Project description:The role of macrophages in fibrosing steatohepatitis is largely unclear. We characterized the origin and molecular mechanisms of macrophages and its targeted therapy of fibrosing steatohepatitis. Fibrosing steatohepatitis was established in Alms1 mutant (foz/foz) and C57BL/6J wildtype mice fed high-fat/high-cholesterol or methionine- and choline-deficient diet. Bone marrow transplantation was performed to track the macrophage origin in fibrosing steatohepatitis. Macrophages were depleted using liposomal clodronate. Primary macrophages were isolated from bone marrow for adoptive transfer into mice. We found that macrophage infiltration is induced in two mouse models of fibrosing steatohepatitis and human nonalcoholic steatohepatitis-fibrosis patients. Bone marrow-derived macrophages (BMMs) contribute to the hepatic macrophage accumulation in experimental fibrosing steatohepatitis. Depletion of hepatic BMMs by liposomal clodronate during liver injury attenuated fibrosing steatohepatitis, whilst BMMs depletion after liver injury delayed the regression of fibrosing steatohepatitis. The pro-fibrotic effect of macrophages was associated with reduced activation of hepatic stellate cells (HSCs), collagen deposition and hepatic expression of key pro-fibrotic factors (TIMP1, TIMP2, and TGF?1) and endoplasmic reticulum stress markers (GRP78, IRE1?, and PDI). Conversely, adoptive transfer of BMMs significantly aggravated fibrosing steatohepatitis. Moreover, macrophage-conditioned medium directly promoted the phenotypic transition of primary quiescent HSCs to activated HSCs; it enhanced activation and proliferation but decreased apoptosis of HSC cell lines (LX-2 and HSC-T6). The effect of BMMs in promoting fibrosing steatohepatitis was mediated by inducing key pro-fibrosis factors and signaling pathways including cytokine/chemokine, TGF? and complement cascade as assessed by cDNA expression array. Complement 3a receptor (C3ar1) was a predominant effector of macrophage mediated fibrosing steatohepatitis. Knockout of C3ar1 in mice blunted development of fibrosing steatohepatitis. In conclusion, BMMs promoted the progression of fibrosing steatohepatitis during injury, whereas macrophages reduced fibrosing steatohepatitis in the recovery phase of liver injury. Increasing anti-fibrotic macrophages and decreasing pro-fibrotic macrophages are promising approaches for fibrosing steatohepatitis. © 2019 The Authors. The Journal of Pathology published by John Wiley & Sons Ltd on behalf of Pathological Society of Great Britain and Ireland.

Project description:Ductular reactions (DRs) are observed in virtually all forms of human liver disease; however, the histogenesis and function of DRs in liver injury are not entirely understood. It is widely believed that DRs contain bipotential liver progenitor cells (LPCs) that serve as an emergency cell pool to regenerate both cholangiocytes and hepatocytes and may eventually give rise to hepatocellular carcinoma (HCC). Here, we used a murine model that allows highly efficient and specific lineage labeling of the biliary compartment to analyze the histogenesis of DRs and their potential contribution to liver regeneration and carcinogenesis. In multiple experimental and genetic liver injury models, biliary cells were the predominant precursors of DRs but lacked substantial capacity to produce new hepatocytes, even when liver injuries were prolonged up to 12 months. Genetic modulation of NOTCH and/or WNT/?-catenin signaling within lineage-tagged DRs impaired DR expansion but failed to redirect DRs from biliary differentiation toward the hepatocyte lineage. Further, lineage-labeled DRs did not produce tumors in genetic and chemical HCC mouse models. In summary, we found no evidence in our system to support mouse biliary-derived DRs as an LPC pool to replenish hepatocytes in a quantitatively relevant way in injury or evidence that DRs give rise to HCCs.

Project description:Aging results in deterioration of the immune system, which is associated with increased susceptibility to infection and impaired wound healing in the elderly. Phagocytosis is an essential process in both wound healing and immune defence. As such, age-related impairments in phagocytosis impact on the health of the elderly population. Phagocytic efficiency in peritoneal macrophages, bone marrow-derived macrophages and bone marrow monocytes from young and old mice was investigated. Aging significantly impaired phagocytosis by peritoneal macrophages, both in vitro and in vivo. However, bone marrow-derived macrophages and bone marrow monocytes did not exhibit age-related impairments in phagocytosis, suggesting no intrinsic defect in these cells. We sought to investigate underlying mechanisms in age-related impairments in phagocytosis by peritoneal macrophages. We hypothesized that microenvironmental factors in the peritoneum of old mice impaired macrophage phagocytosis. Indeed, macrophages from young mice injected into the peritoneum of old mice exhibited impaired phagocytosis. Proportions of peritoneal immune cells were characterized, and striking increases in numbers of T cells, B1 and B2 cells were observed in the peritoneum of old mice compared with young mice. In addition, B cell-derived IL-10 was increased in resting and LPS-activated peritoneal cell cultures from old mice. These data demonstrate that aging impairs phagocytosis by tissue-resident peritoneal macrophages, but not by bone marrow-derived macrophages/monocytes, and suggest that age-related defects in macrophage phagocytosis may be due to extrinsic factors in the tissue microenvironment. As such, defects may be reversible and macrophages could be targeted therapeutically in order to boost immune function in the elderly.

Project description:Bone marrow derived macrophage vs peritoneal macrophage

Project description:A common feature of many skeletal diseases is the accumulation of marrow fat. A reciprocal relationship exists between osteogenesis and adipogenesis in bone marrow that is mediated by the relative activity of PPAR? and RUNX2 transcription factors. The ERK/MAPK pathway is an important inducer of MSC differentiation to osteoblasts and an inhibitor of adipogenesis that functions by phosphorylating RUNX2 and PPAR?. To begin to assess the importance of this regulation in vivo, we examined the consequences of blocking one arm of this pathway, PPAR? S112 phosphorylation, by evaluating the bone phenotype of PPAR? S112A mutant mice. This mutation prevents MAPK phosphorylation and inhibition of PPAR? transcriptional activity. Both male and female PPAR? S112A mice had decreased tibial and vertebral BV/TV and decreased trabecular bone relative to wild type littermates. These results were explained by a decrease in bone formation and osteoblast activity in the absence of changes in resorption. In contrast, marrow adipose tissue, adipocyte markers and serum adiponectin were all dramatically increased. Bone marrow stromal cells isolated from PPAR? S112A mice had elevated PPAR? and preferentially differentiated to adipocytes while total and phosphorylated RUNX2 and osteoblastogenesis were inhibited, indicating that the PPAR? S112A mutation affects bone in a cell autonomous manner. Changes in osteoblast/adipocyte lineage allocation in MSC cultures were also seen where CFU-OBs were reduced with a parallel increase in CFU-AD. This study emphasizes the importance of PPAR? phosphorylation in controlling bone mass and marrow adiposity and demonstrates how a regulatory mutation in PPAR? previously associated with peripheral fat metabolism can have broader effects on bone homeostasis that may in turn affect whole body energy metabolism.

Project description:Cell therapy can improve cardiac function in animals and humans after injury, but the mechanism is unclear. We performed cell therapy experiments in genetically engineered mice that permanently express green fluorescent protein (GFP) only in cardiomyocytes after a pulse of 4-OH-tamoxifen. Myocardial infarction diluted the GFP(+) cardiomyocyte pool, indicating refreshment by non-GFP(+) progenitors. Cell therapy with bone marrow-derived c-kit(+) cells, but not mesenchymal stem cells, further diluted the GFP(+) pool, consistent with c-kit(+) cell-mediated augmentation of cardiomyocyte progenitor activity. This effect could not be explained by transdifferentiation to cardiomyocytes by exogenously delivered c-kit(+) cells or by cell fusion. Therapy with c-kit(+) cells but not mesenchymal stem cells improved cardiac function. These findings suggest that stimulation of endogenous cardiogenic progenitor activity is a critical mechanism of cardiac cell therapy.

Project description:M-CSF is a critical growth factor for myeloid lineage cells, including monocytes, macrophages, and osteoclasts. Tissue-resident macrophages in most organs rely on local M-CSF. However, it is unclear what specific cells in the bone marrow produce M-CSF to maintain myeloid homeostasis. Here, we found that Adipoq-lineage progenitors but not mature adipocytes in bone marrow or in peripheral adipose tissue, are a major cellular source of M-CSF, with these Adipoq-lineage progenitors producing M-CSF at levels much higher than those produced by osteoblast lineage cells. The Adipoq-lineage progenitors with high CSF1 expression also exist in human bone marrow. Deficiency of M-CSF in bone marrow Adipoq-lineage progenitors drastically reduces the generation of bone marrow macrophages and osteoclasts, leading to severe osteopetrosis in mice. Furthermore, the osteoporosis in ovariectomized mice can be significantly alleviated by the absence of M-CSF in bone marrow Adipoq-lineage progenitors. Our findings identify bone marrow Adipoq-lineage progenitors as a major cellular source of M-CSF in bone marrow and reveal their crucial contribution to bone marrow macrophage development, osteoclastogenesis, bone homeostasis, and pathological bone loss.

Project description:Triplicate circadian time courses in synchronized macrophages sampling every 2 hours over 48 hours, starting at 16 hours post serum shock. Global proteome at each time point was quantified with 8 TMT10plex experiments.

Project description:Immunometabolism is a rapidly growing field, which has led to greater understanding of innate immune cell functions. Macrophages are at the core of this research: polarized subsets of in vitro-derived cells reportedly utilize select metabolic pathways to maintain their phenotype. However, relevance of these in vitro studies to the in vivo setting is not known, and metabolic requirements are likely dependent on unique physiological and cellular metabolic environments. Here we define the metabolic requirements of peritoneal tissue-resident macrophages, the accessibility of these metabolites to cells in the peritoneum, and we dissect the role of this unique environment in maintaining a crucial macrophage function. We find that the peritoneal cavity is enriched in amino acids, most notably glutamate. Peritoneal tissue-resident macrophages have an extraordinarily large mitochondrial capacity compared with other phagocytes; this is primarily fueled by glutaminolysis, which is additionally required to maintain an extensive respiratory burst. Glutaminolysis fuels the electron transport chain, which is enhanced during tissue-resident macrophage respiratory burst via a switch to dependence of mitochondrial complex-II. This is not dependent on the level of NADPH, but requires p47 maintained NADPH-oxidase activity. Therefore, we propose that tissue-resident macrophages exploit their unique metabolic niche by implementing their glutamine-fueled mitochondrial-rich phenotype to sustain respiratory burst to assault pathogens, showing that cell-specific metabolic underpinning is important for function. Importantly, we also find that glutamine is required for the respiratory burst in human monocytes, which highlights that metabolites are not species-specific and can be the link between cellular mechanism in mouse and man.

Project description:Hematopoietic stem cell (HSC) maintenance depends on extrinsic cues. Currently, only local signals arising from the bone marrow niche have been shown to maintain HSCs. However, it is not known whether systemic factors also sustain HSCs. We assessed the physiological source of thrombopoietin (TPO), a key cytokine required for maintaining HSCs. Using TpoDsRed-CreER knock-in mice, we showed that TPO is expressed by hepatocytes but not by bone marrow cells. Deletion of Tpo from hematopoietic cells, osteoblasts, or bone marrow mesenchymal stromal cells does not affect HSC number or function. However, when Tpo is deleted from hepatocytes, bone marrow HSCs are depleted. Thus, a cross-organ factor, circulating TPO made in the liver by hepatocytes, is required for bone marrow HSC maintenance. Our results demonstrate that systemic factors, in addition to the local niche, are a critical extrinsic component for HSC maintenance.