Abstract 308: Low molecular weight cyclin E deregulates DNA replication and damage repair to promote genomic instability in breast cancer

Abstract

Abstract Background: Low molecular weight cyclin E (LMW-E) are oncogenic forms of cyclin E that are post translationally generated from the full-length cyclin E1 (FL-cycE). LMW-E is detected in breast cancer cells and tumor tissues, but not in normal mammary epithelial cells or adjacent normal tissues. Unlike FL-cycE, LMW-E drives mammary epithelial cell transformation in human cells and spontaneous mammary tumor formation in transgenic mouse models, but the oncogenic mechanisms of LMW-E and its unique function(s) independent of FL-cycE are not fully understood. It is currently assumed that LMW-E drives the tumorigenic process by promoting G1/S cell cycle transition and accelerating mitotic exit. Biochemical features such as longer protein half-life, higher affinity to its kinase partner CDK2, and resistance to endogenous CDK inhibitors such as p21 and p27 all promote the tumorigenic ability of LMW-E. Clinical studies in breast cancer reveal that overexpression of LMW-E predicts recurrence and poor survival in breast cancer patients independent of molecular subtype, Ki67 status, nodal status, or tumor grade, suggesting LMW-E may drive breast cancer development independent of its role in cell proliferation. In the current study, we tested the hypothesis that LMW-E promotes genomic instability by deregulating DNA replication and damage repair. Results: We generated immortalized pre-cancerous human mammary epithelial cells (hMECs) to express doxycycline inducible LMW-E or FL-cycE in CCNE1 knock-out background. We found that FL-cycE overexpression led to DNA replication stress and DNA damage accumulation, resulting in reduced cell viability. LMW-E overexpression, on the other hand, promoted cell survival under replication stress, resulting in persistent genomic instability. RNA-sequencing results showed LMW-E but not FL-cycE overexpression enhanced DNA replication and damage repair pathways. Molecularly, LMW-E interacted with and facilitated pre-replication complex assembly. LMW-E also mediated DNA repair by upregulating RAD51 and C17orf53, showing a dominant repairing effect over DNA damage induced by FL-cycE. Moreover, targeting the replication stress response pathway ATR-CHK1-RAD51 with small molecule inhibitors significantly decreased viability of LMW-E overexpressing hMECs and breast cancer cells. Lastly, we showed that positive LMW-E status was associated with genomic instability in tumors from a cohort of 725 patients diagnosed with early-stage breast cancer, further supporting our hypothesis that LMW-E promotes genomic instability to fuel breast cancer development. Conclusions: Collectively, our findings delineated a novel role for LMW-E in breast tumorigenesis mediated by replication stress tolerance and genomic instability, providing novel therapeutic strategies for LMW-E overexpressing breast cancers. Citation Format: Mi Li, Spiridon Tsavachidis, Fuchenchu Wang, Tuyen Bui, Tuyen D. Nguyen, Linjie Luo, Asha S. Multani, Melissa L. Bondy, Kelly K. Hunt, Khandan Keyomarsi. Low molecular weight cyclin E deregulates DNA replication and damage repair to promote genomic instability in breast cancer [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 308.