced by HER2 inhibition, we observed a reversible quiescent state characterized by decreased proliferation and viability, accompanied by a significant increase in the CSC marker CD44. CD44 expression was rapidly induced following HER2 inhibition, preceding measurable effects on cell viability, and persisted throughout the dormancy phase. CD44-positive populations showed reduced sensitivity to HER2 inhibition and displayed robust proliferative recovery upon therapy withdrawal. Functional studies revealed that the inhibition of JAK1, but not STAT3, impaired the recovery of CD44-positive populations and decreased their proliferative capacity, suggesting a critical role for JAK1 in maintaining the CSC phenotype during therapy. These findings underscore the importance of CD44 as a marker and mediator of therapy resistance and suggest that targeting CD44-positive cells or the JAK1 signaling axis could improve the efficacy of HER2-targeted therapies. Our study provides novel insights into the mechanisms underlying dormancy and CSC induction in HER2-positive breast cancer and highlights potential strategies to mitigate therapy resistance and prevent disease recurrence.
Keywords: CD44; JAK-STAT signaling; breast cancer; cancer stem-cells; genome-editing; tumor dormancy; tumor recurrence.