Project description:The developmental integrity of bile duct epithelium and peribiliary glands (PBGs) plays a key role in maintaining bile flow and preventing liver diseases. We emplpoyed multilineage biliary organoids (MBOs) engineered from co-cultures of human liver epithelial cells, umbilical vein endothelial cells (HUVECs), and mesenchymal stem cells (MSCs) to model biliary development and pathogenesis of biliary atresia (BA). Self organization of these cells into MBOs recapitulated the dual compartmentalization of bile ducts with the epithelial layer and PBGs. Notably, BA patient-derived MBOs exhibited markers of epithelial-mesenchymal transition (EMT) and activated TGF-β/Activin-SMAD2/3 signaling pathways, suggesting a link to the delayed maturation of bile duct epithelium. Inhibition of TGF-β signaling suppressed EMT, promoted epithelial maturation, and improved organoid structure. In in vivo, TGF-β inhibitor treatment in a neonatal mouse model of BA reduced biliary injury and liver fibrosis. These data support the critical role of epithelial and mesenchymal cell interactions in bile duct development, give insight into molecular mechanisms of BA, and point to the therapeutic potential of targeting TGF-β signaling.

Project description:Biliary atresia (BA) is a rare cholestatic disease of unknown etiology that affects infants and shows an incidence of 1 out of 18,000 live births in Europe (1). The first therapeutic option is a timely performed portoenterostomy. However, the majority of patients suffer from a progressive inflammatory process, which leads to complete destruction of the extra- and intrahepatic biliary system followed by end-stage liver cirrhosis. Hence, BA is the leading indication for pediatric liver transplantation worldwide (2, 3). To understand the pathogenesis of the disease and improve theoutcome of BA patients, research has focused on the inflammatory process in liver and bile ducts, in which several factors are remarkably elevated, such as activated CD4 and CD8 T-cells, TNF alpha,IFN alpha and other proinflammatory TH1 cytokines (3-8). By the time of diagnosis, however, the disease has already reached an advanced state, characterized by the complete obstruction of the extrahepatic bile ducts with impaired bile flow and fibrosis or cirrhosis of the liver. Therefore, studies in humans focusing on the trigger mechanism of BA are limited due to the paucity of liver and availability of bile duct tissue for research. One infectious animal model has been developed, in which newborn Balb/c mice exclusively show the experimental BA phenotype after infection with rhesus rotavirus (RRV) (9, 10). This model allows the analysis of the inflammatory reactions in liver and bile ducts at early steps in the development of bile duct atresia (11-20). Furthermore, inbred mouse strains have been shown to have a different susceptibility for the development of experimental BA, suggesting that Balb/c mice have an immunological gap responsible for disease progression (10, 12). The aim of this study was to identify key genes responsible for the BA phenotype by comparing the transcriptomes at an early time point after virus infection, i.e. before bile duct atresia, between two mouse strains with different susceptibilities to BA. Differences in the virus titration and the clinical course of infected mice were analyzed, and variations in the hepatic gene response assessed by comparative microarray assays were correlated to variances in the hepatic inflammatory reaction. Balb/c mice and C57Black/6 (Black/6) mice were infected with RRV postpartum and signs of BA and survival were noted. Liver sections of diseased, healthy and control animals were assessed for T-cell expression, and the virus loads were determined. Second, mice were sacrificed after three days, and isolated hepatic RNA was subjected to gene expression analysis using Affymetrix Gene Chip MOE 430 2.0.We compared three individual expression profiles from RRV-infected Balb/c mice against 2 individual expression profiles from RRV-infected C57/BL6 control mice using the Affymetrix GeneChip MOE 430 2.0.

Project description:Biliary atresia (BA) is a rare cholestatic disease of unknown etiology that affects infants and shows an incidence of 1 out of 18,000 live births in Europe (1). The first therapeutic option is a timely performed portoenterostomy. However, the majority of patients suffer from a progressive inflammatory process, which leads to complete destruction of the extra- and intrahepatic biliary system followed by end-stage liver cirrhosis. Hence, BA is the leading indication for pediatric liver transplantation worldwide (2, 3). To understand the pathogenesis of the disease and improve theoutcome of BA patients, research has focused on the inflammatory process in liver and bile ducts, in which several factors are remarkably elevated, such as activated CD4 and CD8 T-cells, TNF alpha,IFN alpha and other proinflammatory TH1 cytokines (3-8). By the time of diagnosis, however, the disease has already reached an advanced state, characterized by the complete obstruction of the extrahepatic bile ducts with impaired bile flow and fibrosis or cirrhosis of the liver. Therefore, studies in humans focusing on the trigger mechanism of BA are limited due to the paucity of liver and availability of bile duct tissue for research. One infectious animal model has been developed, in which newborn Balb/c mice exclusively show the experimental BA phenotype after infection with rhesus rotavirus (RRV) (9, 10). This model allows the analysis of the inflammatory reactions in liver and bile ducts at early steps in the development of bile duct atresia (11-20). Furthermore, inbred mouse strains have been shown to have a different susceptibility for the development of experimental BA, suggesting that Balb/c mice have an immunological gap responsible for disease progression (10, 12). The aim of this study was to identify key genes responsible for the BA phenotype by comparing the transcriptomes at an early time point after virus infection, i.e. before bile duct atresia, between two mouse strains with different susceptibilities to BA. Differences in the virus titration and the clinical course of infected mice were analyzed, and variations in the hepatic gene response assessed by comparative microarray assays were correlated to variances in the hepatic inflammatory reaction.

Project description:Biliary atresia (BA) is a pediatric liver disease that often necessitates parenteral nutrition (PN) to support growth due to impaired liver function. While soy oil lipid emulsions (SLE) are commonly used in PN, they may contribute to cholestatic liver injury. In contrast, mixed oil lipid emulsions (MLE) have shown promise in preventing cholestasis in non-BA infants, potentially by restoring bile flow. However, their effectiveness in cases of complete bile duct obstruction, as seen in BA, remains uncertain. To explore the potential benefits of MLE in BA, we utilized a neonatal pig model of bile duct ligation (BDL). Pigs underwent either BDL or sham surgery and were subsequently fed either MLE or SLE via PN, or enterally with formula. The MLE-BDL pigs exhibited significantly greater weight gain compared to those fed SLE or formula enterally. Additionally, MLE-BDL pigs showed higher serum bile acid and gamma-glutamyl transferase concentrations compared to SLE-BDL pigs. However, no significant differences in liver injury, assessed by ductular reaction or fibrosis, were observed between MLE- and SLE-BDL pigs. Based on weight gain alone, MLE may be a superior lipid emulsion for use in neonates with obstructive cholestasis.

Project description:Restitution of the extrahepatic biliary luminal epithelium in cholangiopathies is poorly understood. Prominin-1 (Prom1) is a key component of epithelial ciliary body of stem/progenitor cells. Given that intrahepatic Prom1-expressing progenitor cells undergo cholangiocyte differentiation, we hypothesized that Prom1 may promote restitution of the extrahepatic bile duct (EHBD) epithelium following injury. Utilizing various murine biliary injury models, we identified Prom1-expressing cells in the peribiliary glands (PBGs) of the EHBD. These Prom1-expressing cells are progenitor cells which give rise to cholangiocytes as part of the normal maintenance of the EHBD epithelium. Following injury, these cells proliferate significantly more rapidly to re-populate the biliary luminal epithelium. Null mutation of Prom1 leads to significantly more than ten-fold dilated PBGs following rhesus rotavirus-mediated biliary injury. Cultured organoids derived from Prom1 knockout mice are comprised of biliary progenitor cells with altered apical-basal cellular polarity, significantly fewer and shorter cilia, and decreased organoid proliferation dynamics consistent with impaired cell motility. We, therefore, conclude that Prom1 is involved in biliary epithelial restitution following biliary injury in part through its role in supporting cell polarity.

Project description:RNA-Sequencing was performed on mechanically dissociated, epithelial-enriched samples, of human extrahepatic biliary tissue from Gallbladder, Common Bile Duct, and Pancreatic Duct tissues. Sequencing was also performed on in vitro cultures of Organoid cell lines at passage 5 that were derived from human Gallbladder, Common Bile Duct, Pancreatic Duct, or Intrahepatic Bile Ducts.

Project description:Biliary diseases can cause inflammation, fibrosis, bile duct destruction and eventually liver failure. There are no curative treatments for biliary disease except for liver transplantation. New therapies are urgently required. We have purified human Biliary Epithelial Cells (hBEC) from discarded human livers. hBECs were tested as a cell therapy in a mouse model of biliary disease where the conditional deletion of Mdm2 in cholangiocytes causes senescence, biliary strictures and fibrosis. hBEC are expandable, phenotypically stable and help restore biliary structure and function, highlighting their regenerative capacity and a potential alternative to liver transplantation for biliary disease.

Project description:Biliary atresia (BA), blockage of the proper bile flow due to loss of extrahepatic bile ducts, is a rare, complex disease of the liver and the bile ducts with unknown etiology. Despite ongoing investigations to understand its complex pathogenesis, BA remains the most common cause of liver failure requiring liver transplantation in children. To elucidate underlying mechanisms, we analyzed the different types of high-throughput genomic and transcriptomic data collected from the blood and liver tissue samples of children suffering from BA. Through use of a novel integrative approach, we identified potential biomarkers and over-represented biological functions and pathways to derive a comprehensive network showing the dysfunctional mechanisms associated with BA. One of the pathways highlighted in the integrative network was hypoxia signaling. Perturbation with hypoxia inducible factor activator, dimethyloxalylglycine, induced the biliary defects of BA in a zebrafish model, serving as a validation for our studies. Our approach enables a systems-level understanding of human BA biology that is highlighted by the interaction between key biological functions such as fibrosis, inflammation, immunity, hypoxia, and development

Project description:Biliary atresia (BA) causes neonatal cholestasis jaundice. The primary therapeutic treatment for BA is the Kasai portoenterostomy, a surgical procedure creating a new bile duct to restore bile flow. However, current diagnostic approaches for BA are imprecise and time-consuming, making early diagnosis crucial for successful treatment outcomes. The present study was aimed to analyze proteins from peripheral blood mononuclear cells (PBMCs) obtained from children with biliary atresia compared with healthy children as potential biomarkers for diagnostic tests.

Project description:A network of co-hepato/pancreatic stem/progenitors exists in pigs and humans in Brunner’s Glands (BGs) in the submucosa of the duodenum, in peribiliary glands (PBGs) of intrahepatic and extrahepatic biliary trees, and in pancreatic duct glands (PDGs) of intrapancreatic biliary trees, collectively supporting hepatic and pancreatic regeneration postnatally. The network is found in humans postnatally throughout life and, so far, has been demonstrated in pigs postnatally at least through to young adults. These stem/progenitors in vivo in pigs are in highest numbers in BGs and in PDGS nearest the duodenum, and in humans are in BGs and in PBGs in the hepato/pancreatic common duct, a duct missing postnatally in pigs. Elsewhere in PDGs in pigs and in all PDGs in humans are only committed unipotent or bipotent progenitors.