Abstract
As important effector cells in inflammation, macrophages can be functionally polarized into either inflammatory M1 or alternatively activated anti-inflammatory M2 phenotype depending on surroundings. The key roles of glycolysis in M1 macrophage polarization have been well defined. However, the relationship between glycolysis and M2 polarized macrophages is still poorly understood. Here, we report that 2-deoxy-d-glucose (2-DG), an inhibitor of the glycolytic pathway, markedly inhibited the expressions of Arg, Ym-1, Fizz1, and CD206 molecules, the hall-markers for M2 macrophages, during macrophages were stimulated with interleukin 4. The impacted M2 macrophage polarization by 2-DG is not due to cell death but caused by the impaired cellular glycolysis. Molecular mechanism studies indicate that the effect of 2-DG on M2 polarized macrophages relies on AMPK-Hif-1α-dependent pathways. Importantly, 2-DG treatment significantly decreases anti-inflammatory M2 macrophage polarization and prevents disease progression in a series of mouse models with chitin administration, tumor, and allergic airway inflammation. Thus, the identification of the master role of glycolysis in M2 macrophage polarization offers potential molecular targets for M2 macrophages-mediated diseases. 2-DG therapy may have beneficial effects in patients with tumors or allergic airway inflammation by its negative regulation on M2 macrophage polarization.
Highlights
Macrophages are critical for host immunity and can display different activation states depending on the surrounding contexts [1, 2]
How glycolytic activity is regulated in M2 macrophage polarization was poorly understood
The glycolytic uptake of M2 macrophages was measured by the generation of 3H-labeled glucose from [3-3H]-2-DG
Summary
Macrophages are critical for host immunity and can display different activation states depending on the surrounding contexts [1, 2]. M1 macrophages are inflammatory and can serve a positive role in immunity to microbial pathogens and tumors. M2 macrophages promote tissue repair and metabolic homeostasis and serve key roles in immunity to parasitic helminthes [5]. M1 macrophages greatly rely on aerobic glycolysis, whereas M2 macrophages mainly utilize fatty acid oxidation (FAO; β-oxidation) to fuel mitochondrial oxidative phosphorylation [9]. These studies have provided compelling evidence that macrophage polarization can be regulated by the different aspects of cellular metabolism
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