Project description:Mitochondrial metabolism plays a crucial role in determining the functional polarization of macrophages, yet how mitochondrial signaling differentially regulates the induction of pro- and anti-inflammatory macrophages remains incompletely understood. Phosphoglycerate mutase 5 (PGAM5), a mitochondrial outer membrane phosphatase, has been implicated in promoting pro-inflammatory macrophage responses through a Dynamin-related protein 1(DRP1)-dependent metabolic reprogramming. This study identifies a distinct role for PGAM5 as a negative regulator of anti-inflammatory macrophage responses. Knockdown of PGAM5 markedly enhanced IL-4-induced expression of anti-inflammatory cytokines and M2 marker genes, including Il10, Tgfb, Arg1, Fizz1, and Ym1, as well as surface markers CD163 and CD206. PGAM5 knockdown also augmented mitochondrial oxidative metabolism and increased the expression of fatty acid oxidation/oxidative phosphorylation genes. Mechanistically, PGAM5 selectively regulated IL-4-induced phosphorylation of JAK1 without affecting STAT6 activation, as JAK1 phosphorylation was enhanced in PGAM5 KD macrophages. However, DRP1 was indispensable in IL-4-mediated induction of anti-inflammatory responses and mitochondrial respiration, indicating that PGAM5 negatively regulates anti-inflammatory macrophage polarization through DRP1-independent pathway. Collectively, these findings establish PGAM5 as a central regulator that oppositely controls macrophage polarization, highlighting its potential as a therapeutic strategy to modulate macrophage-driven inflammation and resolution.

Project description:Adverse cardiac remodeling after myocardial infarction (MI) causes structural and functional changes in the heart leading to heart failure. The initial pro-inflammatory response followed by an anti-inflammatory or reparative response post-MI is essential for minimizing the myocardial damage, healing, and scar formation. Bone marrow-derived macrophages (BMDMs) are recruited to the injured myocardium and essential for cardiac repair as they can adopt both pro-inflammatory (M1) or anti-inflammatory/reparative (M2) phenotypes to modulate inflammatory and reparative response, respectively. YAP and TAZ are the key mediators of the Hippo signaling pathway and essential for cardiac regeneration and repair. However, their role in macrophage polarization and post-MI inflammation, remodeling, and healing are not well established. Here, we demonstrate that expression of YAP and TAZ is increased in macrophages undergoing M1 or M2 polarization. Genetic deletion of YAP/TAZ leads to impaired M1 polarization and enhanced M2 polarization. Consistently, YAP activation/overexpression enhanced M1 and impaired M2 polarization. We show that YAP/TAZ promote M1 polarization by increasing IL6 expression, and impede M2 polarization by decreasing Arg1 expression through interaction with the HDAC3-NCoR1 repressor complex. These changes in macrophages polarization due to YAP/TAZ deletion results in reduced fibrosis, and hypertrophy and increased angiogenesis, leading to improved cardiac function after MI. Also, YAP activation augmented MI-induced cardiac fibrosis and remodeling. In summary, we identify YAP/TAZ as important regulators of macrophage-mediated pro- and anti-inflammatory responses post-MI.

Project description:Macrophage-mediated inflammation has been implicated in the pathogenesis of liver fibrosis. Metabolic reprogramming involves in the transition of macrophages from a pro-inflammatory M1-phenotype toward an anti-inflammatory M2-phenotype. S100A9 is highly expressed in activated macrophages and promotes M1 polarization, however, it is unknown whether S100A9 alters the polarization state of macrophages by regulating metabolism. This study revealed enhanced oxidative phosphorylation (OXPHOS) in S100a9-deficient macrophages based on mitochondrial proteomics, characterized by increased mitochondrial fusion and elevated ATP production.

Project description:In the treatment of inflammatory diseases, TPPU has shown potential therapeutic effects on a variety of inflammatory conditions, including reshaping the body's pro-inflammatory/anti-inflammatory balance by stabilizing endogenous anti-inflammatory substances EETs. In cardiovascular diseases, TPPU can regulate the NF-κB signaling pathway to modulate macrophage polarization and reduce inflammation. To explore the mechanism of TPPU in regulating M1 macrophages in TMJOA, we treated M1 macrophages with TPPU. In short, we attempted to verify the key signaling molecules and pathways regulated by TPPU in M1 macrophages.

Project description:Activation of immune cells is accompanied by a metabolic reconfiguration of their cellular energy metabolism including shifts in glycolysis and mitochondrial respiration that critically regulate functional effector responses. However, while current mass spectrometry strategies identify overall or flux-dependent metabolite profiles of cells or tissues, they fail to comprehensively identify the checkpoint nodes and enzymes that are responsible for different metabolic outputs. Here, we demonstrate that a data-driven inverse modelling approach from mass spectrometry metabolomics data can be used to identify a causal biochemical node that influence overall metabolic profiles and reactions. In our study we applied this strategy to TSC2/mTORC1-dependent macrophage polarization. Using multiomics metabolomics, proteomics and transcriptomics analysis as well as enzymatic activity measurements we demonstrate that TSC2, a negative regulator of mTORC1 signaling, critically influences the cellular metabolism of macrophages by regulating the enzyme phosphoglycerate dehydrogenase (PHGDH), a rate-limiting enzyme that diverts carbon from glycolysis for de novo serine/glycine biosynthesis. This is the first evidence that the metabolic kinase mTORC1 positively regulates PHGDH activity in macrophages. Importantly, PHGDH itself is a central regulator of macrophage polarization. Anti-inflammatory (M2) macrophages have high PHGDH activity that is required for the expression of typical anti-inflammatory molecules. Inhibition of PHGDH activity suppressed marker genes in IL-4 stimulated M2 macrophages. This identifies PHGDH as a metabolic signature of M2 macrophages. The presented concept of data-driven inverse modelling and multiomics analysis allows for the systematic integration of genome-scale metabolic reconstruction, prediction and analysis of causal biochemical regulation.

Project description:Corticotomy is a clinical procedure targeting alveolar bone to activate regional acceleratory phenomenon (RAP) and promote orthodontic tooth movement (OTM). Corticotomy involves the orchestration of inflammation by macrophages, but the underlying mechanism remains unclear. Here, we identify endoplasmic reticulum (ER) stress sensor activating transcription factor 6 (ATF6) as a critical player modulating pro- and anti-inflammatory macrophage polarization. We show that macrophage-specific ATF6 deletion blocks corticotomy-induced OTM acceleration, while macrophage ATF6 overexpression exaggerates the acceleration effect. Furthermore, the proportion of pro-inflammatory macrophages is positively correlated with ATF6 expression in vitro and in vivo. By RNA-seq and CUT&Tag, we demonstrate that ATF6 interacts with Tnfα promotor and augments its transcription, thereby mediating the effect of TNF signaling pathway in pro-inflammatory macrophage polarization. In summary, ATF6 may aggravate alveolar bone remodeling during corticotomy by promoting Tnfα transcription in macrophages, suggesting that ATF6 may represent a promising therapeutic target for non-invasive accelerating orthodontics.

Project description:Corticotomy is a clinical procedure targeting alveolar bone to activate regional acceleratory phenomenon (RAP) and promote orthodontic tooth movement (OTM). Corticotomy involves the orchestration of inflammation by macrophages, but the underlying mechanism remains unclear. Here, we identify endoplasmic reticulum (ER) stress sensor activating transcription factor 6 (ATF6) as a critical player modulating pro- and anti-inflammatory macrophage polarization. We show that macrophage-specific ATF6 deletion blocks corticotomy-induced OTM acceleration, while macrophage ATF6 overexpression exaggerates the acceleration effect. Furthermore, the proportion of pro-inflammatory macrophages is positively correlated with ATF6 expression in vitro and in vivo. By RNA-seq and CUT&Tag, we demonstrate that ATF6 interacts with Tnfα promotor and augments its transcription, thereby mediating the effect of TNF signaling pathway in pro-inflammatory macrophage polarization. In summary, ATF6 may aggravate alveolar bone remodeling during corticotomy by promoting Tnfα transcription in macrophages, suggesting that ATF6 may represent a promising therapeutic target for non-invasive accelerating orthodontics.

Project description:SPARC is a member of matricellular protein, and emerging evidence suggests that it plays a critical role in integrated metabolic and inflammatory responses. However, the mechanism how SPARC activates inflammation is still unanswered. Here we showed that excess SPARC induced sterile inflammation, and converted anti-inflammatory macrophage to pro-inflammatory macrophage. RNA-sequencing analysis revealed that SPARC elicits interferon-stimulated genes (ISGs) by transcription factor IRF7. SPARC also dampened mitochondrial respiration that induced pro-glycolytic inflammatory macrophage. Altogether, we discovered a mechanism how SPARC triggers sterile inflammatory response in anti-inflammatory macrophage, and this implicates the potential role of SPARC as a modulator of anti-inflammatory macrophages to maintain tissue homeostasis.

Project description:<p>Macrophages are prominent immune cells in the tumor microenvironment that can be educated into pro-tumoral phenotype by tumor cells to favor tumor growth and metastasis. The mechanisms that mediate a mutualistic relationship between tumor cells and macrophages remain poorly characterized. Here, we have shown <em>in vitro</em> that different human and murine cancer cell lines release branched‐chain α‐ketoacids (BCKAs) into the extracellular milieu, which influence macrophage polarization in an monocarboxylate transporter 1 (MCT1)‐dependent manner. We found that α‐ketoisocaproate (KIC) and α‐keto‐β‐methylvalerate (KMV) induced a pro‐tumoral macrophage state, whereas α‐ketoisovalerate (KIV) exerted a pro‐inflammatory effect on macrophages. This process was further investigated by a combined metabolomics/proteomics platform. KMV and KIC altered macrophage tricarboxylic acid (TCA) cycle intermediates and increased polyamine metabolism. Proteomic and pathway analyses revealed that the three BCKAs, especially KMV, exhibited divergent effects on the inflammatory signal pathways, phagocytosis, apoptosis and redox balance. These findings uncover cancer‐derived BCKAs as novel determinants for macrophage polarization with potential to be selectively exploited for optimizing antitumor immune responses.</p>

Project description:Uploaded proteomics data provides a comprehensive snapshot of the protein expression profiles associated with macrophage polarization. In our study, the analysis focused on the conversion of M2 macrophages, which typically support tumor growth through immunosuppressive signals, into M1 macrophages known for their pro-inflammatory, tumoricidal activity. The data reveal a marked upregulation of key M1-associated proteins—such as those involved in NF-κB signaling and pro-inflammatory cytokine production—alongside a concurrent downregulation of M2-specific markers. This proteomic shift confirms the reprogramming of the macrophage phenotype and underscores the potential of targeting these molecular pathways as a novel anti-tumor strategy.