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Macrophages are one of the most critical cells of the innate immune system M1-like. They are involved in clearing infectious diseases, phagocytosis, antigen presentation, and inflammation regulation2. Furthermore, macrophages are required to regulate other immune cells via various cytokines they release3. There is a big spectrum in macrophage phenotypes4. Depending on the signals that macrophages are exposed to, they polarize toward different inflammatory and metabolic states5. Macrophages manifest metabolic alterations in various diseases, depending on what tissue the macrophages reside6. Polarized macrophages have the capability to reprogram or switch their glycolytic metabolism, lipid metabolism, amino acid metabolism, and mitochondrial oxidative phosphorylation (OXPHOS)7,8. Classically activated M1-like macrophages and alternatively activated M2-like macrophages are the two most studied phenotypes of macrophages3. Non-activated quiescent macrophages are referred to as M0 macrophages. Polarization of M0 macrophages towards an M1-like phenotype can be induced by stimulation of naive BMDMs with bacterial lipopolysaccharide (LPS)9. The PI3K-AKT-mTOR-HIF1a signaling pathway can be activated in macrophages in the presence of inflammatory cytokines, interferon-gamma (IFN γ,) or tumor necrosis factor (TNF)10. M1-like macrophages have increased levels of glycolysis metabolism, decreased levels of oxidative phosphorylation (OXPHOS), producing inflammatory cytokines involved in infectious and inflammatory diseases8. On the other hand, polarization towards the M2-like phenotype can be induced by Interleukin (IL)-4, via the JAK-STAT, PPAR, and AMPK pathways, or by (IL)-13 and TGFβ pathays11,12.
In contrast to M1-like macrophages, M2-like macrophages have decreased glycolysis and increased OXPHOS and are involved in anti-parasitic and tissue repair activities8,13. BMDMs are a widely used system for the study of macrophages that are derived from bone marrow stem cells. Glycolysis and OXPHOS are the two leading energy production pathways in the cells14. Based on their microenvironment, BMDMs can choose to use either of these pathways; in some cases, switch from one to another, or use both pathways14. In this study, we focused on glycolysis metabolism in activated pro-inflammatory macrophages. When the glucose in the cytoplasm is converted to pyruvate and then lactate, the cells produce protons in the medium that cause an elevation in the acidification rate in the surrounded medium of M1-like cells5. An extracellular flux analyzer was used to measure the acidification rate of the cell media. Results are reported as Extracellular Acidification Rate (ECAR) or as Proton Efflux Rate.
An optimized quick and easy method to access glycolysis levels in polarized macrophages is essential to determine the glycolytic phenotype, metabolite changes, and the effects of inhibitors/activators and drugs on the polarized macrophages. The method described in this manuscript has been optimized to give information about specific glycolysis factors (Glycolysis, Glycolytic capacity, Glycolytic reserve, and Non-glycolytic acidification), as well as the metabolic reprogramming of glycolytic metabolism. The inhibitor (2DG) that has been used in this study explicitly targets the glycolysis pathway.
This optimized protocol has been modified and improved based on the combination of a published protocol16, extracellular flux analysis of glycolytic assays of manufacturer's user guides, and direct communication with manufacturer's R&D scientists.