Project description:Most tissue-resident macrophage populations develop during embryogenesis, self-renew in the steady state, and can expand during type 2 immunity. Whether shared mechanisms regulate macrophage proliferation in homeostasis and disease is unclear. We found that the transcription factor Bhlhe40 was cell-intrinsically required in large peritoneal macrophages (LPMs) for self-renewal and maintenance, but was not required in other resident macrophages. Bhlhe40 was selectively necessary in LPMs for proliferation, but not polarization, in response to IL-4. During a helminth infection, Bhlhe40 was required for normal LPM cell cycling. Bhlhe40 repressed the expression of Maf and Mafb and directly promoted expression of cell cycle-related transcripts to enable proliferation of LPMs. Genomic sites bound by Bhlhe40 in LPMs included some co-bound by the macrophage lineage-determining factor PU.1 and others uniquely bound by Bhlhe40, including Maf and cell cycle-related loci. Our findings demonstrate a tissue-specific control mechanism regulating resident macrophage proliferation in homeostasis and type 2 immunity.

Project description:Little is known about the effects of high fat diet (HFD)-induced obesity on resident colonic lamina propria (LP) macrophages (LPMs) function and metabolism. Here, we report that obesity and diabetes resulted in increased macrophage infiltration in the colon. These macrophages exhibited the residency phenotype CX3CR1hiMHCIIhi, and were CD4-TIM4-. During HFD, resident colonic LPM exhibited a lipid metabolism gene expression signature that overlapped that used to define lipid associated macrophages (LAMs). Via single cell RNA sequencing, we identified a sub-cluster of macrophages, increased in HFD, that were responsible for the LAM signature. Compared to other macrophages in the colon, these cells were characterized by elevated glycolysis, phagocytosis and efferocytosis signatures. CX3CR1hiMHCIIhi colonic resident LPMs had fewer lipid droplets (LD) and decreased triacylglycerol (TAG) content compared to equivalent cells in lean mice, and exhibited increased phagocytic capacity, suggesting that HFD induces adaptive responses in LPMs to limit bacterial translocation.

Project description:The clearance of apoptotic cells, termed efferocytosis, is essential for tissue homeostasis and prevention of autoimmunity. Although past studies have elucidated local molecular signals that regulate homeostatic efferocytosis1 in a tissue, whether signals arising distally also regulate homeostatic efferocytosis remains elusive. Here, we find that large peritoneal macrophages (LPMs) display impaired efferocytosis in broad-spectrum antibiotics (ABX)-treated, vancomycin-treated, and germ-free mice in vivo. Mechanistically, the microbiota-derived short-chain fatty acid butyrate directly boosted efferocytosis efficiency/capacity in mouse and human macrophages, and rescued ABX-induced LPM efferocytosis defects in vivo. Bulk mRNA sequencing of butyrate-treated macrophages in vitro and single cell mRNA sequencing of LPMs isolated from ABX-treated and butyrate-rescued mice revealed regulation of efferocytosis-supportive transcriptional programs. Specifically, we found that the efferocytosis receptor T-cell immunoglobulin and mucin domain containing 4 (TIM-4, Timd4) was downregulated in LPMs of ABX-treated mice but rescued by oral butyrate and TIM-4 was required for the butyrate-induced enhancement of LPM efferocytosis capacity. LPM efferocytosis was impaired beyond withdrawal of ABX and ABX-treated mice exhibited significantly worse disease in a mouse model of lupus. Our results demonstrate that homeostatic efferocytosis relies on distal metabolic signals and suggest that defective homeostatic efferocytosis may explain link between ABX use and inflammatory disease.  

Project description:The clearance of apoptotic cells, termed efferocytosis, is essential for tissue homeostasis and prevention of autoimmunity. Although past studies have elucidated local molecular signals that regulate homeostatic efferocytosis1 in a tissue, whether signals arising distally also regulate homeostatic efferocytosis remains elusive. Here, we find that large peritoneal macrophages (LPMs) display impaired efferocytosis in broad-spectrum antibiotics (ABX)-treated, vancomycin-treated, and germ-free mice in vivo. Mechanistically, the microbiota-derived short-chain fatty acid butyrate directly boosted efferocytosis efficiency/capacity in mouse and human macrophages, and rescued ABX-induced LPM efferocytosis defects in vivo. Bulk mRNA sequencing of butyrate-treated macrophages in vitro and single cell mRNA sequencing of LPMs isolated from ABX-treated and butyrate-rescued mice revealed regulation of efferocytosis-supportive transcriptional programs. Specifically, we found that the efferocytosis receptor T-cell immunoglobulin and mucin domain containing 4 (TIM-4, Timd4) was downregulated in LPMs of ABX-treated mice but rescued by oral butyrate and TIM-4 was required for the butyrate-induced enhancement of LPM efferocytosis capacity. LPM efferocytosis was impaired beyond withdrawal of ABX and ABX-treated mice exhibited significantly worse disease in a mouse model of lupus. Our results demonstrate that homeostatic efferocytosis relies on distal metabolic signals and suggest that defective homeostatic efferocytosis may explain link between ABX use and inflammatory disease.  

Project description:Local factors produced in the tissue microenvironment play essential roles in promoting the ontogeny and phenotype of tissue resident macrophages (TRM). In the peritoneal cavity, large peritoneal macrophages (LPM) are the dominant TRMs that functionally mediate type 2 immunity, facilitate tissue repair of the mesothelium, and protect against peritoneal fibrosis. It is established that retinoic acid derived from the omentum induces transcription factor Gata6 expression in LPMs, which in turn regulates gene expression of factors that define peritoneal macrophages. It is still unclear whether retinoic acid is the sole local factor that regulates Gata6 expression in LPMs. Mesothelial cells line the entire peritoneal cavity and produce a protective, non-adhesive barrier against injury, at least in part by recruiting immune cells with secreted cytokines, such as M-CSF. We hypothesized that secreted factors from peritoneal mesothelial cells are also responsible for regulating LPM development including both ontogeny and function. Due to their immediate proximity to the peritoneal cavity, we propose that mesothelial cells can produce and secrete proteins into the peritoneum to maintain Gata6 expression by LPMs. To identify secreted factors that are highly and specifically expressed in mesothelial cells, we harvested primary mesothelial cells from 10-week-old C57BL/6 mice using FACS selection (CD45- PDPN+ GPM6a+). Total RNA was isolated from these cells and subjected to RNA-seq analysis after depletion of ribosomal RNA.

Project description:Tissues in multicellular organisms are ‘serviced’ by resident macrophages, which perform both generic and tissue-specific functions. The latter relies on unique tissue-specific molecular programs induced by signals from the microenvironment and executed through a combinatorial action of tissue-specific and broadly expressed transcriptional regulators. Here, we identify the transcription factors Bhlhe40 and Bhlhe41 as novel regulators of alveolar macrophages (AMs) – a population that provides the first line of immune defense and executes homeostatic functions in lung alveoli. In the absence of these factors, AMs exhibited decreased proliferation that resulted in a severe disadvantage of knockout AMs in a competitive setting. Gene expression analyses revealed a broad cell-intrinsic footprint of Bhlhe40/Bhlhe41-deficiency manifested by a downregulation of AM signature genes and induction of signature genes of other macrophage lineages. Genome-wide characterization of Bhlhe40 DNA binding suggested that these transcription factors directly repress the expression of lineage-inappropriate genes in AMs. Taken together, these results identify Bhlhe40 and Bhlhe41 as key regulators of AM self-renewal and guardians of their identity.

Project description:Differentiated macrophages can self-renew in tissues and expand long-term in culture, but the gene regulatory mechanisms that accomplish self-renewal in the differentiated state have remained unknown. Here we show that in mice, the transcription factors MafB and c-Maf repress a macrophage-specific enhancer repertoire associated with a gene network controlling self-renewal. Single cell analysis revealed that, in vivo, proliferating resident macrophages can access this network by transient down-regulation of Maf transcription factors. The network also controls embryonic stem cell self-renewal but is associated with distinct embryonic stem cell-specific enhancers. This indicates that distinct lineage-specific enhancer platforms regulate a shared network of genes that control self-renewal potential in both stem and mature cells.

Project description:Rationale: Doxorubicin-induced cardiomyopathy (DiCM) is a significant cause of heart failure and mortality in cancer patients, in which macrophage-orchestrated inflammation serves as an essential pathogenic mechanism. However, the specific roles of tissue-resident and monocyte-derived macrophages in DiCM remain poorly understood. Objective: Uncovering the origins, phenotypes, and functions of proliferative cardiac resident macrophages and mechanistic insights into the self-maintenance of cardiac macrophage during DiCM progression. Methods and Results: Mice were administrated with doxorubicin to induce cardiomyopathy. Dynamic changes of resident and monocyte-derived macrophages were examined by lineage tracing, parabiosis, and bone marrow transplantation. We found that the monocyte-derived macrophages primarily exhibited a pro-inflammatory phenotype that dominated the whole DiCM pathological process and impaired cardiac function. In contrast, cardiac resident macrophages were vulnerable to doxorubicin insult. The survived resident macrophages exhibited enhanced proliferation and conferred a reparative role. Global or myeloid specifically ablation of class A1 scavenger receptor (SR-A1) inhibited proliferation of cardiac resident reparative macrophages and therefore exacerbated cardiomyopathy in DiCM mice. Importantly, the detrimental effect of macrophage SR-A1 deficiency was confirmed by transplantation of GFP+ wild type bone marrow. At the mechanistic level, we show that c-Myc, a key transcriptional factor for the SR-A1-P38-SIRT1 pathway, mediated the effect of SR-A1 in reparative macrophage proliferation in DiCM. Conclusions: The SR-A1-c-Myc axis may represent a promising target to treat DiCM through augmentation of cardiac resident reparative macrophage proliferation.

Project description:Tissue-resident Macrophages have long been appreciated as playing a fundamental role in the ontogeny and function of several organs. For example, osteoclasts are crucial for proper bone remodeling, microglia for synaptic pruning, and lung alveolar macrophages for clearance of surfactant. Perivascular macrophages have been described in many organs. Our analysis of murine perivascular macrophages in several tissues and organs led us to define a macrophage family, whose members share the expression of a number of surface molecules that are not typically considered macrophage markers, such as Lyve1, Folate Receptor 2 (Folr2), Enpep/CD249, and CD38, as well as other more typical macrophage markers such as CD206 and Tim4. This family of perivascular macrophages also occurs in humans. Importantly, this family of perivascular macrophages relies on the transcription factor c-MAF, encoded by the gene Maf, for its full function. Conditional deletion of the Maf gene in the Lyve1+Folr2+CD38+ macrophage family caused their ablation in the brain, without impact on the microglia, while in the adipose tissue the conditional deletion of the Maf gene in perivascular macrophages resulted in a profoundly altered macrophage gene expression, and brought about an increased vascular branching in this tissue. Mice with conditional Maf deletion were protected from metabolic syndrome when submitted to high fat diet (HFD). Our results show that c-MAF is the master regulator of a family of perivascular macrophages.

Project description:Homozygous disruption of c-Maf led to embryonic lethality and impaired erythroblastic island formation. c-Maf is expressed in the fetal liver macrophages. It suggests that macrophages are responsible for the lethality of c-Maf knock-out embryos. To search downstream genes of c-Maf, we surveyed genes associated with macrophage function by microarray analysis. keywords: c-Maf, macrophage, erythroblastic islands, WT (c-Maf WT) and c-Maf KO (c-Maf KO) fetal liver macrophages were sorted by a FACSAria cell sorter. Total RNAs from those macrophages were prepared using RNeasy Kit. Genes down-regulated in c-Maf KO macrophages were searched by GeneSpring software.