Project description:Hepatic macrophages play a central role in the initiation, progression and resolution of various liver diseases. Specifically, infiltrating Ly6Chi monocytes and their-derived macrophage (MoMFs) descendants prevail in acute or chronic liver injury, display marked transcriptional variance and provide crucial functional plasticity. A specific example of MoMFs are lipid associated macrophages (LAMs) involved in progression of metabolic liver disease (Remmerie et al., 2020). Recent studies have uncovered binary developmental trajectories of monocytes in the BM with Neutrophil-like (NeuMo) and dendritic cell (DC)-like (DCMo) monocytes (Weinreb et al., 2020; Yanez et al., 2017), hence further challenging our current comprehension of macrophage heterogeneity in the diseased liver. Yet, the molecular factors regulating their inflammatory versus restorative activity remains enigmatic. The COMMD (copper metabolism MURR1 domain) family includes 10 evolutionarily conserved proteins. Functions of COMMD proteins are still being defined, but they seem to play non-redundant roles in regulating transcription and protein trafficking. Utilizing conditional COMMD10 knockout mice we uncovered a role for COMMD10 in limiting inflammasome activation in Ly6Chi monocytes during experimental sepsis and colitis (Mouhadeb et al., 2018), and in supporting phagolysosomal biogenesis and maturation in KCs and BM-derived macrophages infected with Staphylococcus aureus (Ben Shlomo et al., 2019). Hence, these studies mark COMMD10 as a candidate mediator of monocyte and macrophage fate and immune responses. Here we studeid the effect of COMMD10-deficiency on Ly6Chi monocyte differentiation and inflammatory behaviour in the injured liver, using an acute model of acetaminophen-induced liver injury (AILI). Bulk RNAseq analysis of sorted Ly6Chi monocytes, comparing between COMMD10+ and COMMD10-deficient cells, revealed an increased differentiation bias of Ly6Chi monocytes towards NeuMo and LAM differentiation fates. Collectively, COMMD10 appears as an important regulator of Ly6Chi monocyte fate decisions and reparative behavior in the diseased liver.

Project description:Hepatic macrophages play a central role in the initiation, progression and resolution of various liver diseases. Specifically, infiltrating Ly6Chi monocytes and their-derived macrophage (MoMFs) descendants prevail in acute or chronic liver injury, display marked transcriptional variance and provide crucial functional plasticity. A specific example of MoMFs are lipid associated macrophages (LAMs) involved in progression of metabolic liver disease (Remmerie et al., 2020). Recent studies have uncovered binary developmental trajectories of monocytes in the BM with Neutrophil-like (NeuMo) and dendritic cell (DC)-like (DCMo) monocytes (Weinreb et al., 2020; Yanez et al., 2017), hence further challenging our current comprehension of macrophage heterogeneity in the diseased liver. Yet, the molecular factors regulating their inflammatory versus restorative activity remains enigmatic. The COMMD (copper metabolism MURR1 domain) family includes 10 evolutionarily conserved proteins. Functions of COMMD proteins are still being defined, but they seem to play non-redundant roles in regulating transcription and protein trafficking. Utilizing conditional COMMD10 knockout mice we uncovered a role for COMMD10 in limiting inflammasome activation in Ly6Chi monocytes during experimental sepsis and colitis (Mouhadeb et al., 2018), and in supporting phagolysosomal biogenesis and maturation in KCs and BM-derived macrophages infected with Staphylococcus aureus (Ben Shlomo et al., 2019). Hence, these studies mark COMMD10 as a candidate mediator of monocyte and macrophage fate and immune responses. Here we studeis the effect of COMMD10-deficiency on Ly6Chi monocyte differentiation and inflammatory behaviour in the injured liver, using an acute model of acetaminophen-induced liver injury (AILI). Single cell RNAseq analysis of sorted Ly6Chi monocytes, comparing between COMMD10+ and COMMD10-deficient cells, revealed increased differentiation bias of Ly6Chi monocytes towards NeuMo and LAM differentiation fates. Collectively, COMMD10 appears as an important regulator of Ly6Chi monocyte fate decisions and reparative behavior in the diseased liver.

Project description:Most tissue-resident macrophages are established prenatally and self-maintain independently of bone marrow (BM) monocytes. Instructed by local cues, these cells adopt unique transcriptional modules that impart tissue-specific functional identity (Varol et al., 2015). In the liver, Kupffer cells (KCs) dominate the homeostatic macrophage pool. They reside in the sinusoidal vessels and in the space of Disse, interacting with hepatic stellate cells (HSC) and hepatocytes (Bonnardel et al., 2019), where they act as sentinels and perform specialized accessory functions involving iron and lipid metabolism (Scott and Guilliams, 2018). Yet, the molecular cues governing KC differentiation and maintanence remain largly elusive. Embryonic lethality of COMMD10 deficiency has hampered the study of its function. Yet, utilizing conditional COMMD10 knockout mice we recently uncovered a role for COMMD10 in supporting phagolysosomal biogenesis and maturation in KCs and BM-derived macrophages infected with Staphylococcus aureus (Ben Shlomo et al., 2019). Here we show that COMMD10-deficient KCs adopt liver-specific identity. Strikingly, COMMD10-deficiency in KCs and in other tissue resident macrophages impedes their homeostatic survival, leading to their continuous replacement by Ly6Chi monocytes. Transcriptional analysis of COMMD10-deficiet KCs reveales a notable reduction in genes encoding for translation initiation- and ribosomal complex proteins, for ubiquitin and the proteasome protein complex, and for key proteins of the mitochondrial respiration chain. These transcriptional alterations allude to protein stress and mitochondrial dysfunction, and hint at the reason of their premature death.

Project description:Purpose: In our study, we identified a heterogeneity among bone marrow (BM) Ly6Chi monocytes, which can be subdivided the expression of CXCR4. In order to understand the development of BM monocytes, the goal of this experiment is to compare the transcriptome of these 2 BM Ly6Chi monocyte subsets to those of the common monocyte progenitor (cMoP) and Ly6Clo monocytes.

Project description:We performed a single-cell transcriptomic analysis of monocyte and monocyte progenitors by single-cell mRNA sequencing (scRNA-seq) using the C1 Fluidigm platform. We sorted BM cMoPs (Lin−CD117+CD115+CD135−Ly6C+), BM Ly6C+ monocytes (Lin−CD117-CD115+CD135−Ly6C+) and blood Ly6Chi monocytes (CD115+CD11b+Ly6Chi) from wild-type (WT) C57BL/6 mice by fluorescence-activated cell sorting (FACS) and generated transcriptional profiles for each individual cell (n = 38 for blood Ly6Chi monocytes, n = 66 for BM cMoPs, n = 57 for BM Ly6C+ monocytes).

Project description:We studied the role of Notch2 signaling in Ly6Chi monocyte cell fate during TLR7-induced acute inflammation. To characterize the gene expression changes involved in monocyte differentiation, we subjected monocyte subsets from peripheral blood of wt and myeloid Notch2 mutant mice after Sham or IMQ treatment to RNA-sequencing and gene expression analysis. We found that Cell-intrinsic Notch2 and TLR7-Myd88 pathways independently and synergistically promote Ly6Clo patrolling monocyte development from Ly6Chi monocytes under inflammatory conditions. At the same time TLR7 stimulation in the absence of functional Notch2 signaling promotes resident tissue macrophage gene expression signatures in monocytes and ectopic differentiation of Ly6Chi monocytes into macrophages and dendritic cells. Thus, Notch2 is a master regulator of Ly6Chi monocyte cell fate and inflammation in response to TLR signaling.

Project description:To compare the gene expression profiles of Macrophage & Dendritic cell Progenitors (MDPs), Common Dendritic cell Progenitors (CDPs), committed dendritic cell precursors (pre-DCs), and Ly6Chi monocytes from mouse bone marrow Four samples (MDPs, CDPs, pre-DCs, and monocytes) were collected in triplicate

Project description:Monocytes are integral cells of the innate immune system that play important roles in host defence and tissue repair. It is well established that monocytes are derived from the common monocyte progenitor (cMoP) in the bone marrow (BM) before giving rise to Ly6Chi mature monocytes that enter the circulation. However, our lab has discovered that BM Ly6Chi monocytes are not homogenous, and consist of two subpopulations (CXCR4hi and CXCR4lo) in both mice and humans. In particular, the CXCR4hi subset (termed transitional pre-monocyte (TpMo) population) actively proliferates in the BM and matures into the CXCR4lo subset, which represents mature Ly6Chi monocytes. Nevertheless, how this TpMo population may behave beyond their precursor role in the BM remains undefined. While TpMos have been shown to be strictly immobilized in the BM in the steady state, our preliminary data revealed the mobilization of TpMos into the circulation during sepsis. Furthermore, TpMos were found to give rise to more macrophages than mature Ly6Chi monocytes. Our data hence suggests a critical peripheral role for TpMos that may implicate the outcome of sepsis and possible potential implications in future therapies associated with monocytes. Based on our preliminary findings, we aim to have a better understanding of these monocyte subsets and how they are transcriptionally distinct when they have become macrophages. In particular, we would like to determine if TpMo-derived macrophages are less inflammatory compared to mature monocyte-derived macrophages.

Project description:Monocytes comprise two major subsets, Ly6Chi classical monocytes and Ly6Clo non-classical monocytes. Notch2 signaling in Ly6Chi monocytes triggers transition to Ly6Clo monocytes, which require Nr4a1, Bcl6, Irf2 and Cebpb. By comparison, less is known about transcriptional requirements for Ly6Chi monocytes. We find transcription factor CCAAT/enhancer-binding protein alpha (C/EBPα) is highly expressed in Ly6Chi monocytes, but down-regulated in Ly6Clo monocytes. A few previous studies described the requirement of C/EBPα in the development of neutrophils and eosinophils. However, role of C/EBPα for in vivo monocyte development has not been understood. We deleted the Cebpa +37 kb enhancer in mice, eliminating hematopoietic expression of C/EBPα, reproducing the expected neutrophil defect. Surprisingly, we also discovered a severe and selective loss of Ly6Chi monocytes, while preserving Ly6Clo monocytes. We find that BM progenitors from Cebpa +37–/– mice rapidly progress through the cMoP stage to develop directly into Ly6Clo monocytes even in the absence of Notch2 signaling. These results identify a previously unrecognized role for C/EBPα in maintaining Ly6Chi monocyte identity.

Project description:To compare the gene expression profiles of Macrophage & Dendritic cell Progenitors (MDPs), Common Dendritic cell Progenitors (CDPs), committed dendritic cell precursors (pre-DCs), and Ly6Chi monocytes from mouse bone marrow