4.7 Article

The Warburg effect: persistence of stem-cell metabolism in cancers as a failure of differentiation

Journal

ANNALS OF ONCOLOGY
Volume 29, Issue 1, Pages 264-270

Publisher

OXFORD UNIV PRESS
DOI: 10.1093/annonc/mdx645

Keywords

FDG-PET standardized uptake values; stem cell; metabolism; epithelial malignancies; bimodal distributions

Categories

Funding

  1. NCI Cancer Center Support Grant (CCSG) [P30 CA08748]
  2. Cycle for Survival
  3. Marie-Josee and Henry R. Kravis Center for Molecular Oncology
  4. Dana-Faber Cancer Institute Physical Sciences Oncology Center [U54CA193461]
  5. NATIONAL CANCER INSTITUTE [U54CA193461, P30CA008748] Funding Source: NIH RePORTER

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Background: Two recent observations regarding the Warburg effect are that (i) the metabolism of stem cells is constitutive ( aerobic) glycolysis while normal cellular differentiation involves a transition to oxidative phosphorylation and (ii) the degree of glucose uptake of a malignancy as imaged by 18F-fluorodeoxyglucose positron emission tomography (FDG-PET) is associated with histologic measures of tumor differentiation. Combining these observations, we hypothesized that the high levels of glucose uptake observed in poorly differentiated cancers may reflect persistence of the glycolytic metabolism of stem cells in malignant cells that fail to fully differentiate. Patients and methods: Tumor glucose uptake was measured by FDG-PET in 552 patients with histologically diverse cancers. We used normal mixture modeling to explore FDG-PET standardized uptake value (SUV) distributions and tested for associations between glucose uptake and histological differentiation, risk of lymph node metastasis, and survival. Using RNA-seq data, we carried out pathway and transcription factor analyses to compare tumors with high and low levels of glucose uptake. Results: We found that well-differentiated tumors had low FDG uptake, while moderately and poorly differentiated tumors had higher uptake. The distribution of SUV for each histology was bimodal, with a low peak around SUV 2-5 and a high peak at SUV 8-14. The cancers in the two modes were clinically distinct in terms of the risk of nodal metastases and death. Carbohydrate metabolism and the pentose-related pathway were elevated in the poorly differentiated/high SUV clusters. Embryonic stem cell-related signatures were activated in poorly differentiated/high SUV clusters. Conclusions: Our findings support the hypothesis that the biological basis for the Warburg effect is a persistence of stem cell metabolism (i.e. aerobic glycolysis) in cancers as a failure to transition from glycolysis-utilizing undifferentiated cells to oxidative phosphorylation-utilizing differentiated cells. We found that cancers cluster along the differentiation pathway into two groups, utilizing either glycolysis or oxidative phosphorylation. Our results have implications for multiple areas of clinical oncology.

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