Project description:Under conditions of erythrolytic stress, which accompanies many disease states, macrophages play key roles in phagocytosing damaged RBCs and preventing the toxic effects of cell-free hemoglobin and heme to maintain homeostasis. Using a genetic mouse model of spherocytosis and single-cell RNA sequencing, we show that erythrolytic stress promotes expansion of a specific macrophage population in the liver (which we named “erythrophagocytes”) expressing high levels of Marco and Hmox1 and low levels of MHC class II related genes with an anti-inflammatory gene expression signature. We confirmed the strong anti-inflammatory function of erythrophagocytes in two models of sterile inflammatory liver disease: anti-CD40 antibody-induced systemic inflammation syndrome with necrotizing hepatitis and diet-induced nonalcoholic fatty liver disease (NAFLD). The unique anti-inflammatory phenotype and function of erythrophagocytes was reproduced in vitro by heme-exposure of mouse macrophages, yielding a transcriptional profile that segregated heme-polarized from classical M1- and M2-polarized cells. The phenotype of anti-inflammatory erythrophagocytes coincided with NFE2L2/NRF2 driven gene expression and was abolished in Nfe2l2/Nrf2-deficient macrophages. Our findings point to a novel pathway that regulates macrophage functions to link RBC homeostasis and heme metabolism with innate immunity.

Project description:Under conditions of erythrolytic stress, which accompanies many disease states, macrophages play key roles in phagocytosing damaged RBCs and preventing the toxic effects of cell-free hemoglobin and heme to maintain homeostasis. Using a genetic mouse model of spherocytosis and single-cell RNA sequencing, we show that erythrolytic stress promotes expansion of a specific macrophage population in the liver (which we named “erythrophagocytes”) expressing high levels of Marco and Hmox1 and low levels of MHC class II related genes with an anti-inflammatory gene expression signature. We confirmed the strong anti-inflammatory function of erythrophagocytes in two models of sterile inflammatory liver disease: anti-CD40 antibody-induced systemic inflammation syndrome with necrotizing hepatitis and diet-induced nonalcoholic fatty liver disease (NAFLD). The unique anti-inflammatory phenotype and function of erythrophagocytes was reproduced in vitro by heme-exposure of mouse macrophages, yielding a transcriptional profile that segregated heme-polarized from classical M1- and M2-polarized cells. The phenotype of anti-inflammatory erythrophagocytes coincided with NFE2L2/NRF2 driven gene expression and was abolished in Nfe2l2/Nrf2-deficient macrophages. Our findings point to a novel pathway that regulates macrophage functions to link RBC homeostasis and heme metabolism with innate immunity.

Project description:Under conditions of erythrolytic stress, which accompanies many disease states, macrophages play key roles in phagocytosing damaged RBCs and preventing the toxic effects of cell-free hemoglobin and heme to maintain homeostasis. Using a genetic mouse model of spherocytosis and single-cell RNA sequencing, we show that erythrolytic stress promotes expansion of a specific macrophage population in the liver (which we named “erythrophagocytes”) expressing high levels of Marco and Hmox1 and low levels of MHC class II related genes with an anti-inflammatory gene expression signature. We confirmed the strong anti-inflammatory function of erythrophagocytes in two models of sterile inflammatory liver disease: anti-CD40 antibody-induced systemic inflammation syndrome with necrotizing hepatitis and diet-induced nonalcoholic fatty liver disease (NAFLD). The unique anti-inflammatory phenotype and function of erythrophagocytes was reproduced in vitro by heme-exposure of mouse macrophages, yielding a transcriptional profile that segregated heme-polarized from classical M1- and M2-polarized cells. The phenotype of anti-inflammatory erythrophagocytes coincided with NFE2L2/NRF2 driven gene expression and was abolished in Nfe2l2/Nrf2-deficient macrophages. Our findings point to a novel pathway that regulates macrophage functions to link RBC homeostasis and heme metabolism with innate immunity.

Project description:Under conditions of erythrolytic stress, which accompanies many disease states, macrophages play key roles in phagocytosing damaged RBCs and preventing the toxic effects of cell-free hemoglobin and heme to maintain homeostasis. Using a genetic mouse model of spherocytosis and single-cell RNA sequencing, we show that erythrolytic stress promotes expansion of a specific macrophage population in the liver (which we named “erythrophagocytes”) expressing high levels of Marco and Hmox1 and low levels of MHC class II related genes with an anti-inflammatory gene expression signature. We confirmed the strong anti-inflammatory function of erythrophagocytes in two models of sterile inflammatory liver disease: anti-CD40 antibody-induced systemic inflammation syndrome with necrotizing hepatitis and diet-induced nonalcoholic fatty liver disease (NAFLD). The unique anti-inflammatory phenotype and function of erythrophagocytes was reproduced in vitro by heme-exposure of mouse macrophages, yielding a transcriptional profile that segregated heme-polarized from classical M1- and M2-polarized cells. The phenotype of anti-inflammatory erythrophagocytes coincided with NFE2L2/NRF2 driven gene expression and was abolished in Nfe2l2/Nrf2-deficient macrophages. Our findings point to a novel pathway that regulates macrophage functions to link RBC homeostasis and heme metabolism with innate immunity.

Project description:Heme-activation of NRF2 is a strong anti-inflammatory signal in macrophages, and analyses in this study indicated that the expressed transcriptome in heme-TAMs was consistently enriched for NRF2 target genes. We have therefore delineated the role of NRF2 in a series of experiments with Nrf2 knockout BMDMs, leading to a locked NRF2-inactive state, and macrophages with a knockout of the cytoplasmic NRF2 capture protein KEAP1, leading to a locked NRF2-active state, irrespective of the presence or absence of heme. To demonstrate that activated NRF2 is sufficient to drive heme-TAM transformation, we analyzed Keap1 knockout macrophages.

Project description:Agonistic CD40 monoclonal antibodies have emerged as promising immunotherapeutic compounds with impressive anti-tumoral effects. However, one of the main limitations of their use in patients is the severe liver necro-hepatitis they can induce. Up to this point, no effective treatment for anti-CD40 liver toxicity that does not hinder anti-tumor efficacy has been found. In the present study , we show that anti-CD40 liver toxicity is dependent on liver macrophages and recruitment of monocytes and neutrophils. We specifically reprogrammed the phenotype of liver macrophages to anti-inflammatory erythrophagocytes by using repeated injection of anti-erythrocyte murine Ter119 (mTer119) antibody. mTer119 administration induced phagocytosis of erythrocytes by liver macrophages and their transformation to Hmoxhigh/Marcohigh/MHC-IIlow erythrophagocytes. mTer119 treatment prevented anti-CD40 induced liver toxic side-effect, with significantly reduced elevation of plasma transaminases level and area of liver necrosis on histology, while preserving the anti-tumoral efficiency of anti-CD40. Our study offers a novel targeted therapeutic approach to treat immune-related liver adverse side effects of immunotherapies.

Project description:Agonistic CD40 monoclonal antibodies have emerged as promising immunotherapeutic compounds with impressive anti-tumoral effects. However, one of the main limitations of their use in patients is the severe liver necro-hepatitis they can induce. Up to this point, no effective treatment for anti-CD40 liver toxicity that does not hinder anti-tumor efficacy has been found. In the present study , we show that anti-CD40 liver toxicity is dependent on liver macrophages and recruitment of monocytes and neutrophils. We specifically reprogrammed the phenotype of liver macrophages to anti-inflammatory erythrophagocytes by using repeated injection of anti-erythrocyte murine Ter119 (mTer119) antibody. mTer119 administration induced phagocytosis of erythrocytes by liver macrophages and their transformation to Hmoxhigh/Marcohigh/MHC-IIlow erythrophagocytes. mTer119 treatment prevented anti-CD40 induced liver toxic side-effect, with significantly reduced elevation of plasma transaminases level and area of liver necrosis on histology, while preserving the anti-tumoral efficiency of anti-CD40. Our study offers a novel targeted therapeutic approach to treat immune-related liver adverse side effects of immunotherapies.

Project description:Activation of inflammation is tightly associated with metabolic reprogramming in macrophages. The iron-containing tetrapyrrole heme can induce pro-oxidant and pro-inflammatory effects in murine macrophages, but has been associated with polarization towards an anti-inflammatory phenotype in human macrophages. In the current study, we compared the regulatory responses to heme and the prototypical Toll-like receptor (TLR)4 ligand lipopolysaccharide (LPS) in human and mouse macrophages with a particular focus on alterations of cellular bioenergetics. In human macrophages, bulk RNA-sequencing analysis indicated that heme led to an anti-inflammatory transcriptional profile, whereas LPS induced a classical pro-inflammatory gene response. Co-stimulation of heme with LPS caused opposing regulatory patterns of inflammatory activation and cellular bioenergetics in human and mouse macrophages. Specifically, in LPS-stimulated murine, but not human macrophages, heme led to a marked suppression of oxidative phosphorylation and an up-regulation of glycolysis. The species-specific alterations in cellular bioenergetics and inflammatory responses to heme were critically dependent on the availability of nitric oxide (NO) that is generated in inflammatory mouse, but not human macrophages. Accordingly, studies with an inducible nitric oxide synthase (iNOS) inhibitor in mouse, and a pharmacological NO donor in human macrophages, reveal that NO is responsible for the opposing effects of heme in these cells. Taken together, the current findings indicate that NO is critical for the immunomodulatory role of heme in macrophages.

Project description:ACOD1 is the enzyme repurposing cisaconitate from the tricarboxylic acid (TCA) cycle in the mitochondria to produce itaconate, a metabolite with anti-inflammatory and tolerogenic functions. In particular, itaconate accumulation in macrophages is known to oppose pro-inflammatory cytokine production mainly by inhibiting succinate dehydrogenase activity, activating the NRF2 and ATF3driven responses and inhibiting NLRP3. Itaconate biosynthesis was found to be induced in the liver of mice exposed to ischemia reperfusion (I/R) stress and to oppose the resulting tissue injury by sustaining hepatoprotective antioxidant programs. Whether ACOD1 plays a role in the homeostatic response of liver to different noninfectious injuring conditions remains largely unexplored. This study investigates the contribution of itaconate biosynthesis in the response of liver to dietary lipid overload and in the development of associated nonalcoholic fatty liver disease.

Project description:Glucocorticoids are widely used to treat inflammatory disorders; however, prolonged use of glucocorticoids results in side effects including osteoporosis, diabetes and obesity. Compound A (CpdA), identified as a selective NR3C1/glucocorticoid receptor (nuclear receptor subfamily 3, group C, member 1) modulator, exhibits an inflammation-suppressive effect, largely in the absence of detrimental side effects. To understand the mechanistic differences between the classic glucocorticoid dexamethasone (DEX) and CpdA, we looked for proteins oppositely regulated in bone marrow-derived macrophages using an unbiased proteomics approach. We found that the autophagy receptor SQSTM1 but not NR3C1 mediates the anti-inflammatory action of CpdA. CpdA drives SQSTM1 upregulation by recruiting the NFE2L2 transcription factor to its promoter. In contrast, the classic NR3C1 ligand dexamethasone recruits NR3C1 to the Sqstm1 promoter and other NFE2L2-controlled gene promoters, resulting in gene downregulation. Both DEX and CpdA induce autophagy, with marked different autophagy characteristics and morphology. Suppression of LPS-induced Il6 and Ccl2 genes by CpdA in macrophages is hampered upon Sqstm1 silencing, confirming that SQSTM1 is essential for the anti-inflammatory capacity of CpdA, at least in this cell type. Together, these results demonstrate how off-target mechanisms of selective NR3C1 ligands may contribute to a more efficient anti-inflammatory therapy.