Project description:Fibrosis is a common pathology in cardiovascular disease. In the heart, fibrosis causes mechanical and electrical dysfunction and in the kidney, it predicts the onset of renal failure. Transforming growth factor β1 (TGFβ1) is the principal pro-fibrotic factor, but its inhibition is associated with side effects due to its pleiotropic roles. We hypothesized that downstream effectors of TGFβ1 in fibroblasts could be attractive therapeutic targets and lack upstream toxicity. Here we show, using integrated imaging–genomics analyses of primary human fibroblasts, that upregulation of interleukin-11 (IL-11) is the dominant transcriptional response to TGFβ1 exposure and required for its pro-fibrotic effect. IL-11 and its receptor (IL11RA) are expressed specifically in fibroblasts, in which they drive non-canonical, ERK-dependent autocrine signaling that is required for fibrogenic protein synthesis. In mice, fibroblast-specific Il11 transgene expression or Il-11 injection causes heart and kidney fibrosis and organ failure, whereas genetic deletion of Il11ra1 protects against disease. Therefore, inhibition of IL-11 prevents fibroblast activation across organs and species in response to a range of important pro-fibrotic stimuli. These results reveal a central role of IL-11 in fibrosis and we propose that inhibition of IL-11 is a potential therapeutic strategy to treat fibrotic diseases.

Project description:Aims and introduction: Cardiac fibrosis is the hallmark of cardiac disease, particularly myocardial infarction (MI), and is one of the most prevalent causes of heart failure. MI is intricately linked to inflammation, extracellular matrix (ECM) remodelling, and cardiac fibrosis, however the mechanisms underpinning these events remain poorly understood. We recently identified that ECM1 has potential to play a key role in cardiac wound healing but the cellular origins in the heart and specific mechanisms of ECM1 in fibrosis remain elusive. Therefore, we investigated the spatiotemporal, cell specific, expression profile of ECM1 in the healthy and diseased mouse and human heart and investigate ECM1 dependent human cardiac fibroblast (HuCFb) cell signalling mechanisms. Methods and results: Western blotting, immunohistochemistry (IHC) and mRNA in-situ hybridisation revealed that ECM1 protein expression was significantly upregulated in human ischaemic and dilated heart failure patients, and predominantly localised interstitially to fibrotic, inflammatory, and peri-vascular areas. ECM1 specific analysis of the Litviňuková et al. (2020) single-cell and -nuclei RNA sequencing (sc/snRNAseq) dataset of healthy human hearts, and the Farbehi et al. (2019) scRNAseq dataset of mouse hearts post-MI demonstrated that ECM1 expression originates from fibroblasts, macrophages, and pericytes/vascular mural cells in the heart. Further, we identify that post-MI ECM1 is expressed in a temporal dynamic flux from unactivated fibroblasts in sham-operated mice, to M1 macrophages (M1MΦ) at day-3, and myofibroblasts and M2MΦ at day-7. Phosphoproteomics of ECM1 treated human cardiac fibroblast cells (HuCFb) alongside ECM1 to HuCFb cell surface protein binding pull-down and mass spectrometry, revealed that ECM1 signalling goes via proteins associated with Rho protein signal transduction, cell-cell adhesion, microtubule dynamics, and cell chemotaxis pathways, potentially initiated by ECM1 to CTNND1 binding on the cell surface. Further mechanistic analyses identified that ECM1 inhibits HuCFb cell migration and stimulates inflammatory (IL-6 and IL-1β mRNA expression), fibrotic (TGF-β1, TGF-β2 and Col1a2 mRNA expression), and non-canonical Wnt signalling pathways (Wnt5a mRNA expression and JNK1/2/3 and MYPT1 phosphorylation). Conclusions: This study demonstrates that ECM1 expression originates from macrophages and fibroblasts in the mouse and human heart. ECM1 has significant effects on HuCFb migration, inflammatory, fibrotic, Rho protein, and Wnt5a/non-canonical Wnt signalling pathways. Together, ECM1 plays an important role in cardiac wound healing and may represent a novel mechanism of inflammation-fibrosis crosstalk and progression post-MI.

Project description:Rationale: Myocardial fibrosis manifests progressively in several forms of cardiomyopathies. Although fibrosis depicts a reparative mechanism, maladaptation of the heart due to excessive production of extracellular matrix accelerates cardiac dysfunction. Objective: The anthraquinone Rhein, a compound from rhubarb, was examined for its anti-fibrotic potency to mitigate cardiac fibroblast-to-myofibroblast transition (FMT). Methods and Results: Primary human ventricular cardiac fibroblasts were subjected to hypoxia and characterized with proteomics, transcriptomics and cell functional techniques. Knowledge based analyses of the omics data revealed a modulation of fibrosis-associated pathways and cell cycle due to Rhein administration, whereas p53 and p21 were identified as upstream regulators involved in the manifestation of cardiac fibroblast phenotypes. Mechanistically, Rhein-mediated cellular effects were linked to the histone deacetylase (HDAC)-dependent acetylation status of p53 a posttranslational modification that acts protein stabilizing. Direct enzymatic testing revealed an inhibitory potency of Rhein for HDAC classes I/II. Functionally, Rhein inhibited collagen contraction in response to protein abundance of SMAD7, endogenous inhibitor of TGFβ1 action, thus demonstrating its anti-fibrotic property in cardiac remodeling. Conclusion: In conclusion, this study identifies Rhein as a novel potent HDAC inhibitor and provides evidence that Rhein may contribute to the treatment of cardiac fibrosis as anti-fibrotic agent. As readily available drug with approved safety, Rhein constitutes a promising potential therapeutic approach in the supplemental and protective intervention of cardiac fibrosis.

Project description:Cardiac fibrosis is a pathophysiologic hallmark of the aging heart. In the uninjured heart, cardiac fibroblasts exist in the quiescent state, but little is known about how proliferation rates and fibroblast transcriptional programs change throughout the lifespan of the organism from the immediate postnatal period to adult life and old age. Using EdU pulse labeling, we demonstrate that more than 50% of cardiac fibroblasts are actively proliferating in the first day of post-natal life. However, within 4 weeks of birth in the juvenile animal, only 10% of cardiac fibroblasts are proliferating. By early adulthood, the fraction of proliferating cardiac fibroblasts further decreases to approximately 2%, where it so remains throughout the rest of the organism’s life span. Examination of absolute cardiac fibroblast numbers demonstrated concordance with age related changes in fibroblast proliferation with no significant differences in absolute cardiac fibroblast numbers between animals 14 weeks and 1.5 years of age. We demonstrate that the maximal changes in cardiac fibroblast transcriptional programs and in particular collagen expression occur within the first weeks of life from the immediate postnatal to the juvenile period. We show that even though the aging heart exhibits an increase in the total amount of accumulated collagen, transcription of various collagens and ECM genes both in the heart and cardiac fibroblast is maximal in the newly born and juvenile animal and decreases with organismal aging. Examination of DNA methylation changes both in the heart and in cardiac fibroblasts did not demonstrate significant changes in differentially methylated regions between young and old mice. Our observations demonstrate that cardiac fibroblasts attain a stable proliferation rate and transcriptional program early in the life span of the organism and suggest a model of cardiac aging where phenotypic changes in the aging heart are not directly attributable to changes in proliferation rate or altered collagen expression in cardiac fibroblasts.

Project description:Although fibrosis depicts a reparative mechanism, maladaptation of the heart due to excessive production of extracellular matrix accelerates cardiac dysfunction. The anthraquinone Rhein was examined for its anti-fibrotic potency to mitigate cardiac fibroblast-to-myofibroblast transition (FMT). Primary human ventricular cardiac fibroblasts were subjected to hypoxia and characterized with proteomics, transcriptomics and cell functional techniques. Knowledge based analyses of the omics data revealed a modulation of fibrosis-associated pathways and cell cycle due to Rhein administration during hypoxia, whereas p53 and p21 were identified as upstream regulators involved in the manifestation of cardiac fibroblast phenotypes. Mechanistically, Rhein-mediated cellular effects were linked to the histone deacetylase (HDAC)-dependent acetylation status of p53 a posttranslational modification that acts protein stabilizing. Direct enzymatic testing revealed an inhibitory potency of Rhein for HDAC classes I/II. Functionally, Rhein inhibited collagen contraction in response to protein abundance of SMAD7, thus demonstrating its anti-fibrotic property in cardiac remodeling. In conclusion, this study identifies Rhein as a novel potent HDAC inhibitor and provides evidence that Rhein may contribute to the treatment of cardiac fibrosis as anti-fibrotic agent. As readily available drug with approved safety, repurposing of Rhein constitutes a promising potential therapeutic approach in the supplemental and protective intervention of cardiac fibrosis.

Project description:Cardiac fibroblasts have a central role during the ventricular remodeling process associated to different types of cardiac injury. Recent studies have shown that fibroblasts do not respond homogeneously to heart damage, suggesting that the adult myocardium may contain specialized fibroblast subgroups with specific functions. Due to the limited set of bona fide fibroblast markers, a proper characterization of fibroblast population dynamics in response to cardiac damage is still missing. Using single cell RNA-seq we have identified and characterized a fibroblast subpopulation that emerges in response to myocardial infarction (MI) in a murine model. These activated fibroblasts exhibit a clear pro-fibrotic signature, express high levels of the hormone CTHRC1 and of the immunomodulatory co-receptor CD200, and localize to the wounded myocardium. Combining epigenomic profiling with functional assays, we unveil important candidate regulators mediating their response to cardiac damage. We show that the absence of CTHRC1, a top marker of this activated fibroblast subpopulation, results in pronounced lethality due to ventricular rupture within the first week post-myocardial infarction. Finally, we find evidence for the existence of similar mechanisms in a pig pre-clinical model of MI and establish a positive correlation between Cthrc1 levels and cardiac function after MI.

Project description:Cardiac fibroblasts have a central role during the ventricular remodeling process associated to different types of cardiac injury. Recent studies have shown that fibroblasts do not respond homogeneously to heart damage, suggesting that the adult myocardium may contain specialized fibroblast subgroups with specific functions. Due to the limited set of bona fide fibroblast markers, a proper characterization of fibroblast population dynamics in response to cardiac damage is still missing. Using single cell RNA-seq we have identified and characterized a fibroblast subpopulation that emerges in response to myocardial infarction (MI) in a murine model. These activated fibroblasts exhibit a clear pro-fibrotic signature, express high levels of the hormone CTHRC1 and of the immunomodulatory co-receptor CD200, and localize to the wounded myocardium. Combining epigenomic profiling with functional assays, we unveil important candidate regulators mediating their response to cardiac damage. We show that the absence of CTHRC1, a top marker of this activated fibroblast subpopulation, results in pronounced lethality due to ventricular rupture within the first week post-myocardial infarction. Finally, we find evidence for the existence of similar mechanisms in a pig pre-clinical model of MI and establish a positive correlation between Cthrc1 levels and cardiac function after MI.

Project description:Cardiac fibroblasts have a central role during the ventricular remodeling process associated to different types of cardiac injury. Recent studies have shown that fibroblasts do not respond homogeneously to heart damage, suggesting that the adult myocardium may contain specialized fibroblast subgroups with specific functions. Due to the limited set of bona fide fibroblast markers, a proper characterization of fibroblast population dynamics in response to cardiac damage is still missing. Using single cell RNA-seq we have identified and characterized a fibroblast subpopulation that emerges in response to myocardial infarction (MI) in a murine model. These activated fibroblasts exhibit a clear pro-fibrotic signature, express high levels of the hormone CTHRC1 and of the immunomodulatory co-receptor CD200, and localize to the wounded myocardium. Combining epigenomic profiling with functional assays, we unveil important candidate regulators mediating their response to cardiac damage. We show that the absence of CTHRC1, a top marker of this activated fibroblast subpopulation, results in pronounced lethality due to ventricular rupture within the first week post-myocardial infarction. Finally, we find evidence for the existence of similar mechanisms in a pig pre-clinical model of MI and establish a positive correlation between Cthrc1 levels and cardiac function after MI.

Project description:In diseased organs, stress-activated signaling cascades alter chromatin, triggering maladaptive cell state transitions. Fibroblast activation is a common tissue stress response that worsens lung, liver, kidney and heart disease, yet its mechanistic basis remains obscure. Pharmacologic BET inhibition alleviates cardiac dysfunction, providing a tool to interrogate and modulate cardiac cell states as a potential therapeutic approach. Here, we leverage single-cell epigenomic interrogation of hearts dynamically exposed to BET inhibitors to reveal a reversible transcriptional switch underlying fibroblast activation. Resident cardiac fibroblasts demonstrated robust toggling between the quiescent and activated state in a manner directly correlating with BET inhibitor exposure and cardiac function. Single-cell chromatin accessibility revealed novel DNA elements whose accessibility dynamically correlated with cardiac performance. Among the most dynamic elements was an enhancer regulating the transcription factor MEOX1, which was specifically expressed in activated fibroblasts, occupied putative regulatory elements of a broad fibrotic gene program, and was required for TGFβ-induced fibroblast activation. Selective CRISPR inhibition of the single most dynamic cis-element within the enhancer blocked TGFβ-induced Meox1 activation. We identify MEOX1 as a central regulator of fibroblast activation associated with cardiac dysfunction, and also demonstrate its upregulation upon activation of human lung, liver and kidney fibroblasts. The plasticity and specificity of BET-dependent regulation of MEOX1 in tissue fibroblasts provide new trans- and cis- targets for treating fibrotic disease.

Project description:Contrary to mammals, zebrafish regenerate their heart upon cryoinjury of the cardiac ventricular apex. Regeneration is preceed by a fibrotic response. To understand the contribution of different cell sources to zebrafish cardiac fibrosis we performed an RNASeq including endocardial kdrl:mCherry cells from an uninjured heart, and activated endocardial kdrl:mCherry cells, postnb:citrine fibroblasts and the rest of the cells at 7 days post injury.