Project description:The role of pathological vascular degeneration in cirrhosis remains poorly understood. In this study, we engineered multidimensional vascular models to replicate the pathological characteristics of liver sinusoidal endothelial cells (LSECs) at various fibrosis stages. Our investigation revealed that LSEC response to hydrostatic pressure is matrix stiffness-dependent, with LSECs survival when cultured on soft matrices, while those cultured on hard matrices experiencing cellular damage. The biomimic vascular in vitro model enabled us to identify GPR116 as a crucial membrane receptor of LSECs to sense and respond to hydrostatic pressure. GPR116 is specifically expressed in liver endothelial cells, and silencing GPR116 effectively protected the endothelial cells from hydrostatic pressure-induced damage on hard matrix, consequently inhibiting hepatic stellate cell activation and collagen remodeling. Thus, our findings highlight GPR116 as an indispensable pressure sensor in hepatic sinusoidal endothelium, playing a pivotal role in vascular remodeling during cirrhosis.

Project description:The role of pathological vascular degeneration in cirrhosis remains poorly understood. In this study, we engineered multidimensional vascular models to replicate the pathological characteristics of liver sinusoidal endothelial cells (LSECs) at various fibrosis stages. Our investigation revealed that LSEC response to hydrostatic pressure is matrix stiffness-dependent, with LSECs survival when cultured on soft matrices, while those cultured on hard matrices experiencing cellular damage. The biomimic vascular in vitro model enabled us to identify GPR116 as a crucial membrane receptor of LSECs to sense and respond to hydrostatic pressure. GPR116 is specifically expressed in liver endothelial cells, and silencing GPR116 effectively protected the endothelial cells from hydrostatic pressure-induced damage on hard matrix, consequently inhibiting hepatic stellate cell activation and collagen remodeling. Thus, our findings highlight GPR116 as an indispensable pressure sensor in hepatic sinusoidal endothelium, playing a pivotal role in vascular remodeling during cirrhosis.

Project description:The role of pathological vascular degeneration in cirrhosis remains poorly understood. In this study, we engineered multidimensional vascular models to replicate the pathological characteristics of liver sinusoidal endothelial cells (LSECs) at various fibrosis stages. Our investigation revealed that LSEC response to hydrostatic pressure is matrix stiffness-dependent, with LSECs survival when cultured on soft matrices, while those cultured on hard matrices experiencing cellular damage. The biomimic vascular in vitro model enabled us to identify GPR116 as a crucial membrane receptor of LSECs to sense and respond to hydrostatic pressure. GPR116 is specifically expressed in liver endothelial cells, and silencing GPR116 effectively protected the endothelial cells from hydrostatic pressure-induced damage on hard matrix, consequently inhibiting hepatic stellate cell activation and collagen remodeling. Thus, our findings highlight GPR116 as an indispensable pressure sensor in hepatic sinusoidal endothelium, playing a pivotal role in vascular remodeling during cirrhosis.

Project description:Abstract: Background and aims: Portal hypertension (PH) is the most frequent and severe clinical syndrome associated to chronic liver disease (CLD), defined by a pathological increase in the hepatic venous pressure gradient (HVPG). Considering the known mechanobiological effects of hydrostatic pressure and shear stress on endothelial cells, we hypothesized that PH could not only be a consequence of, but significantly influence the phenotype of liver sinusoidal endothelial cells (LSECs) during disease progression. The aim of this study was to investigate the effects of pathological hydrodynamic pressure on LSECs and to identify endothelial-derived biomarkers of PH. Methods: Primary LSECs were cultured under normal or increased hydrodynamic pressure within a pathophysiological range (1 vs 12 mmHg) using a microfluidic liver-on-a-chip device. RNAseq was used to identify pressure-sensitive genes, which were validated in liver biopsies from two independent cohorts of CLD patients with PH (n=73) vs subjects without PH (n=23). Biomarker discovery was performed in plasma from a third independent cohort of 64 patients (46 with PH vs 18 w/o). Results: Transcriptomic analysis revealed a marked deleterious effect of pathological pressure in LSECs and identified chromobox 7 (CBX7) as a key transcription factor diminished by pressure. Hepatic CBX7 downregulation was validated in patients with PH and significantly correlated with HVPG. MicroRNA 181a-5p was identified as pressure-induced upstream regulator of CBX7. Analysis of two downstream targets of CBX7, ECAD and SPINK1, were found increased in the bloodstream of patients with PH and were highly predictive of PH and clinically significant PH, with a sensitivity of 91.3% and 91.4% respectively. Conclusions: We describe the detrimental effects of increased hydrodynamic pressure on the sinusoidal endothelium, identify CBX7 as a pressure-sensitive transcription factor, and propose that the combination of two of its reported products could be used as plasma biomarkers of PH.

Project description:In human F8 deficiency leads to hemophilia A and is largely synthesized and secreted by the sinusoidal endothelial cells of the liver (LSECs). However, the specificity and characteristics of these cells is not well known. In this study, we performed genome wide expression and CpG methylation profiling of fetal and adult human LSECs together with other fetal endothelial cells, from lung (micro-vascular and arterial), and heart (micro-vascular). Our results reveal plenty of expression and methylation markers distinguishing LSECs at both fetal and adult stages. Differential gene expression of fetal LSECs in comparison to other fetal endothelial cells pointed to several differential regulated pathways and functions in fetal LSECs. We used targeted bisulfite re-sequencing to confirm selected top differentially methylated regions. We further designed an assay where we used the selected methylation markers to test the degree of similarity of in house iPSs generated vascular endothelial cells to fetal and adult LSECs; a higher similarity was found to the fetal than to adult LSECs. Our molecular profiling study provides a guide to test the effectiveness of production of in vitro differentiated LSECs that could be used in cellular therapies. In-silico analysis to identify molecular signature of liver sinusoidal endothelial cells in comparison to other endohtelial cells

Project description:In human F8 deficiency leads to hemophilia A and is largely synthesized and secreted by the sinusoidal endothelial cells of the liver (LSECs). However, the specificity and characteristics of these cells is not well known. In this study, we performed genome wide expression and CpG methylation profiling of fetal and adult human LSECs together with other fetal endothelial cells, from lung (micro-vascular and arterial), and heart (micro-vascular). Our results reveal plenty of expression and methylation markers distinguishing LSECs at both fetal and adult stages. Differential gene expression of fetal LSECs in comparison to other fetal endothelial cells pointed to several differential regulated pathways and functions in fetal LSECs. We used targeted bisulfite re-sequencing to confirm selected top differentially methylated regions. We further designed an assay where we used the selected methylation markers to test the degree of similarity of in house iPSs generated vascular endothelial cells to fetal and adult LSECs; a higher similarity was found to the fetal than to adult LSECs. Our molecular profiling study provides a guide to test the effectiveness of production of in vitro differentiated LSECs that could be used in cellular therapies. In-silico analysis to identify molecular signature of liver sinusoidal endothelial cells in comparison to other endohtelial cells

Project description:In human F8 deficiency leads to hemophilia A and is largely synthesized and secreted by the sinusoidal endothelial cells of the liver (LSECs). However, the specificity and characteristics of these cells is not well known. In this study, we performed genome wide expression and CpG methylation profiling of fetal and adult human LSECs together with other fetal endothelial cells, from lung (micro-vascular and arterial), and heart (micro-vascular). Our results reveal plenty of expression and methylation markers distinguishing LSECs at both fetal and adult stages. Differential gene expression of fetal LSECs in comparison to other fetal endothelial cells pointed to several differential regulated pathways and functions in fetal LSECs. We used targeted bisulfite re-sequencing to confirm selected top differentially methylated regions. We further designed an assay where we used the selected methylation markers to test the degree of similarity of in house iPSs generated vascular endothelial cells to fetal and adult LSECs; a higher similarity was found to the fetal than to adult LSECs. Our molecular profiling study provides a guide to test the effectiveness of production of in vitro differentiated LSECs that could be used in cellular therapies. In-silico analysis to identify molecular signature of liver sinusoidal endothelial cells in comparison to other endohtelial cells

Project description:In human F8 deficiency leads to hemophilia A and is largely synthesized and secreted by the sinusoidal endothelial cells of the liver (LSECs). However, the specificity and characteristics of these cells is not well known. In this study, we performed genome wide expression and CpG methylation profiling of fetal and adult human LSECs together with other fetal endothelial cells, from lung (micro-vascular and arterial), and heart (micro-vascular). Our results reveal plenty of expression and methylation markers distinguishing LSECs at both fetal and adult stages. Differential gene expression of fetal LSECs in comparison to other fetal endothelial cells pointed to several differential regulated pathways and functions in fetal LSECs. We used targeted bisulfite re-sequencing to confirm selected top differentially methylated regions. We further designed an assay where we used the selected methylation markers to test the degree of similarity of in house iPSs generated vascular endothelial cells to fetal and adult LSECs; a higher similarity was found to the fetal than to adult LSECs. Our molecular profiling study provides a guide to test the effectiveness of production of in vitro differentiated LSECs that could be used in cellular therapies. In-silico analysis to identify molecular signature of liver sinusoidal endothelial cells in comparison to other endohtelial cells

Project description:Hydrostatic pressure driven vascular degeneration in cirrhosis [pLSEC]

Project description:Hydrostatic pressure driven vascular degeneration in cirrhosis [6H]