Project description:Fibrotic disease is caused by persistently activated fibroblasts, known as myofibroblasts, that continuously deposit extracellular matrix and fail to de-activate after injury resolution. There are currently no treatments for fibrotic disease; our study addresses the mechanisms whereby myofibroblasts persist in fibrotic tissues such as diseased cardiac valves. We exploit photo-softening hydrogels as synthetic valve tissue mimics and valve fibroblasts as a model to study how stiffness controls pathological myofibroblast activation and their persistence. We show that persistent myofibroblasts have condensed chromatin structure with genome-wide alterations and that this is associated with stabilization of the actin cytoskeleton. Disconnecting the nucleus from the cytoskeleton prevents chromatin condensation and myofibroblast persistence. Notably, myofibroblasts in patients with aortic valve stenosis display a condensed chromatin structure compared to myofibroblasts in a healthy patient, similar to the difference observed between cultured persistent myofibroblasts and transient myofibroblasts. Collectively, our results reveal that nuclear mechanosensing leads to distinct chromatin signatures in persistent myofibroblasts and that this novel cellular mechanism is likely relevant to human fibrotic disease.

Project description:To identify potential dysregulation of miRNA expression in plasmacytoid dendritic cells from Systemic Sclerosis patients (SSc), miRNA profiling was performed in pDCs from healthy donors or patients with the most severe fibrotic cutaneous form of SSc, namely in dcSSc, with either disease duration shorter (edcSSc) or longer than two years (ldcSSc). Plasmacytoid dendritic cells (pDCs) are a critical source of type I interferons (IFNs) that can contribute to the onset and maintenance of autoimmunity. Molecular mechanisms leading to pDC dysregulation and persistent type I IFN signature are largely unexplored, especially in systemic sclerosis (SSc), a disease in which pDCs infiltrate fibrotic skin lesions and produce higher levels of IFNa as compared to healthy controls. To investigate potential microRNA–mediated epigenetic mechanisms underlying pDC dysregulation and type I IFN production in SSc. microRNA expression profiling and validation was performed in highly purified pDCs obtained from the peripheral blood of 3 independent cohorts of healthy controls and SSc patients. Possible functions of miR-618 on pDC biology were identified by overexpression in healthy pDCs. miR-618 expression was upregulated in pDCs of SSc patients, including those in the early stage of disease onset and not presenting with skin fibrosis. IRF8, a crucial transcription factor for pDC development and activation, was identified as a target of miR-618. miR-618 overexpression reduced the development of pDCs from CD34+ cells in-vitro and enhanced their ability to secrete IFNα, mimicking the pDC phenotype observed in SSc patients. miR-618 upregulation suppresses pDC development and increases their ability to secrete IFNα, potentially contributing to the type I IFN signature observed in SSc patients. Considering the importance of pDCs in the pathogenesis of SSc and other diseases characterized by a type I IFN signature, miR-618 potentially represents an important epigenetic target to regulate immune system homeostasis in these conditions.

Project description:JAG1-NOTCH4 mechanosensing drives atherosclerosis

Project description:Systemic sclerosis (SSc) is an uncommon disease characterized by elevated autoantibody production, vasculopathy and fibrosis of the skin and internal organs. pDCs are the core cell type to produce type I IFN and contributes to the ISG signature and SSc progression. Using single-cell RNA sequencing, we profiled 32529 pDCs enriched and T cell depleted peripheral blood mononuclear cells (PBMCs) from 4 patients with SSc and 4 matched controls. Increased CD16+ monocytes and decreased cDCs are the major changes in the cell composition between SSc and heathy controls. Increased expression of interferon-stimulated genes (ISGs) and apoptotic genes distinguished cells from patients with SSc from healthy control cells. The high ISG expression signature (ISGhi) derived from a small number of transcriptionally defined subpopulations within major cell types, including monocytes, natural killer cells, conventional and plasmacytoid dendritic cells, B cells. Profiling of 10976 pDCs revealed a newly identified PTGDS+ population and a clear increased ISG hi clusters in SSc pDCs. Profiling of 13317 Monocytes revealed increased CD16+ Monocytes and a clear increased ISG hi clusters in SSc monocytes. We then compared the TLRs-IFN response of the pDCs from SSc and Healthy control. RNASeq revealed SSc pDCs enables an unexpected TLR8-IFN signaling to increase the IFN signature. This study lays the groundwork for resolving the origin of the SSc transcriptional signatures and the disease heterogeneity towards precision medicine applications.

Project description:Systemic sclerosis (SSc) is an uncommon disease characterized by elevated autoantibody production, vasculopathy and fibrosis of the skin and internal organs. pDCs are the core cell type to produce type I IFN and contributes to the ISG signature and SSc progression. Using single-cell RNA sequencing, we profiled 32529 pDCs enriched and T cell depleted peripheral blood mononuclear cells (PBMCs) from 4 patients with SSc and 4 matched controls. Increased CD16+ monocytes and decreased cDCs are the major changes in the cell composition between SSc and heathy controls. Increased expression of interferon-stimulated genes (ISGs) and apoptotic genes distinguished cells from patients with SSc from healthy control cells. The high ISG expression signature (ISGhi) derived from a small number of transcriptionally defined subpopulations within major cell types, including monocytes, natural killer cells, conventional and plasmacytoid dendritic cells, B cells. Profiling of 10976 pDCs revealed a newly identified PTGDS+ population and a clear increased ISG hi clusters in SSc pDCs. Profiling of 13317 Monocytes revealed increased CD16+ Monocytes and a clear increased ISG hi clusters in SSc monocytes. We then compared the TLRs-IFN response of the pDCs from SSc and Healthy control. RNASeq revealed SSc pDCs enables an unexpected TLR8-IFN signaling to increase the IFN signature. This study lays the groundwork for resolving the origin of the SSc transcriptional signatures and the disease heterogeneity towards precision medicine applications.

Project description:Phosphorylation of sarcomeric proteins has been implicated in heart failure with preserved ejection fraction (HFpEF); such changes may contribute to diastolic dysfunction by altering contractility, cardiac stiffness, Ca2+-sensitivity and mechanosensing. Treatment with cardiosphere-derived cells (CDCs) restores normal diastolic function, attenuates fibrosis and inflammation, and improves survival in a rat HFpEF model. Here, we quantified the phosphorylation changes that underlie HFpEF and those reversed by CDC therapy, with a focus on the sarcomeric subproteome.

Project description:Matrix stiffness is a central regulator of fibroblast function. However, the transcriptional mechanisms linking matrix stiffness to changes in fibroblast phenotype are incompletely understood. Here, we evaluated the effect of matrix stiffness on genome-wide chromatin accessibility in freshly-isolated lung fibroblasts using ATAC-seq. We found higher matrix stiffness profoundly increased global chromatin accessibility relative to lower matrix stiffness, and these alterations were in close genomic proximity to known pro-fibrotic gene programs. Motif analysis of these regulated genomic loci identified ZNF416 as a putative mediator of fibroblast stiffness responses. Genome occupancy analysis using ChIP-seq confirmed that ZNF416 occupies a broad range of genes implicated in fibroblast activation and tissue-fibrosis, with relatively little overlap in genomic occupancy with other mechanoresponsive and pro-fibrotic transcriptional regulators. Using loss and gain of function studies we demonstrated that ZNF416 plays a critical role in fibroblast proliferation, extracellular matrix synthesis and contractile function. Together these observations identify ZNF416 as novel mechano-activated transcriptional regulator of fibroblast biology.

Project description:Matrix stiffness is a central regulator of fibroblast function. However, the transcriptional mechanisms linking matrix stiffness to changes in fibroblast phenotype are incompletely understood. Here, we evaluated the effect of matrix stiffness on genome-wide chromatin accessibility in freshly-isolated lung fibroblasts using ATAC-seq. We found higher matrix stiffness profoundly increased global chromatin accessibility relative to lower matrix stiffness, and these alterations were in close genomic proximity to known pro-fibrotic gene programs. Motif analysis of these regulated genomic loci identified ZNF416 as a putative mediator of fibroblast stiffness responses. Genome occupancy analysis using ChIP-seq confirmed that ZNF416 occupies a broad range of genes implicated in fibroblast activation and tissue-fibrosis, with relatively little overlap in genomic occupancy with other mechanoresponsive and pro-fibrotic transcriptional regulators. Using loss and gain of function studies we demonstrated that ZNF416 plays a critical role in fibroblast proliferation, extracellular matrix synthesis and contractile function. Together these observations identify ZNF416 as novel mechano-activated transcriptional regulator of fibroblast biology.

Project description:Chemokines are chemotactic cytokines that control the migratory patterns and positioning of immune cells. Many chemokines have been associated with systemic autoimmune diseases that have chronic IFN signature. We now describe that a series of chemokines, including CXCL4, CXCL10, CXCL12 and CCL5, can superinduce type I IFN (IFN-I) by TLR9-activated plasmacytoid DCs (pDCs), independently of their respective known chemokine receptors. Mechanistically, we show that chemokines such as CXCL4 mediate transcriptional and epigenetic changes in pDCs, mostly targeted to the IFN-I pathways. We also describe that chemokines physically interact with DNA to form nanoparticles which promote clathrin-mediated cellular uptake and delivery of DNA in the early endosomes of pDCs. Using two mouse models of skin inflammation, we observed the presence of CXCL4 associated with DNA in vivo. These data thus reveal a non-canonical role for chemokines to modulate TLR signaling, and extend our understanding on the mechanism associated with the chronic expression of IFN-I by pDCs in autoimmune diseases.

Project description:Type I IFNs are critical in initiating protective antiviral immune responses and plasmacytoid DCs (pDCs) represent a major source of these cytokines. Here we show that only few pDCs are capable to produce IFN? after virus infection or CpG stimulation. Utilizing IFN?/YFP reporter mice, we identify these IFN?-producing cells in the spleen as a CCR9+CD9- pDC subset exclusively localized within the T/B cell zones. IFN?-producing pDCs exhibit a distinct transcriptome profile with higher expression of genes encoding cytokines and chemokines, facilitating T cell recruitment and activation. These distinctive characteristics of IFN?-producing pDCs are independent of the type I IFN receptor mediated feedback loop. Furthermore, IFN?-producing pDCs exhibit enhanced CCR7-dependent migratory properties in vitro and in a peritoneal inflammation model they effectively recruit T cells in vivo. We define “professional type I IFN-producing cells” as a distinct subset of pDCs specialized in coordinating cellular immune responses. IFN? associated gene expression in ex vivo sorted IFN?/YFPpos vs. IFN?/YFPneg splenic pDCs was measured at 6 hr after i.v. injection of CpG 1668 complexed to DOTAP. Two independent experiments were performed using pooled samples of at least 12 mice per experiment.