Project description:Cell communication within tissues is mediated by multiple paracrine signals including growth factors, which control cell survival and proliferation. Cells and the growth factors they produce and receive constitute a circuit, yet the design features of cell circuits involved in tissue homeostasis are unknown. Here we used computational and experimental approaches to characterize the features of cell circuits based on growth factor exchange between macrophages and fibroblasts, two cell types found in most mammalian tissues. We found that the macrophage-fibroblast cell circuit is stable and robust to perturbations. We employed analytical screening of all possible two-cell circuit topologies and defined the circuit features sufficient for stability, including environmental constraint and negative feedback regulation. Moreover, we discovered that cell-cell contact was essential for the stability of the macrophage-fibroblast circuit. These findings highlight general principles of cell circuit design, and provide a new perspective on quantitative understanding of tissue homeostasis.

Project description:Rationale: Expansion and activation of cardiac fibroblasts contributes to adverse remodeling, fibrosis and dysfunction in the pressure-overloaded heart. Although early fibroblast TGF-β/Smad3 activation protects the pressure overloaded heart by preserving the matrix, sustained TGF-β activation may be deleterious, accentuating fibrosis and dysfunction. Thus, endogenous mechanisms that negatively regulate the TGF- response in fibroblasts may be required to protect from progressive fibrosis and adverse remodeling. Objective: To study the role of fibroblast-specific induction of Smad7, an inhibitory Smad that restrains TGF-β signaling, in regulation of fibrosis, remodeling and dysfunction of the pressure-overloaded heart. Methods and Results: In a mouse model of pressure overload induced through transverse aortic constriction (TAC), Smad7 was upregulated in cardiac myofibroblasts. Mice with myofibroblast-specific loss of Smad7 (MFS7KO) had increased mortality, accentuated systolic dysfunction and dilative remodeling, and accelerated diastolic dysfunction in response to TAC. Increased dysfunction in MFS7KO hearts was associated with accentuated fibrosis and increased collagen denaturation, in the absence of effects on cardiomyocyte death. Secretomic analysis showed that Smad7 loss accentuates secretion of structural collagens and matricellular proteins, and markedly increases secretion of matrix metalloproteinase-2 (MMP2). In a 3D model of fibroblasts populating collagen lattices the effects of Smad7 on fibroblast-induced collagen denaturation and pad contraction were partly mediated via MMP2 downregulation. Surprisingly, MFS7KO mice also exhibited significant macrophage expansion caused by paracrine actions of Smad7 null fibroblasts that stimulate macrophage proliferation and fibrogenic activation. Secretomic analysis and in vitro experiments suggested that macrophage activation involves the combined effects of the fibroblast-derived matricellular proteins CD5L, SPARC, CTGF, ECM1 and TGFBI. Conclusions: The anti-fibrotic effects of Smad7 in the pressure-overloaded heart protect from dysfunction and involve not only reduction in collagen deposition, but also suppression of MMP2-mediated matrix denaturation and paracrine effects that suppress macrophage activation through inhibition of matricellular proteins.

Project description:When monocyte-derived macrophages are recruited to injured tissues, they can induce a maladaptive fibrotic response characterized by excessive production of fibrillar collagen from local fibroblasts. Macrophages initiate the fibrotic programming of fibroblasts via paracrine factors, but it is unclear if reciprocal responses from the fibroblasts trigger pro-fibrotic programming of macrophages to establish a collaborative feed-forward fibrotic circuit. We identify macrophage-fibroblast cross talk necessary for injury-associated fibrosis, in which macrophages induce interleukin 6 (IL-6) expression in fibroblasts via purinergic receptor P2rx4 signaling and IL-6 induces arginase 1 (Arg1) expression in macrophages. Surprisingly, Arg1 contributes to fibrotic responses by metabolizing arginine to ornithine, which fibroblasts use as a substrate to synthesize proline, a uniquely abundant constituent of fibrillar collagen Taken together, we define a bidirectional circuit between macrophages and fibroblasts that facilitates cross-feeding metabolism necessary for injury-associated fibrosis.

Project description:Rationale: Expansion and activation of cardiac fibroblasts contributes to adverse remodeling, fibrosis and dysfunction in the pressure-overloaded heart. Although early fibroblast TGF-β/Smad3 activation protects the pressure overloaded heart by preserving the matrix, sustained TGF-β activation may be deleterious, accentuating fibrosis and dysfunction. Thus, endogenous mechanisms that negatively regulate the TGF- response in fibroblasts may be required to protect from progressive fibrosis and adverse remodeling. Objective: To study the role of fibroblast-specific induction of Smad7, an inhibitory Smad that restrains TGF-β signaling, in regulation of fibrosis, remodeling and dysfunction of the pressure-overloaded heart. Methods and Results: In a mouse model of pressure overload induced through transverse aortic constriction (TAC), Smad7 was upregulated in cardiac fibroblasts and myofibroblasts. Mice with myofibroblast-specific loss of Smad7 (MFS7KO) had increased mortality, accentuated systolic dysfunction and dilative remodeling, and accelerated diastolic dysfunction in response to TAC. Increased dysfunction in MFS7KO hearts was associated with accentuated fibrosis and increased collagen denaturation, in the absence of effects on cardiomyocyte death. Secretomic analysis showed that Smad7 loss accentuates secretion of structural collagens and matricellular proteins, and markedly increases secretion of matrix metalloproteinase-2 (MMP2). In a 3D model of fibroblasts populating collagen lattices the effects of Smad7 on fibroblast-induced collagen denaturation and pad contraction were partly mediated via MMP2 downregulation. Surprisingly, MFS7KO mice also exhibited significant macrophage expansion caused by paracrine actions of Smad7 null fibroblasts that stimulate macrophage proliferation and fibrogenic activation. Secretomic analysis and in vitro experiments suggested that macrophage activation involves the combined effects of the fibroblast-derived matricellular proteins CD5L, SPARC, CTGF, ECM1 and TGFBI. Conclusions: The anti-fibrotic effects of Smad7 in the pressure-overloaded heart protect from dysfunction and involve not only reduction in collagen deposition, but also suppression of MMP2-mediated matrix denaturation and paracrine effects that suppress macrophage activation through inhibition of matricellular proteins.

Project description:The association between kidney stone disease and renal fibrosis has been widely explored in recent years but its underlying mechanisms remain far from complete understanding. Using label-free quantitative proteomics (nanoLC-ESI-LTQ-Orbitrap MS/MS), this study identified 23 significantly altered secreted proteins from calcium oxalate monohydrate (COM)-exposed macrophages (COM-MP) compared with control macrophages (Ctrl-MP) secretome. Functional annotation and protein-protein interactions network analysis revealed that these altered secreted proteins were involved mainly in inflammatory response and fibroblast activation. BHK-21 renal fibroblasts treated with COM-MP secretome had more spindle-shaped morphology with greater spindle index. Immunofluorescence study and gelatin zymography revealed increased levels of fibroblast activation markers (α-smooth muscle actin and F-actin) and fibrotic factors (fibronectin and matrix metalloproteinase-9 and -2) in the COM-MP secretome-treated fibroblasts. Our findings indicate that proteins secreted from macrophages exposed to COM crystals induce renal fibroblast activation and may play important roles in renal fibrogenesis in kidney stone disease.

Project description:Single-cell RNA sequencing (scRNA-seq) was performed to investigate fibroblast–myeloid cell crosstalk in lung fibrosis. The dataset includes murine lung macrophage–fibroblast cocultures or fibroblast monocultures, with macrophages derived from WT mice and fibroblasts from either WT or fibroblast-specific P2rx4 knockout (Pdgfrb-Cre: P2rx4 f/f) mice 7 days after bleomycin injury. Cells were captured using the Fluent Biosciences PIPseq platform. Data include gene–cell count matrices and support the study “Myeloid–mesenchymal crosstalk drives ARG1-dependent profibrotic metabolism via ornithine in lung fibrosis” (Yadav et al., 2025).

Project description:Idiopathic pulmonary fibrosis (IPF) is the prototypic progressive fibrotic lung disease with a median survival of 2-4 years. Injury to and/or dysfunction of alveolar epithelium are strongly implicated in IPF disease initiation, but what factors determine why fibrosis progresses rather than normal tissue repair occurs remain poorly understood. We previously demonstrated that ZEB1-mediated epithelial-mesenchymal transition (EMT) in human alveolar epithelial type II (ATII) cells augments TGF-β-induced profibrogenic responses in underlying lung fibroblasts by paracrine signalling. Here we investigated bi-directional epithelial-mesenchymal crosstalk and its potential to drive fibrosis progression. RNA sequencing (RNA-seq) of lung fibroblasts exposed to conditioned media from ATII cells undergoing RAS-induced EMT identified many differentially expressed genes including those involved in cell migration and extracellular matrix (ECM) regulation. We confirmed that paracrine signalling between AS-activated ATII cells and fibroblasts augmented fibroblast recruitment and demonstrated that this involved a ZEB1-tissue plasminogen activator (tPA) axis. In a reciprocal fashion, paracrine signalling from TGF-β-activated lung fibroblasts or IPF fibroblasts induced RAS activation in ATII cells, at least partially via the secreted protein, SPARC. Together these data identify that aberrant bi-directional epithelial-mesenchymal crosstalk in IPF drives a chronic feedback loop that maintains a wound-healing phenotype and provides self-sustaining pro-fibrotic signals.

Project description:In this model, we integrate in vitro observations of macrophage/fibroblasts in coculture with hypoxia and inflammatory signals. We obtain conditions under which the wound healing process progresses normally or becomes fibrotic.

Project description:Background: Aging is the greatest risk factor for breast cancer, and although epithelial cells are the source of carcinomas, epithelial changes alone do not fully explain cancer susceptibility. Fibroblasts and macrophages are key stromal constituents around the cells of origin for cancer in breast tissue. With age, macrophages surrounding terminal ductal lobular units (TDLUs) become increasingly immunosuppressive. CD105+ fibroblasts intercalate within TDLUs, drive luminal differentiation, and give rise to immunosuppressive cancer-associated fibroblasts in other tissues. We propose that differences in fibroblasts are a crucial component of the stroma that shapes cancer susceptibility. Methods: Primary fibroblast cultures were established from prophylactic and reduction mammoplasties from women ranging in age from 16 to 70 years and breast cancer risk (BRCA1 mutation carriers). Growth characteristics, transcriptional profiles, differentiation potential, and secreted proteins were profiled for fibroblast subtypes from diverse donors. Co-cultures with fibroblasts, monocytes, macrophages, and T cells were used to ascertain the functional role played by CD105+ fibroblasts in immune cell modulation. Results: We found that peri-epithelial CD105+ fibroblasts are enriched in older women as well as women who carry BRCA1 mutations. These CD105+ fibroblasts exhibit robust adipogenesis and secrete factors related to macrophage polarization. Macrophages cocultured with fibroblasts better maintain or enhance polarization states than media alone. CD105+ fibroblasts increased expression of immunosuppressive macrophage genes. CD105+ fibroblasts supported anti-inflammatory macrophage-mediated suppression of T cell proliferation, whereas CD105− fibroblasts significantly reduced the suppressive effect of anti-inflammatory macrophages on T cell proliferation. Conclusions: Establishment of a coculture system to dissect the molecular circuits between CD105+ fibroblasts and macrophages that drive immunosuppressive macrophage polarization has broad utility in understanding mammary gland development and events that precede cancer initiation. CD105+ fibroblasts and macrophages may coordinate to suppress immunosurveillance and increase breast cancer susceptibility.

Project description:Fibroblast to myofibroblast differentiation is crucial for the initial healing response but excessive myofibroblast activation leads to pathological fibrosis. Therefore, it is imperative to understand the mechanisms underlying myofibroblast formation. Here we report that mitochondrial calcium (mCa2+) signaling is a regulatory mechanism in myofibroblast differentiation and fibrosis. We demonstrate that inhibition of mCa2+ uptake in fibroblasts enhances myofibroblast formation and this translates to increased fibrosis following injury. Fibrotic signaling alters the gating of the mitochondrial calcium uniporter (mtCU) to reduce mCa2+ uptake and induce specific changes in metabolism. mCa2+-dependent metabolic reprogramming leads to the activation of αKG-dependent demethylases which epigenetically modify promoter regions specific to the myofibroblast gene program resulting in differentiation. Our results uncover an important role for mCa2+ uptake beyond metabolic regulation and cell death and demonstrate that mCa2+ signaling regulates the epigenome to influence cellular differentiation.