Project description:Background & Aims: Liver macrophages are heterogeneous and play an important role in alcohol_x0002_associated liver disease (ALD) but there is limited understanding of the functions of specific macrophage subsets in the disease. We used a Western Diet Alcohol (WDA) mouse model of ALD to examine the hepatic myeloid cell compartment by scRNA seq and targeted Kupffer cell (KC) ablation to understand the diversity and function of liver macrophages in ALD. Approach and Results: In the WDA liver, KCs and infiltrating monocytes/macrophages (IMs) each represented about 50% of the myeloid pool. Five major KC clusters all expressed genes associated with receptor mediated endocytosis and lipid metabolism, but most were predicted to be non_x0002_inflammatory and antifibrotic with one minor KC cluster having a pro-inflammatory and extracellular matrix degradation gene signature. IM clusters, in contrast, were predicted to be pro_x0002_inflammatory and pro-fibrotic. In vivo diphtheria toxin based selective KC ablation during alcohol exposure resulted in a liver failure phenotype with increases in PT/INR and bilirubin, loss of differentiated hepatocyte gene expression, and an increase in expression of hepatocyte progenitor markers such as EpCAM, CK-7 and Igf2bp3. Gene set enrichment analysis of whole liver RNAseq from the KC ablated WDA mice showed a similar pattern as seen in human alcoholic hepatitis. Conclusions: In this ALD model, KCs are anti-inflammatory and are critical for maintenance of hepatocyte differentiation. IMs are largely pro-inflammatory and contribute more to liver fibrosis. Future targeting of specific macrophage subsets may provide new approaches to treatment of liver failure and fibrosis in ALD.

Project description:There is an evident, unmet need to develop a commercially available in vitro system that can model inflammatory states of the liver and predict immune-mediated hepatotoxicity of drugs and xenobiotics taken under inflamed conditions. Hepatocyte-Kupffer cell co-cultures can model inflammation-mediated hepatotoxicity; however, Kupffer cell (KC) source remains an important bottleneck for the development of such models. Primary human Kupffer cells (PHKCs) are costly, limited in availability and exhibit donor variability. An alternative cell source for KCs has not been reported. Important paradigm shift from the classical dogma of adult blood-circulating monocyte-derived macrophages to intrahepatic precursor/fetal monocyte-derived macrophages has shed new light into the origin of KCs in vivo. Based on these recent findings, we report here, a novel method to generate human KCs in vitro from stem cells (hPSC-KCs) via fetal monocytes. hPSC-KCs expressed macrophage markers, CD11, CD14, CD68, CD163 and CD32 at gene and protein level and exhibited functional properties such as phagocytosis and Interleukin-6 and Tumor Necrosis Factor-4alpha production upon activation. Importantly, molecular signature, liver-macrophage specific CLEC-4F expression and cytokines production levels of hPSC-KCs were similar to PHKCs but different from non-liver macrophages. We used an inflammatory liver co-culture model to demonstrate that activated hPSC-KCs, but not non-liver macrophages, were able to recapitulate effects of PHKCs when stimulated with paradigm hepatotoxicants. hPSC-KCs developed in this study offer a renewable human cell source for liver-specific macrophages which can be used to develop in vitro systems for modelling the inflammatory state of the liver. Gene expression profiles of 9 samples were determined using Human Gene 2.0 ST Array. These 9 samples included three replicates each of PHKCs (primary human Kupffer cells), human pluripotent stem cell-dervied Kupffer cells (hPSC-KCs) and non-liver macrophages (NL-Mφ).

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.

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.

Project description:Abstinence is an important therapeutic intervention for patients with alcohol-associated liver disease (ALD). However, fibrosis improvement after cessation is not uniform and some patients do not improve. We aimed to use scATAC-seq analysis in a mouse model of ALD to define the mechanism of poor ALD resolution. We analyzed differentially accessible regions in livers from control, ALD, or 4 weeks post alcohol cessation mice and identified transcription factors activated in ALD that remained activated after alcohol withdrawal. The top hit was C/EBPβ. We found that hepatocyte specific Cebpb knockout prevented ALD development, while knockout at the time of alcohol cessation promoted fibrosis resolution.

Project description:Inflammation, mediated by liver-resident Kupffer cells (KCs) and recruited infiltrating macrophages (IMs), plays a critical role in NAFLD pathogenesis. Cholesterol induces pro-inflammatory cytokine production by macrophages and has been identified as a key factor involved in progression from simple steatosis to NASH. In this study, using the fructose, palmitate, cholesterol & trans-fat (FPC) diet model which recapitulates human NAFLD, we aimed to determine the impact of cholesterol manipulation on NAFLD progression/regression and macrophage phenotype in vivo.The transcriptomic evaluation of hepatic macrophages from mice fed with FPC diet contained the highest concentration of cholesterol (1.25%) suggest these cells might contribute to liver inflammation, steatohepatitis, and hepatocarcinoma pathways during the progression phase.

Project description:In mice, Kupffer cells (KCs) first derive from yolk sac (YS) hematopoietic progenitors prior to the emergence of the hematopoietic stem cell. To investigate human KC ontogeny, we recapitulated YS hematopoiesis from human pluripotent stem cells (hPSCs) and transplanted derivative macrophage progenitors into NSG mice previously humanized with hPSC-liver sinusoidal endothelial cells (LSECs). We demonstrate that hPSC-LSECs facilitate stable hPSC-YS-macrophage engraftment for at least 7 weeks. Single cell RNA sequencing of engrafted YS-macrophages revealed a homogenous MARCO-expressing KC gene signature and low expression of inflammatory macrophage genes. In contrast, human cord blood (CB)-derived macrophages generated grafts that contain multiple hematopoietic lineages in addition to KCs. Functional analyses showed that the engrafted KCs actively perform phagocytosis and erythrophagocytosis in vivo. Taken together, these findings demonstrate that it is possible to generate human KCs from hPSCs and show that the equivalent of the human YS hematopoietic programs represent enriched sources of progenitors for this lineage.

Project description:Saturated very long-chain fatty acids (VLCFA, ≥ C22), enriched in brain myelin and innate immune cells, accumulate in X-linked adrenoleukodystrophy (X-ALD). The severest form, inherited dysfunction of the VLCFA transporter ABCD1, underlying X-ALD, causes brain myelin destruction with infiltration of pro-inflammatory skewed monocytes/macrophages. How VLCFA levels relate to macrophage activation is unclear. Using whole transcriptome sequencing of X-ALD macrophages, we revealed that VLCFAs prime human macrophage membranes for inflammation and increase factors involved in chemotaxis and invasion. When applied externally, mimicking lipid destruction in X-ALD lesions, VLCFAs did not activate toll-like receptors in healthy cells but provoked pro-inflammatory responses through scavenger receptor CD36-mediated uptake, cumulating in JNK signalling and expression of matrix degrading enzymes and chemokine release. Following pro-inflammatory LPS-activation, VLCFA accumulated in healthy macrophages but were rapidly cleared with onset of resolution by increasing VLCFA degradation through liver-X-receptor mediated upregulation of ABCD1. ABCD1 deficiency impaired VLCFA homeostasis and prolonged pro-inflammatory gene expression. Our study uncovers a pivotal role for ABCD1, a protein linked to neuroinflammation, and associated peroxisomal VLCFA degradation in regulating macrophage plasticity.

Project description:Background and aims: Macrophages are highly versatile innate phagocytes present in most organs of the body and perform various homeostatic and immunological functions. Macrophages are classically known for their important roles in compacting pathogens. Whereas, increasing evidence supports that exposure to infections invokes prolonged changes to tissue-resident macrophages, it remains unclear whether this occurs to liver macrophages. Methods: Here, we utilized a model of parasitic infection invoked by the protozoan parasite Trypanosoma brucei brucei to investigate whether infection history can durably reshape hepatic macrophage identity and function. Employing a combination of genetic lineage-tracing, single cell transcriptomics, epigenomic analysis, and functional assays, we studied the alterations to the liver macrophage compartment during and after the resolution of infection. Results: We show that the infection alters the composition of liver-resident macrophages, leading to the infiltration of monocytes that differentiate into various infection-associated macrophage populations with divergent transcriptomic profiles. Whereas infection-associated macrophages disappear post-resolution of infection, monocyte-derived macrophages assuming the Kupffer cell (KC)-like profile engraft in the liver and co-existed with embryonic KCs in the long-term. Remarkably, the prior exposure to infection imprinted a specific transcriptional program on post-resolution KCs that was independent of cell ontogeny. This reprogramming of KCs was driven by an epigenetic remodeling of KC chromatin landscapes and associated with altered KC function and was associated with increased resiliance to subsequent bacterial infection. Conclusion: Our study demonstrates that prior exposure to a parasitic infection can reshape the identity and function of the liver macrophage pool in the long-term.

Project description:Alcohol-associated liver disease (ALD) is a major cause of alcohol related mortality. Recently we identified hepatic demethylases KDM5B and KDM5C as important sex-specific epigenetic regulators of alcohol response in the liver. In this study we aimed to study the molecular mechanisms of KDM5-dependent ALD development and resolution. We found that alcohol induces pathological changes in cell-cell communication in the liver that are in part mediated by epigenetic changes in hepatocytes mediated by histone demethylase KDM5B. Using cell type specific knockout mice, we found that KDM5B histone demethylase was a key regulator of alcohol-induced epigenetic changes in hepatocytes. Moreover, it regulated hepatocytes-non-parenchymal cell crosstalk that promoted inflammation and fibrosis development in ALD. This mechanism was specific to females. In males KDM5B deficiency was not sufficient to prevent fibrosis development. In contrast KDM5B demethylase loss promoted fibrosis resolution in both males and females. This mechanism involved changes in hepatocyte-macrophage crosstalk and LXRα activation, which we identified to be critical for the fibrosis resolution process. CONCLUSION: In summary, KDM5B demethylase is a regulator of cell-cell crosstalk involved in disease progression in females and in disease resolution in both sexes.