| Literature DB >> 34986341 |
Pravat Kumar Parida1, Mauricio Marquez-Palencia1, Vidhya Nair1, Akash K Kaushik2, Kangsan Kim1, Jessica Sudderth3, Eduardo Quesada-Diaz4, Ambar Cajigas5, Vamsidhara Vemireddy6, Paula I Gonzalez-Ericsson7, Melinda E Sanders7, Bret C Mobley7, Kenneth Huffman8, Sunati Sahoo1, Prasanna Alluri9, Cheryl Lewis8, Yan Peng1, Robert M Bachoo6, Carlos L Arteaga6, Ariella B Hanker6, Ralph J DeBerardinis10, Srinivas Malladi11.
Abstract
HER2+ breast cancer patients are presented with either synchronous (S-BM), latent (Lat), or metachronous (M-BM) brain metastases. However, the basis for disparate metastatic fitness among disseminated tumor cells of similar oncotype within a distal organ remains unknown. Here, employing brain metastatic models, we show that metabolic diversity and plasticity within brain-tropic cells determine metastatic fitness. Lactate secreted by aggressive metastatic cells or lactate supplementation to mice bearing Lat cells limits innate immunosurveillance and triggers overt metastasis. Attenuating lactate metabolism in S-BM impedes metastasis, while M-BM adapt and survive as residual disease. In contrast to S-BM, Lat and M-BM survive in equilibrium with innate immunosurveillance, oxidize glutamine, and maintain cellular redox homeostasis through the anionic amino acid transporter xCT. Moreover, xCT expression is significantly higher in matched M-BM brain metastatic samples compared to primary tumors from HER2+ breast cancer patients. Inhibiting xCT function attenuates residual disease and recurrence in these preclinical models.Entities:
Keywords: HER2; breast cancer brain metastasis; immune surveillance; late recurrences; metabolism; metastasis; metastatic dormancy; metastatic latency; redox homeostasis; relapse
Mesh:
Year: 2022 PMID: 34986341 PMCID: PMC9307073 DOI: 10.1016/j.cmet.2021.12.001
Source DB: PubMed Journal: Cell Metab ISSN: 1550-4131 Impact factor: 31.373