Project description:The importance of immunometabolism in the development of metabolic diseases is clear. Yet, how certain metabolic disorders, such as insulin deficiency (ID), influence immune cell function, and vice versa, is poorly understood. Also, therapeutic strategies to harness the interplay between immune cells and metabolism are lacking. Here, we observe that ID rearranges the immune landscape of the liver, causing a decrease of T cells and an increase of the Kupffer cells, accompanied by a shift in the transcriptional signature and polarization of the latter. Treating ID mice with the protein S100A9 rescues the polarization and lipid-related changes caused by ID in the KCs, and, through them, rescues hypertriglyceridemia and hyperketonemia in a TLR4-dependent manner. Additionally, S100A9 acts on other immune niches to increase glucose uptake in the skeletal muscle, improving hyperglycemia. In summary, our findings pinpoint the S100A9-TLR4 axis as a new tool to harness immune cells for improving ID-related metabolic dysfunction.

Project description:Background & Aims: Kupffer cell (KC) participates in hepatic inflammation and fibrosis in metabolic dysfunction-associated steatohepatitis (MASH), but underlying molecular mechanisms are not fully resolved. Transcription factor CCAAT/enhancer binding protein β (C/EBPβ) has been implicated in both metabolic and immune dysregulations. In this study, we aimed to investigate the role of C/EBPβ in KCs under the context of MASH pathogenesis. Approach & Results: A 12-week high-fat and high-cholesterol diet (HFHCD) model was used in wild-type or KC-specific Cebpb heterozygous knockout mice (Cebpbfl/+;Clec4f-iCre), followed by evaluation of liver using histopathology, analytical flow cytometry and RNA-seq. We found that HFHCD in wild-type mice induced significant inflammatory immune cell infiltration, including increased proportion of monocyte-derived macrophages (MoMFs), accompanied with concomitant increase in C/EBPβ protein level in KCs. KC-specific Cebpb heterozygous knockout significantly reduced HFHCD-induced immune cell (including MoMFs, neutrophils and CD8+ T cells) infiltration and inflammation-related gene expression in liver. FACS-sorted KCs of HFHCD-treated mice were used for C/EBPβ CUT&Tag-seq. We found that C/EBPβ activity was increased in MASH KCs, leading to selective promotion on part of MASH-induced genes. Combined analysis of RNA-seq and CUT&Tag-seq, along with dual luciferase reporter assay identified Vcam1 (encoding vascular cell adhesion molecule 1, VCAM1) as a key downstream gene of C/EBPβ in KCs of murine MASH liver. In both murine liver and MASH patients, VCAM1 was predominantly expressed in KCs. Its expression in liver was significantly increased after MASH onset, and it was involved in promoting immune cell infiltration in MASH. Conclusions: In MASH pathogenesis, increased C/EBPβ in KCs act as a MASH-associated stimulus-regulated TF, and has a direct transcriptional activation effect on Vcam1 promoter, leading to abnormal elevation in VCAM1 expression in KCs and subsequent immune cell infiltration. Our findings suggest that C/EBPβ in KCs can be a potential therapeutic target for NASH inflammation.

Project description:Background & Aims: Kupffer cell (KC) participates in hepatic inflammation and fibrosis in metabolic dysfunction-associated steatohepatitis (MASH), but underlying molecular mechanisms are not fully resolved. Transcription factor CCAAT/enhancer binding protein β (C/EBPβ) has been implicated in both metabolic and immune dysregulations. In this study, we aimed to investigate the role of C/EBPβ in KCs under the context of MASH pathogenesis. Approach & Results: A 12-week high-fat and high-cholesterol diet (HFHCD) model was used in wild-type or KC-specific Cebpb heterozygous knockout mice (Cebpbfl/+;Clec4f-iCre), followed by evaluation of liver using histopathology, analytical flow cytometry and RNA-seq. We found that HFHCD in wild-type mice induced significant inflammatory immune cell infiltration, including increased proportion of monocyte-derived macrophages (MoMFs), accompanied with concomitant increase in C/EBPβ protein level in KCs. KC-specific Cebpb heterozygous knockout significantly reduced HFHCD-induced immune cell (including MoMFs, neutrophils and CD8+ T cells) infiltration and inflammation-related gene expression in liver. FACS-sorted KCs of HFHCD-treated mice were used for C/EBPβ CUT&Tag-seq. We found that C/EBPβ activity was increased in MASH KCs, leading to selective promotion on part of MASH-induced genes. Combined analysis of RNA-seq and CUT&Tag-seq, along with dual luciferase reporter assay identified Vcam1 (encoding vascular cell adhesion molecule 1, VCAM1) as a key downstream gene of C/EBPβ in KCs of murine MASH liver. In both murine liver and MASH patients, VCAM1 was predominantly expressed in KCs. Its expression in liver was significantly increased after MASH onset, and it was involved in promoting immune cell infiltration in MASH. Conclusions: In MASH pathogenesis, increased C/EBPβ in KCs act as a MASH-associated stimulus-regulated TF, and has a direct transcriptional activation effect on Vcam1 promoter, leading to abnormal elevation in VCAM1 expression in KCs and subsequent immune cell infiltration. Our findings suggest that C/EBPβ in KCs can be a potential therapeutic target for NASH inflammation.

Project description:Kupffer cells (KCs) self-renew by local proliferation in the adult independently from monocytes (Mos). However, how they maintain during chronic metabolic disorders such as non-alcoholic steatohepatitis (NASH) remains ill-defined. We characterized KCs during NASH and observed diversity in the KC pool, with a significant fraction of monocyte-derived KCs (MoKCs). Here, we aim to uncover the transcriptional landscapes of KCs subsets found in a mouse model of methionine and choline deficient (MCD)-diet induced non-alcoholic steatohepatitis (NASH).

Project description:Evolution of melanoma from a primary tumor to widespread metastasis is crucially dependent on lymphatic spread. The mechanisms regulating the initial step in metastatic dissemination via regional lymph nodes remain largely unknown. We have previously described a dysfunctional immune profile that precedes evidence of metastasis in the first node draining from the primary tumor, the sentinel lymph node (SLN). Herein, we explore the role of melanoma-derived extracellular vesicles (EVs) as mediators of this pre-metastatic niche through cargo-specific polarization of dendritic cells (DCs). Utilizing mass cytometry, pre-metastatic SLNs demonstrate compromised co-stimulatory CD80 expression compared to healthy lymph nodes. Similarly, DCs matured in vitro in the presence of melanoma EVs showed impaired co-stimulation and polarization towards a chronic inflammatory cytokine milieu. Profiling of melanoma EV cargo identified shared proteomic and RNA signatures including the signaling axis S100A8, S100A9 and cognate receptor TLR4. Mechanistically, S100A8 and S100A9 compromised DC maturation, a phenotype which was partially recovered following TLR4 blockade. Early evidence demonstrates similar EVs can be isolated from human afferent lymphatic fluid ex vivo. Taken together, we propose synergistic interactions among melanoma EV cargo are responsible for suppressing DC maturation, potentially explaining the survival of malignant melanocytes metastasizing into seemingly “normal” regional lymph nodes.

Project description:Harnessing distinct tissue-resident immune niches via S100A9/TLR4 improves metabolic imbalance

Project description:Proinflammatory activation of hepatic macrophages plays a key role in the development of nonalcoholic steatohepatitis (NASH). This involves increased embryonic hepatic Kupffer cell (KC) death, facilitating the placement of KCs with bone marrow-derived recruited hepatic macrophages (RHMs) that highly express proinflammatory genes. Moreover, phago/efferocytic activity of KCs is diminished in NASH, enhancing liver inflammation. However, the molecular mechanisms underlying these changes in KCs are not known. Here, we show that HIF-2a mediates NASH-associated decreased KC growth and efferocytosis by enhancing lysosomal stress. At the molecular level, HIF-2a stimulated mTOR and ERK-dependent inhibitory TFEB phosphorylation, leading to decreased lysosomal and phagocytic gene expression. With increased metabolic stress and phago/efferocytic burden in NASH, these changes were sufficient to increase lysosomal stress, causing decreased efferocytosis and lysosomal cell death. Of interest, HIF-2a-dependent TFEB regulation only occurred in KCs, but not in RHMs. Instead, in RHMs, HIF-2a promoted mtROS production and proinflammatory activation by increasing ANT2 expression and mitochondrial permeability transition. Taken together, our results suggest that macrophage subtype-specific effects of HIF-2a collectively contributes to the proinflammatory activation of liver macrophages, leading to the development of NASH.

Project description:Kupffer cells (KCs) are tissue-resident macrophages which colonize the liver early during embryogenesis. KCs start to acquire a tissue-specific transcriptional signature immediately after colonizing the liver, mature together with the tissue, and adapt to the tissue?s functions. Throughout development and adulthood, KCs have distinct core functions that are essential for liver and organismal homeostasis, such as supporting fetal erythropoiesis as well as postnatal erythrocyte recycling and liver metabolism. However, whether perturbations of macrophage core functions during development contribute to or cause disease at postnatal stages is poorly understood. Here, we utilize a mouse model of maternal obesity to perturb KC functions during gestation. We show that offspring exposed to maternal obesity develop fatty liver disease, driven by aberrant developmental programming of KCs that persists into adulthood. Programmed KCs mediate lipid uptake by hepatocytes through apolipoprotein secretion. KC depletion in neonates born to obese mothers, followed by replenishment with exogenous monocytes, rescues the fatty liver disease. The transcriptional programming of KCs and the fatty liver disease phenotype are also rescued by genetic depletion of hypoxia-inducible factor alpha (Hif1?) in macrophages during gestation. These results establish developmental perturbation of KC functions as a cause for the development of fatty liver disease in adult life and, thereby, place fetal-derived macrophages as intergenerational messengers within the concept of developmental origins of health and diseases.

Project description:Liver sinusoidal endothelial cells (LSECs) and Kupffer cells (KCs) have important roles in liver homeostasis and host defense. Sharing the same microenvironment in the liver sinusoid, they form an effective scavenger cell system for removal of potentially harmful blood-borne substances. Unlike most other endothelia, LSECs are highly efficient in endocytosis of nanoparticles, including virus. Though controversial, LSECs have been reported to act as antigen presenting cells, thus contributing importantly to induction of immune tolerance in liver. There are also controversies about LSEC and KC specific markers, which may be due to overlapping cell functions, species differences, and/or problems with cell purification. We therefore used label-free proteomics to characterize and quantitatively compare proteome of freshly isolated, highly pure rat LSECs (SE-1/CD32b positive) and KCs (CD11b/c positive.We found that most immune genes expressed in KCs were also expressed in LSECs, albeit at a lower density, and they also have overlap in cell surface marker expression. Both cell types express high levels of scavenger receptors and immune lectins.

Project description:Kupffer cells (KCs) are tissue-resident macrophages which colonize the developing liver early during embryogenesis1. Throughout development and adulthood, KCs have distinct core functions that are essential for liver and organismal homeostasis, such as supporting fetal erythropoiesis as well as postnatal erythrocyte recycling and liver metabolism2. KCs acquire their tissue-specific transcriptional signature immediately after colonizing the liver, mature together with the tissue, and adapt to the tissue’s function1,3,4. However, whether perturbation of macrophage core functions during development may contribute to or cause disease at postnatal stages is poorly understood. Here, we utilize a maternal obesity model to disturb KC functions during gestation. We show that offspring born to obese mothers develop fatty liver disease that is accompanied by a local pro-inflammatory response, a phenotype that is augmented if the offspring is kept on control diet after birth. Further, transcriptional analyses reveal that KCs undergo developmental programming through the maternal high-fat diet, which lasts until adulthood. The offspring’s KC developmental programming is irreversible despite the switch to control diet and leads to increased lipid uptake in hepatocytes mediated via paracrine factors stemming from KCs. The transcriptional programming of KCs and the fatty liver disease phenotype are rescued by genetic depletion of hypoxia-inducible factor alpha (Hif1a) in macrophages during gestation. These results demonstrate that macrophages rely on an undisturbed development to fulfil their core functions and support organ homeostasis during adulthood, and establish developmental programming of KCs as a therapeutic strategy for metabolic disorders, such as fatty liver disease.