Nicole A. Traphagen scite author profile

Purpose: Despite adjuvant endocrine therapy for patients with estrogen receptor alpha (ER)-positive breast cancer, dormant residual disease can persist for years and eventually cause tumor recurrence. We sought to deduce mechanisms underlying the persistence of dormant cancer cells to identify therapeutic strategies. Experimental Design: Mimicking the aromatase inhibitor-induced depletion of estrogen levels used to treat patients, we developed preclinical models of dormancy in ER+ breast cancer induced by estrogen withdrawal in mice. We analyzed tumor xenografts and cultured cancer cells for molecular and cellular responses to estrogen withdrawal and drug treatments. Publicly available clinical breast tumor gene expression datasets were analyzed for responses to neoadjuvant endocrine therapy. Results: Dormant breast cancer cells exhibited upregulated 5' adenosine monophosphate-activated protein kinase (AMPK) levels and activity, and upregulated fatty acid oxidation. While the anti-diabetes AMPKactivating drug metformin slowed the estrogen-driven growth of cells and tumors, metformin promoted the persistence of estrogen-deprived cells and tumors through increased mitochondrial respiration driven by fatty acid oxidation. Pharmacologic or genetic inhibition of AMPK or fatty acid oxidation promoted clearance of dormant residual disease, while dietary fat increased tumor cell survival.Conclusions: AMPK has context-dependent effects in cancer, cautioning against the widespread use of an AMPK activator across disease settings. The development of therapeutics targeting fat metabolism is warranted in ER+ breast cancer.

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Tumor pharmacokinetics and pharmacodynamics of the CDK4/6 inhibitor ribociclib in patients with recurrent glioblastoma

Miller

Traphagen

Li³

et al. 2019

J Neurooncol

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Therapeutically targeting tumor microenvironment–mediated drug resistance in estrogen receptor–positive breast cancer

Shee

Yang

Hinds

et al. 2018

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Estrogen therapy induces an unfolded protein response to drive cell death in ER+ breast cancer

et al. 2019

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Estrogens have been shown to elicit anticancer effects against estrogen receptor α ( ER )‐positive breast cancer. We sought to determine the mechanism underlying the therapeutic response. Response to 17β‐estradiol was assessed in ER + breast cancer models with resistance to estrogen deprivation: WHIM 16 patient‐derived xenografts, C7‐2‐ HI and C4‐ HI murine mammary adenocarcinomas, and long‐term estrogen‐deprived MCF ‐7 cells. As another means to reactivate ER , the anti‐estrogen fulvestrant was withdrawn from fulvestrant‐resistant MCF ‐7 cells. Transcriptional, growth, apoptosis, and molecular alterations in response to ER reactivation were measured. 17β‐estradiol treatment and fulvestrant withdrawal induced transcriptional activation of ER , and cells adapted to estrogen deprivation or fulvestrant were hypersensitive to 17β‐estradiol. ER transcriptional response was followed by an unfolded protein response and apoptosis. Such apoptosis was dependent upon the unfolded protein response, p53, and JNK signaling. Anticancer effects were most pronounced in models exhibiting genomic amplification of the gene encoding ER ( ESR 1 ), suggesting that engagement of ER at high levels is cytotoxic. These data indicate that long‐term adaptation to estrogen deprivation or ER inhibition alters sensitivity to ER reactivation. In such adapted cells, 17β‐estradiol treatment and anti‐estrogen withdrawal hyperactivate ER , which drives an unfolded protein response and subsequent growth inhibition and apoptosis. 17β‐estradiol treatment should be considered as a therapeutic option for anti‐estrogen‐resistant disease, particularly in patients with tumors harboring ESR 1 amplification or ER overexpression. Furthermore, therapeutic strategies that enhance an unfolded protein response may increase the therapeutic effects of ER reactivation.

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Endocytosis of very low-density lipoproteins: an unexpected mechanism for lipid acquisition by breast cancer cells

Lupien

Bloch

Dehairs

et al. 2020

Journal of Lipid Research

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We previously described the expression of CD36 and LPL by breast cancer (BC) cells and tissues and the growth-promoting effect of VLDL observed only in the presence of LPL. We now report a model in which LPL is bound to a heparan sulfate proteoglycan motif on the BC cell surface and acts in concert with the VLDL receptor to internalize VLDLs via receptor-mediated endocytosis. We also demonstrate that gene-expression programs for lipid synthesis versus uptake respond robustly to triglyceride-rich lipoprotein availability. The literature emphasizes de novo FA synthesis and exogenous free FA uptake using CD36 as paramount mechanisms for lipid acquisition by cancer cells. We find that the uptake of intact lipoproteins is also an important mechanism for lipid acquisition and that the relative reliance on lipid synthesis versus uptake varies among BC cell lines and in response to VLDL availability. This metabolic plasticity has important implications for the development of therapies aimed at the lipid dependence of many types of cancer, in that the inhibition of FA synthesis may elicit compensatory upregulation of lipid uptake. Moreover, the mechanism that we have elucidated provides a direct connection between dietary fat and tumor biology..

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