Project description:Disturbance of heterologous cell communication is associated with a structural reorganization of the vascular niche, a process called capillarization, which is already initiated in early stages of liver tumor development. In this study, the molecular characterization of endothelial cell (EC) subpopulations from healthy livers and yes-associated protein (Yap)-induced liver tumors revealed a dynamic crosstalk between liver sinusoidal endothelial cells (LSECs) and capillary endothelial cells (CECs). Initial paracrine stimuli from parenchymal cells include the Yap/Tead4 target gene osteopontin (Opn), which promotes CECs expansion through the induction of c-Met and sensitization towards LSEC-derived hepatocyte growth factor (Hgf). In addition, Yap/Tead4-induced C-C motif chemokine ligand 2 (Ccl2) recruits bone-marrow-derived macrophages (BMDMs) with an unpolarized phenotype (M0) to the perivascular space of expanding CECs.

Project description:Disturbance of heterologous cell communication is associated with a structural reorganization of the vascular niche, a process called capillarization, which is already initiated in early stages of liver tumor development. In this study, the molecular characterization of endothelial cell (EC) subpopulations from healthy livers and yes-associated protein (Yap)-induced liver tumors revealed a dynamic crosstalk between liver sinusoidal endothelial cells (LSECs) and capillary endothelial cells (CECs). Initial paracrine stimuli from parenchymal cells include the Yap/Tead4 target gene osteopontin (Opn), which promotes CECs expansion through the induction of c-Met and sensitization towards LSEC-derived hepatocyte growth factor (Hgf). In addition, Yap/Tead4-induced C-C motif chemokine ligand 2 (Ccl2) recruits bone-marrow-derived macrophages (BMDMs) with an unpolarized phenotype (M0) to the perivascular space of expanding CECs.

Project description:Disturbance of heterologous cell communication is associated with a structural reorganization of the vascular niche, a process called capillarization, which is already initiated in early stages of liver tumor development. In this study, the molecular characterization of endothelial cell (EC) subpopulations from healthy livers and yes-associated protein (Yap)-induced liver tumors revealed a dynamic crosstalk between liver sinusoidal endothelial cells (LSECs) and capillary endothelial cells (CECs). Initial paracrine stimuli from parenchymal cells include the Yap/Tead4 target gene osteopontin (Opn), which promotes CECs expansion through the induction of c-Met and sensitization towards LSEC-derived hepatocyte growth factor (Hgf). In addition, Yap/Tead4-induced C-C motif chemokine ligand 2 (Ccl2) recruits bone-marrow-derived macrophages (BMDMs) with an unpolarized phenotype (M0) to the perivascular space of expanding CECs.

Project description:Chronic liver disease is a major leading cause of portal hypertension that affects approximately 1.5 billion people globally. We show that GIMAP5, a small organellar GTPase, is selectively expressed in liver endothelial cells and human GIMAP5 deficiency causes portal hypertension with capillarization of liver sinusoidal endothelial cells (LSECs). LSEC capillarization is recapitulated in GIMAP5 loss-of-function (LOF) mice, and upon conditional Gimap5 deletion in endothelial cells. Single cell RNA-sequencing analyses reveals replacement of LSECs with capillarized endothelial cells and expansion of liver lymphatic endothelial cells in GIMAP5 LOF mice, and places GIMAP5 upstream of GATA4, a transcription factor required for LSEC-specification. Our studies reveal that GIMAP5 prevents portal hypertension by maintaining LSEC identity and suggest that LSEC is an induced endothelial cell state.

Project description:Liver sinusoidal endothelium (LSEC) is a prime example for organ-specific microvascular differentiation and functions. Disease-associated capillarization of LSEC in vivo and dedifferentiation of LSEC in vitro indicate the importance of the hepatic microenvironment. To identify the LSEC-specific molecular differentiation program in the rat, we used a two-sided gene expression profiling approach comparing LSEC freshly isolated ex vivo with both lung microvascular endothelial cells (LMEC) and with LSEC cultured for 42h. The LSEC signature consisted of 48 genes both down-regulated in LMEC and in LSEC upon culture (FC>7 in at least one comparison); qRT-PCR confirmation of these genes included numerous family members and signalling pathway-associated molecules. The LSEC differentiation program comprised distinct sets of growth (wnt2, Fzd4, 5, 9, wls, VEGFR1, 2, 3, Nrp2) and transcription factors (Gata4, Lmo3, Tcfec, Maf) as well as endocytosis-related (Stabilin-1/2, Lyve1 and Ehd3) and cytoskeleton-associated molecules (Rnd3/RhoE). Specific gene induction in cultured LSEC versus freshly isolated LSEC as well as LMEC (Esm-1, Aatf) and up-regulation of gene expression to LMEC levels (CXCR4, Apelin) confirmed true transdifferentiation of LSEC in vitro. In addition, our analysis identified a novel 26 kDa single-pass transmembrane protein, liver endothelial differentiation-associated protein (Leda)-1, that was selectively expressed in all liver endothelial cells and preferentially localized to the abluminal cell surface. Upon forced over-expression in MDCK cells, Leda-1 was sorted baso-laterally to E-cadherin-positive adherens junctions suggesting functional involvement in cell adhesion and polarity. Conclusion: Comparative microvascular analysis in rat identified a hepatic microenvironment-dependent LSEC-specific differentiation program including the novel junctional molecule Leda-1. Highly pure liver sinusoidal endothelial cells (LSEC) and lung microvascular endothelial cells (LMEC) were isolated by enzymatic digestion, density gradient centrifugation and MACS sorting and subjected to RNA extraction and affymetrix hybridization without any culturing step (LSEC_0h, LMEC_0h). LSEC were also plated on collagen coated dishes and RNA extraction and Affymetrix hybridization was carried out after 2h and 42h in culture (LSEC_2h, LSEC_42h).

Project description:Angiocrine signaling by liver sinusoidal endothelial cells (LSEC) regulates liver functions such as liver growth, metabolic maturation, and regeneration. Recently, we identified GATA4 as the master regulator of LSEC specification during development. Here, we studied endothelial GATA4 in the adult liver and in hepatic disease pathogenesis. We generated adult Clec4g-icretg/0xGata4fl/fl (Gata4LSEC KO) mice with deficiency of Gata4 in LSEC. Livers were analyzed by histology, electron microscopy, immunohistochemistry/immunofluorescence, in-situ hybridization, and by expression profiling and ATAC-sequencing of isolated LSEC. For liver regeneration, partial hepatectomy was performed. As models of liver fibrosis, CDAA diet and chronic CCl4 exposure were applied. Human single cell RNAseq data sets were analyzed for endothelial alterations in healthy and cirrhotic livers. Genetic Gata4 deficiency in LSEC in adult mice caused perisinusoidal liver fibrosis, hepatopathy and impaired liver regeneration. Sinusoidal capillarization and LSEC-to-continuous endothelial transdifferentiation were accompanied by a profibrotic angiocrine switch including de novo endothelial expression of hepatic stellate cell-activating cytokine PDGFB. Increased chromatin accessibility and amplification by activated Myc mediated angiocrine PDGFB expression. In CDAA diet-induced perisinusoidal liver fibrosis, LSEC showed repression of GATA4, activation of MYC and the profibrotic angiocrine switch already detected in Gata4LSEC KO mice. Comparison of CDAA-fed Gata4LSEC KO and control mice demonstrated that endothelial Gata4 indeed protects from dietary-induced perisinusoidal liver fibrosis. In human cirrhotic livers, Gata4-positive LSEC and endothelial Gata4 target genes were reduced, while non-LSEC endothelial cells and Myc target genes including PDGFB were enriched. Endothelial GATA4 protects from perisinusoidal liver fibrosis by repressing MYC activation and profibrotic angiocrine signaling on the chromatin level. Therapies targeting the GATA4/MYC/PDGFB/PDGFRβ axis offer a promising strategy for the prevention and treatment of liver fibrosis.

Project description:Angiocrine signaling by liver sinusoidal endothelial cells (LSEC) regulates liver functions such as liver growth, metabolic maturation, and regeneration. Recently, we identified GATA4 as the master regulator of LSEC specification during development. Here, we studied endothelial GATA4 in the adult liver and in hepatic disease pathogenesis. We generated adult Clec4g-icretg/0xGata4fl/fl (Gata4LSEC KO) mice with deficiency of Gata4 in LSEC. Livers were analyzed by histology, electron microscopy, immunohistochemistry/immunofluorescence, in-situ hybridization, and by expression profiling and ATAC-sequencing of isolated LSEC. For liver regeneration, partial hepatectomy was performed. As models of liver fibrosis, CDAA diet and chronic CCl4 exposure were applied. Human single cell RNAseq data sets were analyzed for endothelial alterations in healthy and cirrhotic livers. Genetic Gata4 deficiency in LSEC in adult mice caused perisinusoidal liver fibrosis, hepatopathy and impaired liver regeneration. Sinusoidal capillarization and LSEC-to-continuous endothelial transdifferentiation were accompanied by a profibrotic angiocrine switch including de novo endothelial expression of hepatic stellate cell-activating cytokine PDGFB. Increased chromatin accessibility and amplification by activated Myc mediated angiocrine PDGFB expression. In CDAA diet-induced perisinusoidal liver fibrosis, LSEC showed repression of GATA4, activation of MYC and the profibrotic angiocrine switch already detected in Gata4LSEC KO mice. Comparison of CDAA-fed Gata4LSEC KO and control mice demonstrated that endothelial Gata4 indeed protects from dietary-induced perisinusoidal liver fibrosis. In human cirrhotic livers, Gata4-positive LSEC and endothelial Gata4 target genes were reduced, while non-LSEC endothelial cells and Myc target genes including PDGFB were enriched. Endothelial GATA4 protects from perisinusoidal liver fibrosis by repressing MYC activation and profibrotic angiocrine signaling on the chromatin level. Therapies targeting the GATA4/MYC/PDGFB/PDGFRβ axis offer a promising strategy for the prevention and treatment of liver fibrosis.

Project description:Molecular markers of dedifferentiation of dysfunctional liver sinusoidal endothelial cells (LSEC), have not been fully elucidated. We aimed at deciphering the molecular profile of dysfunctional LSEC in different pathological scenarios. Flow cytometry was used to sort CD11bˉ/CD32b+ and CD11bˉ/CD32bˉLSEC from three rat models of liver disease (bile duct ligation-BDL, inhaled carbon tetrachloride-CCl4 and high fat glucose/fructose diet-HFGFD). Full proteomic profile was performed applying nano-scale liquid chromatography tandem mass spectrometry (nLC-MS) and analyzed with PEAKS software. The percentage of CD32bˉ LSEC varied across groups, suggesting different capillarization processes. Both CD32+ and CD32bˉLSEC from models are different from control LSEC but differently expressed proteins in CD32bˉLSEC are significantly higher. Heatmaps evidenced specific protein expression patterns for each model. Analysis of biological significance comparing dysfunctional CD32bˉLSEC with specialized CD32b+ LSEC from controls showed central similarities represented by 45 common downregulated proteins involved in the suppression of the endocytic machinery and 63 common upregulated proteins associated with the actin-dependent cytoskeleton reorganization. In summary, substantial differences but also similarities in dysfunctional LSEC from the three most common models of liver disease were found, supporting the idea that LSEC may harbor different protein expression profiles according to the etiology or disease stage.

Project description:Liver sinusoidal endothelium (LSEC) is a prime example for organ-specific microvascular differentiation and functions. Disease-associated capillarization of LSEC in vivo and dedifferentiation of LSEC in vitro indicate the importance of the hepatic microenvironment. To identify the LSEC-specific molecular differentiation program in the rat, we used a two-sided gene expression profiling approach comparing LSEC freshly isolated ex vivo with both lung microvascular endothelial cells (LMEC) and with LSEC cultured for 42h. The LSEC signature consisted of 48 genes both down-regulated in LMEC and in LSEC upon culture (FC>7 in at least one comparison); qRT-PCR confirmation of these genes included numerous family members and signalling pathway-associated molecules. The LSEC differentiation program comprised distinct sets of growth (wnt2, Fzd4, 5, 9, wls, VEGFR1, 2, 3, Nrp2) and transcription factors (Gata4, Lmo3, Tcfec, Maf) as well as endocytosis-related (Stabilin-1/2, Lyve1 and Ehd3) and cytoskeleton-associated molecules (Rnd3/RhoE). Specific gene induction in cultured LSEC versus freshly isolated LSEC as well as LMEC (Esm-1, Aatf) and up-regulation of gene expression to LMEC levels (CXCR4, Apelin) confirmed true transdifferentiation of LSEC in vitro. In addition, our analysis identified a novel 26 kDa single-pass transmembrane protein, liver endothelial differentiation-associated protein (Leda)-1, that was selectively expressed in all liver endothelial cells and preferentially localized to the abluminal cell surface. Upon forced over-expression in MDCK cells, Leda-1 was sorted baso-laterally to E-cadherin-positive adherens junctions suggesting functional involvement in cell adhesion and polarity. Conclusion: Comparative microvascular analysis in rat identified a hepatic microenvironment-dependent LSEC-specific differentiation program including the novel junctional molecule Leda-1.

Project description:Microvascular endothelial cells (EC) are increasingly recognized as organ-specific gatekeepers of their microenvironment. Microvascular EC instruct neighboring cells in their organ-specific vascular niches by angiocrine factors that comprise secreted growth factors/angiokines, but also extracellular matrix molecules and transmembrane proteins. The molecular regulators, however, that drive organ-specific microvascular transcriptional programs and thereby regulate angiodiversity, are largely elusive. Opposite to continuous barrier-forming EC, liver sinusoids are a prime model of discontinuous, permeable micro-vessels. Here, we show that transcription factor GATA4 controls liver sinusoidal endothelial (LSEC) specification and function. LSEC-restricted deletion of GATA4 caused transformation of discontinuous liver sinusoids into continuous capillaries. Capillarization was characterized by ectopic basement membrane deposition and formation of an abundantly VE-Cadherin expressing continuous endothelium. Correspondingly, ectopic expression of GATA4 in cultured continuous EC mediated downregulation of continuous EC transcripts and upregulation of LSEC genes. Regarding angiocrine functions, the switch from discontinuous LSEC to continuous EC during embryogenesis caused liver hypoplasia, fibrosis, and impaired colonization by hematopoietic progenitor cells resulting in anemia and embryonic lethality. Thus, GATA4 acts as master regulator of hepatic microvascular specification and acquisition of organ-specific vascular competence indispensable for liver development. The data also establish an essential role of the hepatic microvasculature for embryonic hematopoiesis.