Abstract Background: 41.9% of adult US population is obese and every 5-unit BMI increase is associated with 12 percent increase in breast cancer risk; it is an independent predictor of poor outcomes in breast cancer. Microbiome has emerged as a central regulator of obesity and we recently discovered that microbes can not only potentiate breast cancer growth and metastasis but also affect therapeutic response. We showed weight-loss by Diet/Exercise/Behavioral intervention (POWER-remote trial) exerts favorable effects. Here, we examine molecular underpinnings of poor therapy response in obese state and explore the gut microbiome to mitigate the same. Methods: We co-implanted lineage determined human White preAdipocytes (hWAT) with MCF7 breast cancer cells in the mammary glands of mice. Changes in tumor microenvironment and tumor cells were evaluated ex situ by RNA sequencing, flow cytometry, Raman spectroscopy, Quantitative phase microscopy, PCR, immunoblotting and functional assays. To inspect the gut microbiome, 16 obese breast cancer patients were subjected to weight loss intervention over 14 weeks. Gut microbiome was analyzed at baseline and post-intervention by microbial shotgun sequencing. Patients were divided into responders and non-responders based on % weight-loss. Results: We found that human breast cancer cells co-implanted with hWAT formed more aggressive tumors compared to controls. RNA sequencing revealed significant upregulation of multiple oncogenic pathways along with robust innate immune response. Tumor dissociated cells from hWAT-MCF7 tumors showed extensive molecular reprogramming rendering them more proliferative, motile and stem-like along with dramatic physiological changes like increased intercellular lipid accumulation. hWAT-MCF7 cells attained resistance to multiple drugs including Tamoxifen, Fulvestrant, Letrozole and Palbociclib. Simultaneous targeting of multiple signaling pathways using pharmacological inhibitors is infeasible in clinical setting hence we explored the obesity-microbiome axis. Obese breast cancer patients underwent POWER-remote intervention and their gut microbiome analysis showed significant differential expression of many microbes. Based on abundance and metabolite profile, F. prausnitzii was selected as the candidate of interest. On treatment with F. prausnitzii growth media, acquired multi-drug resistance in hWAT-MCF7 cells could be reversed suggesting that increase in gut population of the bacterium could be helpful in sensitizing patients unresponsive to therapy. Conclusion: Direct interaction between breast cancer cells and WAT rendered them resistant to multiple drugs. Metabolites produced by weight-loss-associated bacterium F. prausnitzii reversed adiposity-induced multi-drug resistance, hence, can potentially have therapeutic benefits in obese breast cancer patients. Citation Format: Sheetal Parida, Sumit Siddharth, Nethaji Muniraj, Zhenhui Liu, Ishan Barman, Michael Smith, Jenni Sheng, Vered Stearns, Janelle W. Coughlin, Dipali Sharma. Weight loss intervention triggered gut microbiota modulation can positively impact obesity associated endocrine therapy resistance [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 5916.
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