Project description:Macrophages in lungs can be classified into two subpopulations, alveolar macrophages (AMs) and interstitial macrophages (IMs), which reside in the alveolar and interstitial spaces, respectively. Accumulating evidence indicates the involvement of IMs in lung metastasis but the roles of AMs in lung metastasis still remain elusive. An intravenous injection of a mouse hepatocellular carcinoma (HCC) cell line, BNL, caused lung metastasis foci with infiltration of AMs and IMs. Comprehensive determination of arachidonic acid (AA) metabolite levels revealed increases in leukotrienes (LTs) and prostaglandins in lungs in this metastasis model. A 5-lipoxygenase (LOX) inhibitor but not a cyclooxygenase inhibitor reduced the numbers of metastatic foci, particularly those with larger sizes. A major 5-LOX metabolite, LTB4, augmented in vitro cell proliferation of human HCC cell lines as well as BNL cells. Moreover, in this lung metastasis course, AMs exhibited higher expression levels of the 5-LOX and LTB4 than IMs. Consistently, 5-LOX-expressing AMs increased in the lungs of human HCC patients with lung metastasis, compared with those without lung metastasis. Furthermore, intratracheal clodronate liposome injection selectively depleted AMs but not IMs, together with reduced LTB4 content and metastatic foci numbers in this lung metastasis process. Finally, IMs in mouse metastatic foci produced CCL2, thereby recruiting blood-borne, CCR2-expressing AMs into lungs. Thus, AMs can be recruited under the guidance of IM-derived CCL2 into metastatic lungs and can eventually contribute to the progression of lung metastasis by providing a potent AA-derived tumor growth promoting mediator, LTB4.

Project description:The lung is inhabited by resident alveolar and interstitial macrophages as well as monocytic cells that survey the lung. Each cell type plays distinct functional roles under homeostatic and inflammatory conditions, but mechanisms establishing their molecular identities and functional potential remain poorly understood. Here, systematic evaluation of transcriptomes and open chromatin of alveolar macrophages (AMs), interstitial macrophages (IMs) and lung monocytes from two mouse strains enabled inference of common and cell-specific transcriptional regulators. We provide evidence that these factors drive selection of regulatory landscapes that specify distinct phenotypes of AMs and IMs and entrain qualitatively different responses to TLR4 signaling in vivo. These studies reveal a striking divergence in a fundamental innate immune response pathway in AMs and establish a framework for further understanding macrophage diversity in the lung.

Project description:The lung is inhabited by resident alveolar and interstitial macrophages as well as monocytic cells that survey the lung. Each cell type plays distinct functional roles under homeostatic and inflammatory conditions, but mechanisms establishing their molecular identities and functional potential remain poorly understood. Here, systematic evaluation of transcriptomes and open chromatin of alveolar macrophages (AMs), interstitial macrophages (IMs) and lung monocytes from two mouse strains enabled inference of common and cell-specific transcriptional regulators. We provide evidence that these factors drive selection of regulatory landscapes that specify distinct phenotypes of AMs and IMs and entrain qualitatively different responses to TLR4 signaling in vivo. These studies reveal a striking divergence in a fundamental innate immune response pathway in AMs and establish a framework for further understanding macrophage diversity in the lung.

Project description:The lung is inhabited by resident alveolar and interstitial macrophages as well as monocytic cells that survey the lung. Each cell type plays distinct functional roles under homeostatic and inflammatory conditions, but mechanisms establishing their molecular identities and functional potential remain poorly understood. Here, systematic evaluation of transcriptomes and open chromatin of alveolar macrophages (AMs), interstitial macrophages (IMs) and lung monocytes from two mouse strains enabled inference of common and cell-specific transcriptional regulators. We provide evidence that these factors drive selection of regulatory landscapes that specify distinct phenotypes of AMs and IMs and entrain qualitatively different responses to TLR4 signaling in vivo. These studies reveal a striking divergence in a fundamental innate immune response pathway in AMs and establish a framework for further understanding macrophage diversity in the lung.

Project description:Tissue-resident macrophages (TRMs) are heterogeneous cell populations found throughout the body. Depending on their location, they perform diverse functions maintaining tissue homeostasis and providing immune surveillance. To survive and function within, TRMs adapt metabolically to the distinct microenvironments. However, little is known about the metabolic signatures of TRMs. The thymus provides a nurturing milieu for developing thymocytes yet efficiently removes those that failed the selection, relying on the TRMs – resident thymic macrophages (TMφs). This study harnesses multiomics analyses to characterize TMφs and unveils their unique metabolic features. We find that the pentose phosphate pathway (PPP) is preferentially activated in TMφs, responding to the reduction-oxidation demands associated with the efferocytosis of dying thymocytes. The blockade of PPP in Mφs leads to decreased efferocytosis, which can be rescued by ROS scavengers. Our study reveals the key role of PPP in TMφs and underscores the importance of metabolic adaptation in supporting Mφ efferocytosis.

Project description:Tissue-resident macrophages (TRMs) play central roles in local tissue development and immunity. However, how to control TRM ontogeny and maintenance remains unclear. We performed transcriptional and histone modification analyses of alveolar macrophages in mice with myeloid-specific (Csf1rCre) deletion of HDAC3 using bulk RNA-seq, single-cell RNA-seq and ChIP-seq. We report that HDAC3 deficiency results in metabolic disorders and increased cell death of the fetal lung TRMs, which is partially regulated through directly targeting PPAR-γ. Although the loss of AMs in the absence of HDAC3 is not AM subset specific, the transcriptome changes in HDAC3 deficient AM subsets are different. We propose that HDAC3 serves a key epigenetic regulator that controls embryonic TRM ontogeny and maintenance.

Project description:Tissue-resident macrophages (TRMs) play central roles in local tissue development and immunity. However, how to control TRM ontogeny and maintenance remains unclear. We performed transcriptional and histone modification analyses of alveolar macrophages in mice with myeloid-specific (Csf1rCre) deletion of HDAC3 using bulk RNA-seq, single-cell RNA-seq and ChIP-seq. We report that HDAC3 deficiency results in metabolic disorders and increased cell death of the fetal lung TRMs, which is partially regulated through directly targeting PPAR-γ. Although the loss of AMs in the absence of HDAC3 is not AM subset specific, the transcriptome changes in HDAC3 deficient AM subsets are different. We propose that HDAC3 serves a key epigenetic regulator that controls embryonic TRM ontogeny and maintenance.

Project description:Tissue-resident macrophages (TRMs) play central roles in local tissue development and immunity. However, how to control TRM ontogeny and maintenance remains unclear. We performed transcriptional and histone modification analyses of alveolar macrophages in mice with myeloid-specific (Csf1rCre) deletion of HDAC3 using bulk RNA-seq, single-cell RNA-seq and ChIP-seq. We report that HDAC3 deficiency results in metabolic disorders and increased cell death of the fetal lung TRMs, which is partially regulated through directly targeting PPAR-γ. Although the loss of AMs in the absence of HDAC3 is not AM subset specific, the transcriptome changes in HDAC3 deficient AM subsets are different. We propose that HDAC3 serves a key epigenetic regulator that controls embryonic TRM ontogeny and maintenance.

Project description:Lung interstitium macrophages (IMs) are non-alveolar resident tissue macrophages which contribute to the lung homeostasis. These cells were reported to be heterogeneous by our group and other teams, which contains two main distinct subpopulations: CD206+ IMs and CD206- IMs. However, the exact origin of IMs and the transcriptional programs that regulate IM differentiation remains unclear. In recent report, we analyzed the refilled IMs in the course of time after induced IM depletion with single-cell RNA sequencing (10X Genomics Chromium) and bulk RNA sequencing. In this study, the de novo refilled CD206+ and CD206- IMs on Day 14 post-depletion were compared to those without depletion. Alvelar macrophages (AMs) samples were also included in this analysis and served as a reference. Results of clustering and PCA analyses showed high similarity between de novo refilled and original IMs for both CD206+ and CD206- subsets. Only 9 genes were find upregulated in refilled IMs: AA467197, Cd109, Igf2r, Rarb and S100a4.

Project description:Tissue-resident macrophages (TRMs) are long-lived cells that maintain locally and can be phenotypically distinct from monocyte-derived macrophages. Whether TRMs and monocyte-derived macrophages have district roles under differing pathologies is not understood. Here, we showed that a substantial portion of the macrophages that accumulated during pancreatitis and pancreatic cancer in mice had expanded from TRMs. Pancreas TRMs had an extracellular matrix remodeling phenotype that was important for maintaining tissue homeostasis during inflammation. Loss of TRMs led to exacerbation of severe pancreatitis and death, due to impaired acinar cell survival and recovery. During pancreatitis, TRMs elicited protective effects by triggering the accumulation and activation of fibroblasts, which was necessary for initiating fibrosis as a wound healing response. The same TRM-driven fibrosis, however, drove pancreas cancer pathogenesis and progression. Together, these findings indicate that TRMs play divergent roles in the pathogenesis of pancreatitis and cancer through regulation of stromagenesis.