Ahmad A. Cluntun scite author profile

Reliance on glutamine has long been considered a hallmark of cancer cell metabolism. However, some recent studies have challenged this notion in vivo, prompting a need for further clarifications on the role of glutamine metabolism in cancer. We find that there is ample evidence of an essential role for glutamine in tumors and that a variety of factors, including tissue type, the underlying cancer genetics, the tumor microenvironment and other variables such as diet and host physiology collectively influence the role of glutamine in cancer. Thus the requirements for glutamine in cancer are overall highly heterogeneous. In this review, we discuss the implications both for basic science and for targeting glutamine metabolism in cancer therapy.

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Acetate Production from Glucose and Coupling to Mitochondrial Metabolism in Mammals

Liu

Cooper

Cluntun

et al. 2018

Cell

310

209

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SUMMARY Acetate is a major nutrient that supports acetyl-coenzyme A (Ac-CoA) metabolism and thus lipogenesis and protein acetylation. Its source however has been unclear. Here we report that pyruvate, the end product of glycolysis and key node in central carbon metabolism, quantitatively generates acetate in mammals. This phenomenon becomes more pronounced in contexts of nutritional excess such as during hyperactive glucose metabolism. Conversion of pyruvate to acetate occurs through two mechanisms: 1) coupling to reactive oxygen species (ROS), and 2) neomorphic enzyme activity from keto acid dehydrogenases that enable function as pyruvate decarboxylases. Further, we demonstrate that de novo acetate production sustains Ac-CoA pools and cell proliferation in limited metabolic environments such as during mitochondrial dysfunction or ATP citrate lyase (ACLY) deficiency. De novo acetate production occurs in mammals and is further coupled to mitochondrial metabolism providing possible regulatory mechanisms and links to pathophysiology.

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Quantitative determinants of aerobic glycolysis identify flux through the enzyme GAPDH as a limiting step

et al. 2014

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Aerobic glycolysis or the Warburg Effect (WE) is characterized by the increased metabolism of glucose to lactate. It remains unknown what quantitative changes to the activity of metabolism are necessary and sufficient for this phenotype. We developed a computational model of glycolysis and an integrated analysis using metabolic control analysis (MCA), metabolomics data, and statistical simulations. We identified and confirmed a novel mode of regulation specific to aerobic glycolysis where flux through GAPDH, the enzyme separating lower and upper glycolysis, is the rate-limiting step in the pathway and the levels of fructose (1,6) bisphosphate (FBP), are predictive of the rate and control points in glycolysis. Strikingly, negative flux control was found and confirmed for several steps thought to be rate-limiting in glycolysis. Together, these findings enumerate the biochemical determinants of the WE and suggest strategies for identifying the contexts in which agents that target glycolysis might be most effective.DOI: http://dx.doi.org/10.7554/eLife.03342.001

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The pyruvate-lactate axis modulates cardiac hypertrophy and heart failure

et al. 2021

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Ahmad A. Cluntun

Glutamine Metabolism in Cancer: Understanding the Heterogeneity

Acetate Production from Glucose and Coupling to Mitochondrial Metabolism in Mammals

Quantitative determinants of aerobic glycolysis identify flux through the enzyme GAPDH as a limiting step

The pyruvate-lactate axis modulates cardiac hypertrophy and heart failure

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