Project description:Pulmonary fibrosis (PF) represents a progressive interstitial lung disease marked by excessive extracellular matrix deposition and architectural distortion. Vascular endothelial cells (ECs) critically contribute to fibrogenesis through paracrine secretion of pro-fibrotic mediators, yet their mechanobiological regulation remains elusive. UsingThrough integrated single-cell multi-omics profiling of human PF specimens and experimental fibrosis models induced by bleomycin or silica (Bleomycin/SiO2-induced), we identify identified mechanosensitive Piezo1 upregulation in ECs as a hallmark of fibrotic progression. Endothelial-specific Piezo1 knockout significantly attenuates attenuated Bleomycin-induced fibrotic remodeling, establishing its pathogenic necessity. Mechanistically, Piezo1 activation promotes promoted PF development by inducing a pro-fibrotic molecule interleukin-33 (IL-33) secretion via CAPN2-mediated STAT3 phosphorylation. These findings suggest that the endothelial PIEZO1-CAPN2-STAT3-IL-33 axis is a promising therapeutic target for PF intervention.

Project description:Pulmonary fibrosis (PF) is a life-threatening condition characterised by excessive extracellular matrix deposition and tissue scarring. While much of PF research has focused on alveolar epithelial cells and fibroblasts, endothelial cells have emerged as active contributors to the disease initiation, especially in the context of systemic exposure to pro-fibrotic substances. Here, we investigate early transcriptomic and secretory responses of human umbilical vein endothelial cells (HUVEC) to subtoxic doses of bleomycin, a known pro-fibrotic agent, and TGF-beta, a key cytokine in fibrosis. Bleomycin exposure induced a rapid and extensive shift in the endothelial transcriptional programme, including signatures of endothelial to mesenchymal transition, cellular senescence, and immune cell recruitment. These findings suggest endothelial cells as early initiators of pro-fibrotic signals, independent of contributions from other cell types. In contrast, TGF-beta effects were limited and transient, indicating its pro-fibrotic action may require another initial stimulus and interplay with other cells like fibroblasts. This study highlights the sensitivity of endothelial cells to systemic pro-fibrotic exposure and provides a blueprint of early pro-fibrotic mechanisms, emphasising their pivotal role in PF pathogenesis.

Project description:Pulmonary fibrosis (PF) is a chronic interstitial lung disease that causes irreversible and progressive lung scarring and respiratory failure. Activation of fibroblasts (FBs) play a central role in progression of PF. Here we report that platelet endothelial aggregation receptor 1 (Pear1) in FBs is a new molecular target for PF therapy. Pear1 deficiency spontaneously caused respiratory function decline and alveolar collagens accumulation in old mice. The degree of PF and mortality induced by bleomycin were significantly enhanced in Pear1 deficient mice. FB Mesenchyme-specific Pear1 deficiency aggravated bleomycin-induced PF, confirming that Pear1 modulates PF progression probably byvia regulation of FBs function. Single cell RNA-seq analysis of pulmonary FB and functional enrichment analysis revealed drastic expansion of Aactivated- FB clusters and enrichment of activated FB marker genes in extracellular matrix (ECM) development and pulmonary fibrosis in Pear1-/- fibrotic lungs. CD140+ bulk tissue RNA-seq analysis further confirmed that multiple mesenchyme development pathways especially epithelial mesenchymal transition (EMT) are enriched with up-regulated genes involving FB mediated ECM organization and development in in Pear1-/- fibrotic lungs. We further found that Pear1 associated with Protein Phosphatase 1 to suppress fibrotic factors such as TGFß, FGF or PDGF-induced intracellular signalling and FB activation. Intratracheal aerosolization of monoclonal antibody activating Pear1 greatly ameliorates PF in both wild-type mice and Pear1-humanized mice, suggesting that targeting Pear1 may serve as a new therapeutic strategy for PF.

Project description:Pulmonary fibrosis (PF) is a chronic interstitial lung disease that causes irreversible and progressive lung scarring and respiratory failure. Activation of fibroblasts (FBs) play a central role in progression of PF. Here we report that platelet endothelial aggregation receptor 1 (Pear1) in FBs is a new molecular target for PF therapy. Pear1 deficiency spontaneously caused respiratory function decline and alveolar collagens accumulation in old mice. The degree of PF and mortality induced by bleomycin were significantly enhanced in Pear1 deficient mice. FB Mesenchyme-specific Pear1 deficiency aggravated bleomycin-induced PF, confirming that Pear1 modulates PF progression probably byvia regulation of FBs function. Single cell RNA-seq analysis of pulmonary FB and functional enrichment analysis revealed drastic expansion of Aactivated- FB clusters and enrichment of activated FB marker genes in extracellular matrix (ECM) development and pulmonary fibrosis in Pear1-/- fibrotic lungs. CD140+ bulk tissue RNA-seq analysis further confirmed that multiple mesenchyme development pathways especially epithelial mesenchymal transition (EMT) are enriched with up-regulated genes involving FB mediated ECM organization and development in in Pear1-/- fibrotic lungs. We further found that Pear1 associated with Protein Phosphatase 1 to suppress fibrotic factors such as TGFß, FGF or PDGF-induced intracellular signalling and FB activation. Intratracheal aerosolization of monoclonal antibody activating Pear1 greatly ameliorates PF in both wild-type mice and Pear1-humanized mice, suggesting that targeting Pear1 may serve as a new therapeutic strategy for PFand significantly improves their survival rate.

Project description:Pulmonary fibrosis (PF) is a pathology associated with interstitial lung diseases (ILDs), including idiopathic pulmonary fibrosis (IPF). Fibrosis promotes continual secretion of extracellular matrix (ECM), producing non-functional scar tissue and causing organ failure. This study investigated the tyrosine kinase receptor Ephrin type-B receptor 4 (EphB4) as a mediator of PF. To this end, we generated mice with conditional Col1a2-driven deletion of Ephb4 and used a preclinical mouse model of PF, total and single nuclei RNA (snRNA) sequencing, NanoString, previously published single cell data, computational analysis, and functional assays of mouse and human healthy control and IPF lung fibroblasts. Col1a2-CreERT-driven Ephb4 deletion, or EphB4 inhibition via NVP-BHG712, markedly protected against bleomycin-induced PF. Total RNA-sequencing of fibroblasts isolated from Ephb4-deficient fibrotic mouse lungs exhibited reduced expression of ECM, ER Cargo, and protein trafficking-related genes. NVP-BHG712 reduced expression of these identified genes in mouse lung fibroblasts under fibrotic conditions in vitro. SnRNA sequencing of mouse lungs treated with NVP-BHG712 identified transcriptomic changes of ECM genes in specific fibroblast subpopulations. RNA sequencing, computational, and functional assays using mouse and human IPF fibroblasts identified elastin as a key mediator involved in EphB4 signaling. Combined, our data show that EphB4 is a crucial mediator of PF.

Project description:Pulmonary fibrosis (PF) is a pathology associated with interstitial lung diseases (ILDs), including idiopathic pulmonary fibrosis (IPF). Fibrosis promotes continual secretion of extracellular matrix (ECM), producing non-functional scar tissue and causing organ failure. This study investigated the tyrosine kinase receptor Ephrin type-B receptor 4 (EphB4) as a mediator of PF. To this end, we generated mice with conditional Col1a2-driven deletion of Ephb4 and used a preclinical mouse model of PF, total and single nuclei RNA (snRNA) sequencing, NanoString, previously published single cell data, computational analysis, and functional assays of mouse and human healthy control and IPF lung fibroblasts. Col1a2-CreERT-driven Ephb4 deletion, or EphB4 inhibition via NVP-BHG712, markedly protected against bleomycin-induced PF. Total RNA-sequencing of fibroblasts isolated from Ephb4-deficient fibrotic mouse lungs exhibited reduced expression of ECM, ER Cargo, and protein trafficking-related genes. NVP-BHG712 reduced expression of these identified genes in mouse lung fibroblasts under fibrotic conditions in vitro. SnRNA sequencing of mouse lungs treated with NVP-BHG712 identified transcriptomic changes of ECM genes in specific fibroblast subpopulations. RNA sequencing, computational, and functional assays using mouse and human IPF fibroblasts identified elastin as a key mediator involved in EphB4 signaling. Combined, our data show that EphB4 is a crucial mediator of PF.

Project description:Pulmonary fibrosis (PF) is a pathology associated with interstitial lung diseases (ILDs), including idiopathic pulmonary fibrosis (IPF). Fibrosis promotes continual secretion of extracellular matrix (ECM), producing non-functional scar tissue and causing organ failure. This study investigated the tyrosine kinase receptor Ephrin type-B receptor 4 (EphB4) as a mediator of PF. To this end, we generated mice with conditional Col1a2-driven deletion of Ephb4 and used a preclinical mouse model of PF, total and single nuclei RNA (snRNA) sequencing, NanoString, previously published single cell data, computational analysis, and functional assays of mouse and human healthy control and IPF lung fibroblasts. Col1a2-CreERT-driven Ephb4 deletion, or EphB4 inhibition via NVP-BHG712, markedly protected against bleomycin-induced PF. Total RNA-sequencing of fibroblasts isolated from Ephb4-deficient fibrotic mouse lungs exhibited reduced expression of ECM, ER Cargo, and protein trafficking-related genes. NVP-BHG712 reduced expression of these identified genes in mouse lung fibroblasts under fibrotic conditions in vitro. SnRNA sequencing of mouse lungs treated with NVP-BHG712 identified transcriptomic changes of ECM genes in specific fibroblast subpopulations. RNA sequencing, computational, and functional assays using mouse and human IPF fibroblasts identified elastin as a key mediator involved in EphB4 signaling. Combined, our data show that EphB4 is a crucial mediator of PF.

Project description:Tyrosine kinase inhibitors (TKIs) have improved cancer outcomes but are limited by cardiovascular toxicity, most notably hypertension and heart failure. The underlying mechanisms remain poorly understood, hindering the development of protective strategies. Here, we investigated the role of endothelial mechanotransduction in mediating vascular and cardiac injury caused by the VEGFR-targeting TKI sunitinib. Using patient-specific induced pluripotent stem cell-derived endothelial cells (iPSC-ECs) and a mouse model of TKI-induced hypertension, we identified downregulation of PIEZO1, a mechanically activated ion channel, as a central driver of endothelial dysfunction. Restoring PIEZO1 expression, either pharmacologically with Yoda1, a selective agonist, or through inducible overexpression in iPSC-ECs, reversed sunitinib-induced endothelial dysfunction and mitigated its hypertensive effects, providing both mechanistic and genetic validation of PIEZO1’s protective role against vascular toxicity. In mice, Yoda1 co-treatment prevented the long-term cardiac dysfunction observed following sunitinib exposure, and normalized elevations in circulating cardiac stress biomarkers. Single-nuclei multiomic profiling of mouse hearts revealed that sunitinib exposure activated chromatin remodeling and fibrogenic programs, which were reversed with PIEZO1 activation. Human engineered cardiac organoids further demonstrated that sunitinib impaired cardiomyocyte function only in the presence of endothelial cells, confirming a role for disrupted endothelial-cardiomyocyte crosstalk in TKI cardiotoxicity. Together, these findings identify endothelial PIEZO1 as a critical mediator of TKI-induced hypertension and cardiac dysfunction and highlight PIEZO1 activation as a potential therapeutic strategy for protecting cardiovascular health during cancer therapy.

Project description:Tyrosine kinase inhibitors (TKIs) have improved cancer outcomes but are limited by cardiovascular toxicity, most notably hypertension and heart failure. The underlying mechanisms remain poorly understood, hindering the development of protective strategies. Here, we investigated the role of endothelial mechanotransduction in mediating vascular and cardiac injury caused by the VEGFR-targeting TKI sunitinib. Using patient-specific induced pluripotent stem cell-derived endothelial cells (iPSC-ECs) and a mouse model of TKI-induced hypertension, we identified downregulation of PIEZO1, a mechanically activated ion channel, as a central driver of endothelial dysfunction. Restoring PIEZO1 expression, either pharmacologically with Yoda1, a selective agonist, or through inducible overexpression in iPSC-ECs, reversed sunitinib-induced endothelial dysfunction and mitigated its hypertensive effects, providing both mechanistic and genetic validation of PIEZO1’s protective role against vascular toxicity. In mice, Yoda1 co-treatment prevented the long-term cardiac dysfunction observed following sunitinib exposure, and normalized elevations in circulating cardiac stress biomarkers. Single-nuclei multiomic profiling of mouse hearts revealed that sunitinib exposure activated chromatin remodeling and fibrogenic programs, which were reversed with PIEZO1 activation. Human engineered cardiac organoids further demonstrated that sunitinib impaired cardiomyocyte function only in the presence of endothelial cells, confirming a role for disrupted endothelial-cardiomyocyte crosstalk in TKI cardiotoxicity. Together, these findings identify endothelial PIEZO1 as a critical mediator of TKI-induced hypertension and cardiac dysfunction and highlight PIEZO1 activation as a potential therapeutic strategy for protecting cardiovascular health during cancer therapy.

Project description:Tyrosine kinase inhibitors (TKIs) have improved cancer outcomes but are limited by cardiovascular toxicity, most notably hypertension and heart failure. The underlying mechanisms remain poorly understood, hindering the development of protective strategies. Here, we investigated the role of endothelial mechanotransduction in mediating vascular and cardiac injury caused by the VEGFR-targeting TKI sunitinib. Using patient-specific induced pluripotent stem cell-derived endothelial cells (iPSC-ECs) and a mouse model of TKI-induced hypertension, we identified downregulation of PIEZO1, a mechanically activated ion channel, as a central driver of endothelial dysfunction. Restoring PIEZO1 expression, either pharmacologically with Yoda1, a selective agonist, or through inducible overexpression in iPSC-ECs, reversed sunitinib-induced endothelial dysfunction and mitigated its hypertensive effects, providing both mechanistic and genetic validation of PIEZO1’s protective role against vascular toxicity. In mice, Yoda1 co-treatment prevented the long-term cardiac dysfunction observed following sunitinib exposure, and normalized elevations in circulating cardiac stress biomarkers. Single-nuclei multiomic profiling of mouse hearts revealed that sunitinib exposure activated chromatin remodeling and fibrogenic programs, which were reversed with PIEZO1 activation. Human engineered cardiac organoids further demonstrated that sunitinib impaired cardiomyocyte function only in the presence of endothelial cells, confirming a role for disrupted endothelial-cardiomyocyte crosstalk in TKI cardiotoxicity. Together, these findings identify endothelial PIEZO1 as a critical mediator of TKI-induced hypertension and cardiac dysfunction and highlight PIEZO1 activation as a potential therapeutic strategy for protecting cardiovascular health during cancer therapy.