Loss of p27Kip1 causes metabolic reprogramming and is sufficient to induce a Warburg effect and glutamine addiction in untransformed cells

The metabolic needs of a cell are tightly linked to its proliferative state and increasing evidence indicate an extensive bidirectional crosstalk between metabolic pathways and cell cycle regulators. In cancer cells, metabolism is reprogrammed to couple energetic needs and relentless proliferation. The cyclin/CDK inhibitor p27Kip1 (p27) is frequently inactivated in cancers. p27 is also involved in multiple cellular processes, including transcriptional regulation or autophagy induction. Herein, we investigated the effect of p27 loss on cell metabolism. The knockout of p27 in immortalized mouse fibroblasts increases glucose uptake and glycolysis, while decreasing mitochondrial ATP production, consistent with induction of a Warburg effect, and this was accompanied by an increased glutamine dependency to feed the TCA cycle. Our data suggest that p27 loss causes this phenotype through extensive transcriptional remodeling of metabolic gene expression. Importantly, p27 silencing in human retinal RPE1-hTERT cells was sufficient to induce a Warburg effect. Together, these results reveal a new function of p27 in regulating energy metabolism and that loss of p27 expression is sufficient to induce metabolic reprogramming and a Warburg effect, suggesting that p27 inactivation in cancer cells not only results in the loss of cell cycle inhibition but also enables the metabolic rewiring needed for increased proliferation.