Innate Immunity and Pathogenesis of Biliary Atresia

Biliary atresia (BA) is a devastating fibro-inflammatory disease characterized by the obstruction of extrahepatic and intrahepatic bile ducts in infants that can have fatal consequences, when not treated in a timely manner. It is the most common indication of pediatric liver transplantation worldwide and the development of new therapies, to alleviate the need of surgical intervention, has been hindered due to its complexity and lack of understanding of the disease pathogenesis. For that reason, significant efforts have been made toward the development of experimental models and strategies to understand the etiology and disease mechanisms and to identify novel therapeutic targets. The only characterized model of BA, using a Rhesus Rotavirus Type A infection of newborn BALB/c mice, has enabled the identification of key cellular and molecular targets involved in epithelial injury and duct obstruction. However, the establishment of an unleashed chronic inflammation followed by a progressive pathological wound healing process remains poorly understood. Like T cells, macrophages can adopt different functional programs [pro-inflammatory (M1) and resolutive (M2) macrophages] and influence the surrounding cytokine environment and the cell response to injury. In this review, we provide an overview of the immunopathogenesis of BA, discuss the implication of innate immunity in the disease pathogenesis and highlight their suitability as therapeutic targets.

[1]  G. Tiao,et al.  Rotavirus Reassortant–Induced Murine Model of Liver Fibrosis Parallels Human Biliary Atresia , 2020, Hepatology.

[2]  C. Pechmann,et al.  Policy and Research Related to Consumer Rebates: A Comprehensive Review , 2013 .

[3]  Yayi Hou,et al.  C-type lectin receptor-mediated immune recognition and response of the microbiota in the gut , 2019, Gastroenterology report.

[4]  Y. Iwakura,et al.  Myeloid C‐type lectin receptors in skin/mucoepithelial diseases and tumors , 2019, Journal of leukocyte biology.

[5]  S. Paul,et al.  RAGE and Its Ligands: Molecular Interplay Between Glycation, Inflammation, and Hallmarks of Cancer—a Review , 2018, Hormones and Cancer.

[6]  C. Petersen,et al.  Role of viruses in biliary atresia: news from mice and men , 2018, Innovative surgical sciences.

[7]  T. Geijtenbeek,et al.  C-Type Lectin Receptors in Antiviral Immunity and Viral Escape , 2018, Front. Immunol..

[8]  A. Jegga,et al.  Gene‐disease associations identify a connectome with shared molecular pathways in human cholangiopathies , 2018, Hepatology.

[9]  Ruizhong Zhang,et al.  Autoimmune liver disease-related autoantibodies in patients with biliary atresia , 2018, World journal of gastroenterology.

[10]  Hanmin Li,et al.  The Injury-Related Activation of Hedgehog Signaling Pathway Modulates the Repair-Associated Inflammation in Liver Fibrosis , 2017, Front. Immunol..

[11]  M. Davenport Adjuvant therapy in biliary atresia: hopelessly optimistic or potential for change? , 2017, Pediatric Surgery International.

[12]  M. Manns,et al.  norUrsodeoxycholic acid improves cholestasis in primary sclerosing cholangitis. , 2017, Journal of hepatology.

[13]  G. Salekdeh,et al.  Advanced glycation end‐products produced systemically and by macrophages: A common contributor to inflammation and degenerative diseases , 2017, Pharmacology & therapeutics.

[14]  M. Gershwin,et al.  How the biliary tree maintains immune tolerance? , 2017, Biochimica et biophysica acta. Molecular basis of disease.

[15]  C. Nylund,et al.  Incidence of Biliary Atresia and Timing of Hepatoportoenterostomy in the United States. , 2017, The Journal of pediatrics.

[16]  S. Glaser,et al.  Mechanisms of cholangiocyte responses to injury. , 2017, Biochimica et biophysica acta. Molecular basis of disease.

[17]  J. Meller,et al.  A Point Mutation in the Rhesus Rotavirus VP4 Protein Generated through a Rotavirus Reverse Genetics System Attenuates Biliary Atresia in the Murine Model , 2017, Journal of Virology.

[18]  T. Wynn,et al.  Mechanisms of Organ Injury and Repair by Macrophages. , 2017, Annual review of physiology.

[19]  J. Meller,et al.  The SRL peptide of rhesus rotavirus VP4 protein governs cholangiocyte infection and the murine model of biliary atresia , 2017, Hepatology.

[20]  C. Chougnet,et al.  The dendritic cell–T helper 17–macrophage axis controls cholangiocyte injury and disease progression in murine and human biliary atresia , 2017, Hepatology.

[21]  Guo-qing Cao,et al.  Foxp3 promoter methylation impairs suppressive function of regulatory T cells in biliary atresia. , 2016, American journal of physiology. Gastrointestinal and liver physiology.

[22]  G. Tiao,et al.  Rhesus rotavirus VP6 regulates ERK-dependent calcium influx in cholangiocytes. , 2016, Virology.

[23]  M. Davenport,et al.  Biliary atresia and other cholestatic childhood diseases: Advances and future challenges. , 2016, Journal of hepatology.

[24]  M. Davenport,et al.  Biliary atresia: A comprehensive review. , 2016, Journal of autoimmunity.

[25]  J. Reguła,et al.  A Placebo-Controlled Trial of Obeticholic Acid in Primary Biliary Cholangitis. , 2016, The New England journal of medicine.

[26]  P. Dawson,et al.  Bile acids and nonalcoholic fatty liver disease: Molecular insights and therapeutic perspectives , 2016, Hepatology.

[27]  M. Girard,et al.  Biliary atresia: Clinical advances and perspectives. , 2016, Clinics and research in hepatology and gastroenterology.

[28]  M. Davenport Biliary atresia: From Australia to the zebrafish. , 2016, Journal of pediatric surgery.

[29]  M. Davenport,et al.  Steroids after the Kasai procedure for biliary atresia: the effect of age at Kasai portoenterostomy , 2015, Pediatric Surgery International.

[30]  M. Davenport,et al.  Cytomegalovirus-associated biliary atresia: An aetiological and prognostic subgroup. , 2015, Journal of pediatric surgery.

[31]  J. Meller,et al.  Rhesus rotavirus VP4 sequence-specific activation of mononuclear cells is associated with cholangiopathy in murine biliary atresia. , 2015, American journal of physiology. Gastrointestinal and liver physiology.

[32]  H. Yoshida,et al.  Evidence for viral infection as a causative factor of human biliary atresia. , 2015, Journal of pediatric surgery.

[33]  G. Offerhaus,et al.  Liver fibrosis during the development of biliary atresia: Proof of principle in the murine model. , 2015, Journal of pediatric surgery.

[34]  D. Brenner,et al.  Recent advancement of molecular mechanisms of liver fibrosis , 2015, Journal of hepato-biliary-pancreatic sciences.

[35]  J. Bezerra,et al.  Pathogenesis of biliary atresia: defining biology to understand clinical phenotypes , 2015, Nature Reviews Gastroenterology &Hepatology.

[36]  T. Rőszer,et al.  Understanding the Mysterious M2 Macrophage through Activation Markers and Effector Mechanisms , 2015, Mediators of inflammation.

[37]  I. Sealy,et al.  Identification of a plant isoflavonoid that causes biliary atresia , 2015, Science Translational Medicine.

[38]  S. Karpen,et al.  Genetic Contributors and Modifiers of Biliary Atresia , 2015, Digestive Diseases.

[39]  C. Mack What Causes Biliary Atresia? Unique Aspects of the Neonatal Immune System Provide Clues to Disease Pathogenesis , 2015, Cellular and molecular gastroenterology and hepatology.

[40]  S. Yamagishi,et al.  Role of receptor for advanced glycation end products (RAGE) in liver disease , 2015, European Journal of Medical Research.

[41]  D. Vergani,et al.  Regulatory T cells: Mechanisms of suppression and impairment in autoimmune liver disease , 2015, IUBMB life.

[42]  Yingwei Chen,et al.  Low doses of CMV induce autoimmune-mediated and inflammatory responses in bile duct epithelia of regulatory T cell-depleted neonatal mice , 2015, Laboratory Investigation.

[43]  S. Kosola,et al.  Native Liver Histology After Successful Portoenterostomy in Biliary Atresia , 2014, Journal of clinical gastroenterology.

[44]  Peter A Keyel,et al.  How is inflammation initiated? Individual influences of IL-1, IL-18 and HMGB1. , 2014, Cytokine.

[45]  Jun Li,et al.  Hedgehog signaling pathway as key player in liver fibrosis: new insights and perspectives , 2014, Expert opinion on therapeutic targets.

[46]  S. Goerdt,et al.  Macrophage activation and polarization: nomenclature and experimental guidelines. , 2014, Immunity.

[47]  G. Gores,et al.  Biliary repair and carcinogenesis are mediated by IL-33-dependent cholangiocyte proliferation. , 2014, The Journal of clinical investigation.

[48]  P. Rosenthal,et al.  Use of corticosteroids after hepatoportoenterostomy for bile drainage in infants with biliary atresia: the START randomized clinical trial. , 2014, JAMA.

[49]  J. Fallowfield,et al.  Liver fibrosis and repair: immune regulation of wound healing in a solid organ , 2014, Nature Reviews Immunology.

[50]  J. Bezerra,et al.  Perforin and granzymes work in synergy to mediate cholangiocyte injury in experimental biliary atresia. , 2014, Journal of hepatology.

[51]  P. Rosenthal,et al.  Extrahepatic Anomalies in Infants With Biliary Atresia: Results of a Large Prospective North American Multicenter Study , 2013, Hepatology.

[52]  Guo-qing Cao,et al.  Elevated Th17 cells accompanied by decreased regulatory T cells and cytokine environment in infants with biliary atresia , 2013, Pediatric Surgery International.

[53]  R. Tucker,et al.  Regulatory T cells inhibit Th1 cell-mediated bile duct injury in murine biliary atresia. , 2013, Journal of hepatology.

[54]  G. Tiao,et al.  Role of myeloid differentiation factor 88 in Rhesus rotavirus-induced biliary atresia. , 2013, The Journal of surgical research.

[55]  M. Davenport,et al.  Aetiology of biliary atresia: what is actually known? , 2013, Orphanet Journal of Rare Diseases.

[56]  D. Voehringer,et al.  Interleukin-33-dependent innate lymphoid cells mediate hepatic fibrosis. , 2013, Immunity.

[57]  R. Tucker,et al.  B Cell Deficient Mice Are Protected from Biliary Obstruction in the Rotavirus-Induced Mouse Model of Biliary Atresia , 2013, PloS one.

[58]  D. Witte,et al.  Rotavirus Replication in the Cholangiocyte Mediates the Temporal Dependence of Murine Biliary Atresia , 2013, PloS one.

[59]  J. Golmard,et al.  Improving outcomes of biliary atresia: French national series 1986-2009. , 2013, Journal of hepatology.

[60]  R. D. de Man,et al.  The long-term outcome of the Kasai operation in patients with biliary atresia: a systematic review. , 2013, The Netherlands journal of medicine.

[61]  S. Honsawek,et al.  Soluble receptor for advanced glycation end products and liver stiffness in postoperative biliary atresia. , 2013, Clinical biochemistry.

[62]  J. Dranoff,et al.  Advances in cholangiocyte immunobiology. , 2012, American journal of physiology. Gastrointestinal and liver physiology.

[63]  G. Tiao,et al.  Rotavirus infection of human cholangiocytes parallels the murine model of biliary atresia. , 2012, The Journal of surgical research.

[64]  M. Besnard,et al.  Biliary atresia: does ethnicity matter? , 2012, Journal of hepatology.

[65]  Amy G. Feldman,et al.  Biliary atresia: cellular dynamics and immune dysregulation. , 2012, Seminars in pediatric surgery.

[66]  M. Davenport Biliary atresia: clinical aspects. , 2012, Seminars in pediatric surgery.

[67]  C. Chougnet,et al.  Regulatory T cells control the CD8 adaptive immune response at the time of ductal obstruction in experimental biliary atresia , 2012, Hepatology.

[68]  R. Tucker,et al.  Cytomegalovirus‐specific T‐cell reactivity in biliary atresia at the time of diagnosis is associated with deficits in regulatory T cells , 2012, Hepatology.

[69]  Alberto Mantovani,et al.  Macrophage plasticity and polarization: in vivo veritas. , 2012, The Journal of clinical investigation.

[70]  E. Mohammadi,et al.  Barriers and facilitators related to the implementation of a physiological track and trigger system: A systematic review of the qualitative evidence , 2017, International journal for quality in health care : journal of the International Society for Quality in Health Care.

[71]  Shan Zheng,et al.  Changes in Epigenetic Regulation of CD4+ T Lymphocytesin Biliary Atresia , 2011, Pediatric Research.

[72]  S. Harpavat,et al.  Patients With Biliary Atresia Have Elevated Direct/Conjugated Bilirubin Levels Shortly After Birth , 2011, Pediatrics.

[73]  S. Mohanty,et al.  Th2 signals induce epithelial injury in mice and are compatible with the biliary atresia phenotype. , 2011, The Journal of clinical investigation.

[74]  C. Chougnet,et al.  Dendritic Cells Regulate Natural Killer Cell Activation and Epithelial Injury in Experimental Biliary Atresia , 2011, Science Translational Medicine.

[75]  C. Meyer,et al.  IL-13 Induces Connective Tissue Growth Factor in Rat Hepatic Stellate Cells via TGF-β–Independent Smad Signaling , 2011, The Journal of Immunology.

[76]  R. Ward,et al.  The Rhesus Rotavirus Gene Encoding VP4 Is a Major Determinant in the Pathogenesis of Biliary Atresia in Newborn Mice , 2011, Journal of Virology.

[77]  M. Gale,et al.  Immune signaling by RIG-I-like receptors. , 2011, Immunity.

[78]  A. Diehl,et al.  Hedgehog signaling in cholangiocytes , 2011, Current opinion in gastroenterology.

[79]  S. McCall,et al.  Hedgehog activity, epithelial‐mesenchymal transitions, and biliary dysmorphogenesis in biliary atresia , 2011, Hepatology.

[80]  M. Kagnoff,et al.  RIG-I/MDA5/MAVS Are Required To Signal a Protective IFN Response in Rotavirus-Infected Intestinal Epithelium , 2011, The Journal of Immunology.

[81]  G. Karaca,et al.  Osteopontin is induced by hedgehog pathway activation and promotes fibrosis progression in nonalcoholic steatohepatitis , 2011, Hepatology.

[82]  R. Tucker,et al.  α-enolase autoantibodies cross-reactive to viral proteins in a mouse model of biliary atresia. , 2010, Gastroenterology.

[83]  Kenichi Harada,et al.  Biliary Innate Immunity: Function and Modulation , 2010, Mediators of inflammation.

[84]  Y. Nakanuma,et al.  Biliary innate immunity in the pathogenesis of biliary diseases. , 2010, Inflammation & allergy drug targets.

[85]  C. Chougnet,et al.  Post-natal paucity of regulatory T cells and control of NK cell activation in experimental biliary atresia. , 2010, Journal of hepatology.

[86]  R. Premont,et al.  Signals from dying hepatocytes trigger growth of liver progenitors , 2010, Gut.

[87]  S. Mohanty,et al.  Macrophages Are Targeted by Rotavirus in Experimental Biliary Atresia and Induce Neutrophil Chemotaxis by Mip2/Cxcl2 , 2010, Pediatric Research.

[88]  S. Akira,et al.  Pattern Recognition Receptors and Inflammation , 2010, Cell.

[89]  D. Vignali,et al.  Regulatory T cells and inhibitory cytokines in autoimmunity. , 2009, Current opinion in immunology.

[90]  R. Tucker,et al.  Cholangiocytes as immune modulators in rotavirus‐induced murine biliary atresia , 2009, Liver international : official journal of the International Association for the Study of the Liver.

[91]  C. Chougnet,et al.  Neonatal NK cells target the mouse duct epithelium via Nkg2d and drive tissue-specific injury in experimental biliary atresia. , 2009, The Journal of clinical investigation.

[92]  A. Porrello,et al.  Repair‐related activation of hedgehog signaling promotes cholangiocyte chemokine production , 2009, Hepatology.

[93]  T. Jiang,et al.  Imbalance between T helper type 17 and T regulatory cells in patients with primary biliary cirrhosis: the serum cytokine profile and peripheral cell population , 2009, Clinical and experimental immunology.

[94]  J. Kuebler,et al.  Incidence of hepatotropic viruses in biliary atresia , 2009, European Journal of Pediatrics.

[95]  G. Tiao,et al.  Cholangiocyte secretion of chemokines in experimental biliary atresia. , 2009, Journal of pediatric surgery.

[96]  M. Yoneyama,et al.  RNA recognition and signal transduction by RIG‐I‐like receptors , 2009, Immunological reviews.

[97]  M. Davenport,et al.  Cystic biliary atresia: an etiologic and prognostic subgroup. , 2008, Journal of pediatric surgery.

[98]  K. Isse,et al.  Induction of innate immune response and absence of subsequent tolerance to dsRNA in biliary epithelial cells relate to the pathogenesis of biliary atresia , 2008, Liver international : official journal of the International Association for the Study of the Liver.

[99]  S. Mohanty,et al.  Temporal‐spatial activation of apoptosis and epithelial injury in murine experimental biliary atresia , 2008, Hepatology.

[100]  K. Isse,et al.  Innate immune response to double‐stranded RNA in biliary epithelial cells is associated with the pathogenesis of biliary atresia , 2007, Hepatology.

[101]  R. Ward,et al.  MAPK signaling contributes to rotaviral-induced cholangiocyte injury and viral replication. , 2007, Surgery.

[102]  C. Chougnet,et al.  Effector role of neonatal hepatic CD8+ lymphocytes in epithelial injury and autoimmunity in experimental biliary atresia. , 2007, Gastroenterology.

[103]  R. Sokol,et al.  Oligoclonal expansions of CD4+ and CD8+ T-cells in the target organ of patients with biliary atresia. , 2007, Gastroenterology.

[104]  S. Kawasaki,et al.  Maternal microchimerism in biliary atresia. , 2007, Journal of Pediatric Surgery.

[105]  K. Isse,et al.  IL‐8 expression by biliary epithelial cells is associated with neutrophilic infiltration and reactive bile ductules , 2007, Liver international : official journal of the International Association for the Study of the Liver.

[106]  M. Yoneyama,et al.  Function of RIG-I-like Receptors in Antiviral Innate Immunity* , 2007, Journal of Biological Chemistry.

[107]  R. Ward,et al.  Effect of Rotavirus Strain on the Murine Model of Biliary Atresia , 2006, Journal of Virology.

[108]  R. Tucker,et al.  Cellular and humoral autoimmunity directed at bile duct epithelia in murine biliary atresia , 2006, Hepatology.

[109]  K. Isse,et al.  Endotoxin tolerance in human intrahepatic biliary epithelial cells is induced by upregulation of IRAK‐M , 2006, Liver international : official journal of the International Association for the Study of the Liver.

[110]  Taku Sato,et al.  Interleukin 15–dependent crosstalk between conventional and plasmacytoid dendritic cells is essential for CpG-induced immune activation , 2006, Nature Immunology.

[111]  P. Flemming,et al.  Expression of the interferon-induced Mx proteins in biliary atresia. , 2006, Journal of pediatric surgery.

[112]  L. Zitvogel,et al.  In vivo veritas , 2005, Nature Biotechnology.

[113]  A. Sahai,et al.  Expression of Osteopontin Correlates with Portal Biliary Proliferation and Fibrosis in Biliary Atresia , 2005, Pediatric Research.

[114]  R. Tucker,et al.  Armed CD4+ Th1 effector cells and activated macrophages participate in bile duct injury in murine biliary atresia. , 2005, Clinical immunology.

[115]  A. Bruu,et al.  Extrahepatic bile duct atresia and viral involvement , 2005, Pediatric transplantation.

[116]  M. Davenport A challenge on the use of the words embryonic and perinatal in the context of biliary atresia , 2005, Hepatology.

[117]  R. Ward,et al.  Obstruction of extrahepatic bile ducts by lymphocytes is regulated by IFN-gamma in experimental biliary atresia. , 2004, The Journal of clinical investigation.

[118]  B. Aronow,et al.  Coordinate expression of regulatory genes differentiates embryonic and perinatal forms of biliary atresia. , 2004, Hepatology.

[119]  B. Aronow,et al.  Coordinate expression of regulatory genes differentiates embryonic and perinatal forms of biliary atresia , 2004 .

[120]  S. Sakaguchi Naturally arising CD4+ regulatory t cells for immunologic self-tolerance and negative control of immune responses. , 2004, Annual review of immunology.

[121]  B. Aronow,et al.  Genetic induction of proinflammatory immunity in children with biliary atresia , 2002, The Lancet.

[122]  F. Suchy,et al.  Cholestatic Liver Disease: Working Group Report of the First World Congress of Pediatric Gastroenterology, Hepatology, and Nutrition , 2002, Journal of pediatric gastroenterology and nutrition.

[123]  W. Verhagen,et al.  Immunological gap in the infectious animal model for biliary atresia. , 2001, The Journal of surgical research.

[124]  C. Samuel,et al.  Antiviral Actions of Interferons , 2001, Clinical Microbiology Reviews.

[125]  D. Dawson,et al.  Cytomegalovirus and Human Herpesvirus 6, but Not Human Papillomavirus, Are Present in Neonatal Giant Cell Hepatitis and Extrahepatic Biliary Atresia , 2000, Pediatric and developmental pathology : the official journal of the Society for Pediatric Pathology and the Paediatric Pathology Society.

[126]  R. Drut,et al.  Presence of human papillomavirus in extrahepatic biliary atresia. , 1998, Journal of pediatric gastroenterology and nutrition.

[127]  K. Tyler,et al.  Detection of reovirus RNA in hepatobiliary tissues from patients with extrahepatic biliary atresia and choledochal cysts , 1998, Hepatology.

[128]  K. Schäkel,et al.  Detection of group C rotavirus in infants with extrahepatic biliary atresia. , 1996, The Journal of infectious diseases.

[129]  R. Lloyd,et al.  Reovirus 3 not detected by reverse transcriptase—mediated polymerase chain reaction analysis of preserved tissue from infants with cholestatic liver disease , 1995, Hepatology.

[130]  M. Davenport,et al.  Biliary atresia splenic malformation syndrome: an etiologic and prognostic subgroup. , 1993, Surgery.

[131]  P. Ogra,et al.  Group A Rotaviruses Produce Extrahepatic Biliary Obstruction in Orally Inoculated Newborn Mice , 1993, Pediatric Research.

[132]  R. Hall,et al.  Lack of correlation between infection with reovirus 3 and extrahepatic biliary atresia or neonatal hepatitis. , 1988, The Journal of pediatrics.

[133]  W. Balistreri,et al.  Role of reovirus type 3 in persistent infantile cholestasis. , 1984, The Journal of pediatrics.

[134]  M. Horwitz,et al.  Biliary atresia and reovirus type 3 infection. , 1982, The New England journal of medicine.

[135]  M. Odiévre,et al.  Immunoglobulin deposits in the biliary remnants of extrahepatic biliary atresia: a study by immunoperoxidase staining in 128 infants , 1981, Histopathology.

[136]  Chao-Long Chen,et al.  Expression of toll-like receptors and type 1 interferon specific protein MxA in biliary atresia , 2007, Laboratory Investigation.

[137]  Y. Goltsev,et al.  Tumor necrosis factor receptor and Fas signaling mechanisms. , 1999, Annual review of immunology.

[138]  P. Harper,et al.  Congenital biliary atresia and jaundice in lambs and calves. , 1990, Australian veterinary journal.

[139]  B. Landing Considerations of the pathogenesis of neonatal hepatitis, biliary atresia and choledochal cyst--the concept of infantile obstructive cholangiopathy. , 1974, Progress in pediatric surgery.

[140]  Landing Bh Considerations of the pathogenesis of neonatal hepatitis, biliary atresia and choledochal cyst--the concept of infantile obstructive cholangiopathy. , 1974 .

[141]  J. Spillane,et al.  The clinical aspects. , 1962, Proceedings of the Royal Society of Medicine.