Gain Fat—Lose Metastasis: Converting Invasive Breast Cancer Cells into Adipocytes Inhibits Cancer Metastasis.
Dana Ishay-Ronen, Maren Diepenbruck, Ravi Kiran Reddy Kalathur, Nami Sugiyama, Stefanie Tiede, Robert Ivanek, Glenn Bantug, Marco Francesco Morini, Junrong Wang, Christoph Hess, Gerhard Christofori.
University Hospital Basel, University of Basel, Basel, Switzerland.
HIGHLIGHTS
EMT-derived breast cancer cells can differentiate into post-mitotic adipocytes
Adipogenesis disconnects cancer cells from an invasive and oncogenic phenotype
EMT/MET transcription factors and TGF-β signaling regulate cancer adipogenesis
Adipogenesis-inducing drug combinations repress metastasis in preclinical models
Cancer cell plasticity facilitates the development of therapy resistance and malignant progression. De-differentiation processes, such as an epithelial-mesenchymal transition (EMT), are known to enhance cellular plasticity. Here, we demonstrate that cancer cell plasticity can be exploited therapeutically by forcing the trans-differentiation of EMT-derived breast cancer cells into post-mitotic and functional adipocytes. Delineation of the molecular pathways underlying such trans-differentiation has motivated a combination therapy with MEK inhibitors and the anti-diabetic drug Rosiglitazone in various mouse models of murine and human breast cancer in vivo. This combination therapy provokes the conversion of invasive and disseminating cancer cells into post-mitotic adipocytes leading to the repression of primary tumor invasion and metastasis formation.
Cancer cell plasticity and EMT are dynamic and can occur during different steps of cancer metastasis. We demonstrate that cellular plasticity acquired by EMT can be exploited to trans-differentiate breast cancer cells into post-mitotic and functional adipocytes. Notably, adipogenic differentiation therapy with a combination of Rosiglitazone and an MEK inhibitor efficiently inhibits cancer cell invasion, dissemination, and metastasis formation in various preclinical mouse models of breast cancer. The results underscore the pivotal role of cancer cell plasticity in malignant tumor progression and reveal the therapeutic potential that lies in the targeting of cellular plasticity, for example by forcing post-mitotic adipogenesis.
