Abstract
Tumor relapse from treatment‐resistant cells (minimal residual disease, MRD) underlies most breast cancer‐related deaths. Yet, the molecular characteristics defining their malignancy have largely remained elusive. Here, we integrated multi‐omics data from a tractable organoid system with a metabolic modeling approach to uncover the metabolic and regulatory idiosyncrasies of the MRD. We find that the resistant cells, despite their non‐proliferative phenotype and the absence of oncogenic signaling, feature increased glycolysis and activity of certain urea cycle enzyme reminiscent of the tumor. This metabolic distinctiveness was also evident in a mouse model and in transcriptomic data from patients following neo‐adjuvant therapy. We further identified a marked similarity in DNA methylation profiles between tumor and residual cells. Taken together, our data reveal a metabolic and epigenetic memory of the treatment‐resistant cells. We further demonstrate that the memorized elevated glycolysis in MRD is crucial for their survival and can be targeted using a small‐molecule inhibitor without impacting normal cells. The metabolic aberrances of MRD thus offer new therapeutic opportunities for post‐treatment care to prevent breast tumor recurrence.
Highlights
Tumor relapse from treatment-resistant cells underlies most breast cancer-related deaths
We started with polarized organoids lining a lumen (Fig 1A, referred to as “normal cells” ) that represent the healthy tissue (Jechlinger et al, 2009; Havas et al, 2017)
The normal and the tumor organoids did not appreciably change their appearance compared with the untreated condition (Fig 4B). These results show that residual cells are —as hypothesized above—more dependent on glycolysis than tumor cells at doses of 3-BP that do not affect normal cells
Summary
Tumor relapse from treatment-resistant cells (minimal residual disease, MRD) underlies most breast cancer-related deaths. We find that the resistant cells, despite their nonproliferative phenotype and the absence of oncogenic signaling, feature increased glycolysis and activity of certain urea cycle enzyme reminiscent of the tumor. This metabolic distinctiveness was evident in a mouse model and in transcriptomic data from patients following neo-adjuvant therapy. Our data reveal a metabolic and epigenetic memory of the treatment-resistant cells. The metabolic aberrances of MRD offer new therapeutic opportunities for post-treatment care to prevent breast tumor recurrence
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