Pathology and pathogenesis of intrahepatic bile duct loss

In recent years, the pathology and pathogenesis of bile duct loss have been extensively studied, and a num‐ber of hepatobiliary diseases have been added to the list of ductopenic diseases. In addition, the biology of biliary epithelial cells is now being studied with respect to bile duct loss, as well as biliary epithelial neoplasia. In this review, recent advances in pathogenetic and pathological studies of intrahepatic bile duct loss are described, with an emphasis on immune‐mediated cholangiopathies. The bile duct loss, an acquired and pathologic process that occurs in the biliary tree, is recognizable as an absence of bile duct in an individual portad tract, and also as such absence in the vicinity of parallel running hepatic arterial branches that constitute the portal triad. Immunostaining with biliary cytokeratin and other carbohydrate materials is useful for the identification of biliary elements in the inflamed portal tracts or fibrous septa. The underlying processes responsible for bile duct loss include immunological, ischemic, infectious, metabolic, and toxic processes. Bile duct loss in primary biliary cirrhosis and primary sclerosing cholangitis is immune‐mediated, that in interventional radiology using hepatic arterial branches is related to biliary ischemia, while that in hepatic allograft rejection is related to both immunological and ischemic insults. Bacterial and viral cholangitis with bile duct loss is an example of infectious cholangitis. The biliary tree maintains its homeostasis by renewal and dropout, and bile duct loss occurs mainly via biliary apoptosis. In some patients with bile duct loss, such as occurs in drug‐induced injuries, the bile ducts regenerate and finally redistribute in the liver, while in other types of bile duct loss, the loss is progressive and is followed by vanishing bile duct syndrome, leading to biliary cirrhosis or liver transplantation. More analysis of the biology of biliary epithelial cells is mandatory for the evaluation of the pathobiology of bile duct loss, as well as for the effective restoration of biliary epithelial cells, in ductopenic liver diseases.     

Electron microscopic observation of destruction of biliary epithelium in primary biliary cirrhosis

ABSTRACT— Electron microscopic studies of the intrahepatic biliary tree in 16 patients with primary biliary cirrhosis (PBC) disclosed four types of biliary epithelial injury suggesting cell death in the ducts: 1) coagulative and 2) lytic necrosis without detachment of affected cells from the biliary epithelial layer, and 3) apoptosis and 4) detachment of several adjoining biliary cells from the basement membrane and neighboring biliary cells. Lesions 1), 2) and 3) were also found in livers with extrahepatic cholestasis without bile duct loss, and 1) and 2) were found in PBC livers irrespective of the degree of bile duct loss. 3) was rare and mostly confined to bile ductules, when present. By contrast, 4) was only observed in PBC, especially in livers with a moderate degree of bile duct loss in which extensive bile duct destruction appeared to be progressing. Detached biliary cells in lesion 4) were occasionally in contact with and/or surrounded by migrating lymphocytes with pseudopod formation, suggesting lymphocyte-target cell interactions. It therefore seems possible that epithelial detachment is an important ultrastructural lesion associated with extensive bile duct destruction in PBC livers.     

Frequent expression of MUC1 apomucin on biliary epithelial cells of damaged small bile ducts in primary biliary cirrhosis and chronic viral hepatitis: An immunohistochemical study

MUC1 apomucin is a specific target tumor antigen recognized by cytotoxic T cells in a major histocompatibility complex (MHC) unrestricted fashion in patients with pancreatic and breast cancer. This T-cell-mediated immune mechanism against MUC1 apomucin expressing cells has not been evaluated in nonneoplastic immune-mediated diseases. Therefore, we immunohistochemically surveyed the expression of MUC1 apomucin on biliary epithelial cells of small bile ducts in various hepatobiliary diseases, including primary biliary cirrhosis (PBC). MUC1 apomucin was detected using the monoclonal antibody DF3 and the streptavidin-biotin complex, in livers from 31 patients with PBC, 67 with chronic viral hepatitis (CH) with or without cirrhosis, 31 with extrahepatic biliary obstruction (EBO), 30 with hepatolithiasis, and from 23 normal individuals. MUC1 apomucin was infrequently and focally expressed in the biliary epithelial cells of the small bile ducts in 3 of 23 normal livers. In contrast, MUC1 apomucin was frequently and strongly expressed on the luminal surface of biliary epithelia] cells of small bile duct, in 22 of 31 patients with PBC, and in 50 of 67 patients with CH. In particular, high levels of MUC1 apomucin were expressed in bile ducts showing chronic nonsuppurative destructive cholangitis (CNSDC) in PBC and hepatitic duct injuries in CH. In EBO and hepatolithiasis, MUC1 apomucin was focally and weakly expressed in 29% and 30% of livers examined, respectively. More MUC1 apomucin was expressed in PBC and CH than in EBO, hepatolithiasis, and normal liver (P < .01, respectively). Frequent and high luminal expression of MUC1 apomucin on biliary epithelial cells in damaged small bile ducts in PBC and CH may be related to T-cell-mediated immunologic mechanisms in these diseases, probably by an MHC-unrestricted recognition process. (Hepatology 1996 Jun;23(6):1313-7)     

Destruction of bile ducts in primary biliary cirrhosis.

Primary biliary cirrhosis is characterized by the immune-mediated, progressive destruction of interlobular bile ducts. Lymphoid cells migrate into the biliary epithelial layer through integrin alpha(4)/fibronectin interaction and are responsible for chronic destructive cholangitis. The bile ducts express intercellular adhesion molecule-1 (ICAM-1) and vascular cellular adhesion molecule-1 (VCAM-1), and infiltrating lymphocytes express LFA1 and VLA4, facilitating their interaction. Epithelioid granulomas contain foamy cells ingesting biliary lipids, and CD1d was detectable in epithelioid granulomas, suggesting that the biliary substance(s) which are leaked is a trigger for chronic destructive cholangitis. Apoptotic biliary destruction is brought about by antigen-specific and non-specific reactions. Shrunken biliary epithelial cells with pyknotic nuclei positive for terminal deoxynucleotidyl transferase-mediated deoxyuridine triphosphate nick-end labelling (TUNEL) may reflect apoptotic processes. Increased expression of caspase-3 and -8 with DNA fragmentation factor on the bile ducts may reflect molecular events during apoptosis, and down-regulation of Bcl-2 of biliary epithelial cells seems to facilitate apoptosis. Multiple factors, particularly the Fas system, are stimuli of apoptosis. Anoikis with decreased biliary expression of integrin 6, a ligand for laminin, may also be involved in biliary epithelial apoptosis.     

Expression of intercellular adhesion molecule-1 and lymphocyte function-associated antigen-1 protein and messenger RNA in primary biliary cirrhosis

OBJECTIVE: This study examined the role of intercellular adhesion molecule-1 (ICAM-1) and lymphocyte function-associated antigen-1 (LFA-1) in the autoimmune process of bile duct destruction in the early stages of primary biliary cirrhosis (PBC). MATERIALS AND METHODS: Ten PBC liver samples and five control samples were studied. Immunohistochemical studies of ICAM-1 and LFA-1, and Western blot of ICAM-1 were performed. Immunoelectron microscopy was conducted using immunoglobulin-gold and silver staining. Human ICAM-land LFA-1 peptide nucleic acid probes were used for in situ hybridization. RESULTS: In PBC liver samples, immunohistochemistry showed aberrant ICAM-1 expression on bile duct epithelial plasma membrane and also luminal sites of endothelial plasma membrane of terminal portal venules. Western blot confirmed ICAM-1 protein expression. LFA-1-positive lymphocytes were associated with epithelial cells of septal and interlobular bile ducts. Immunoelectron microscopy localized ICAM-1 on the luminal and basal surfaces as well as on lymphocytes around damaged bile duct epithelial cells, and LFA-1 on lymphocytes around damaged bile ducts. Messenger RNA expression of ICAM-1 was demonstrated in bile ducts, and LFA-1 in lymphocytes around bile ducts. CONCLUSION: De novo expression of ICAM-1 and LFA-1 at protein and mRNA levels in PBC may imply an inductive role of ICAM-1 through binding with its ligand LFA-1 in the extravasation of activated lymphocytes and lymphocyte-mediated bile duct destruction.     

原发性胆汁性肝硬化免疫分子机制研究进展

原发性胆汁性肝硬化(primary biliary cirrhosis,PBC)是一种免疫介导损伤胆管上皮细胞及肝内小胆管的胆汁淤积性自身免疫性肝病,具有发展为肝硬化的倾向.多种免疫相关基因通过影响疾病易感性、免疫调节等途径,促使PBC的发生、发展.本文就PBC的免疫分子机制研究动态进行综述.     

Primary biliary cirrhosis and other ductopenic diseases

Several distinct conditions are characterized by a reduction in the number of small and medium-sized intrahepatic bile ducts. These diseases are associated with progressive cholestasis, which in turn leads to biliary fibrosis and ultimately cirrhosis. The best-characterized ductopenic condition in adulthood is primary biliary cirrhosis (PBC) for which there is now strong evidence of an autoimmune cause. The antigenic targets are epitopes on proteins of the 2-oxoacid dehydrogenase complex within mitochondria. Some of these proteins appear to be aberrantly expressed at the surface of cholangiocytes in PBC. The basis for the breakdown in tolerance remains uncertain, although there is recent evidence to indicate that apoptosis may play a key role at early stages in the pathogenesis of the disease. Related conditions include autoimmune overlap syndromes and AMA-negative PBC (autoimmune cholangitis). Primary sclerosing cholangitis is clinically and histologically distinct, although there is evidence that it also may have an immune-mediated cause. Ductopenia may also arise on the basis of drug-induced injury; the best example of this is progressive cholestasis complicating chlorpromazine therapy.     

Heterogeneity of the intrahepatic biliary epithelium

The objectives of this review are to outline the recent findings related to the morphological heterogeneity of the biliary epithelium and the heterogeneous pathophysiological responses of different sized bile ducts to liver gastrointestinal hormones and peptides and liver injury/toxins with changes in apoptotic, proliferative and secretory activities. The knowledge of biliary function is rapidly increasing because of the recognition that biliary epithelial cells (cholangiocytes) are the targets of human cholangiopathies, which are characterized by proliferation/damage of bile ducts within a small range of sizes. The unique anatomy, morphology, innervation and vascularization of the biliary epithelium are consistent with function of cholangiocytes within different regions of the biliary tree. The in vivo models [e.g., bile duct ligation (BDL), partial hepatectomy, feeding of bile acids, carbon tetrachloride (CCl4) orα-naphthylisothiocyanate (ANIT)] and the in vivo experimental tools [e.g., freshly isolated small and large cholangiocytes or intrahepatic bile duct units (IBDU) and primary cultures of small and large murine cholangiocytes] have allowed us to demonstrate the morphological and functional heterogeneity of the intrahepatic biliary epithelium. These models demonstrated the differential secretory activities and the heterogeneous apoptotic and proliferative responses of different sized ducts. Similar to animal models of cholangiocyte proliferation/injury restricted to specific sized ducts, in human liver diseases bile duct damage predominates specific sized bile ducts. Future studies related to the functional heterogeneity of the intrahepatic biliary epithelium may disclose new pathophysiological treatments for patients with cholangiopathies.     

Telomere shortening in the damaged small bile ducts in primary biliary cirrhosis reflects ongoing cellular senescence

Telomere shortening is a trigger of cellular senescence. Biliary epithelial cells in damaged small bile ducts in primary biliary cirrhosis (PBC) show senescent features such as the expression of senescence-associated beta-galactosidase and the increased expression of p16(INK4a) and p21(WAF1/Cip1). We investigated whether the telomere shortening is involved in the pathogenesis of biliary cellular senescence in PBC. We analyzed the telomere length of biliary epithelial cells using quantitative fluorescence in situ hybridization in livers taken from the patients with PBC (n = 13) and control livers (n = 13). We also assessed immunohistochemically the prevalence of DNA damage and the expression of p16(INK4a) and p21(WAF1/Cip1). The study showed a significant decrease in telomere length in biliary epithelial cells in the damaged small bile ducts and bile ductules in PBC compared with normal-looking bile ducts and bile ductules in PBC, chronic viral hepatitis, and normal livers (P < 0.01). gammaH2AX-DNA-damage-foci were detected in biliary epithelial cells in damaged small bile ducts and bile ductules in PBC but were absent in biliary epithelial cells in chronic viral hepatitis and normal livers. The expression of p16(INK4a) and p21(WAF1/Cip1) was increased corresponding to telomere shortening and gammaH2AX-DNA-damage-foci in the damaged small bile ducts in PBC. CONCLUSION: Telomere shortening and an accumulation of DNA damage coincide with increased expression of p16(INK4a) and p21(WAF1/Cip1) in the damaged bile ducts, characterize biliary cellular senescence, and may play a role in the following progressive bile duct loss in PBC.     

Primary biliary cirrhosis: modalities of injury and death in biliary epithelium

BACKGROUND/AIM: Despite the number of studies on primary biliary cirrhosis, contrasting data remain concerning modalities of cholangiocyte death. Liver biopsies obtained from 40 patients with anti mitochondrial antibody-positive primary biliary cirrhosis, at various stages of the disease, were examined, and special attention was paid to the expression of subcellular damage and evidence of apoptosis. METHODS: Liver sections were stained with haematoxylin/eosin or Sirius red. Ductular mass was evaluated on sections after cytokeratin 7 staining. Apoptosis was evaluated on haematoxylin/eosin stained material or after processing for terminal deoxynucleotidyl transferase-mediated dUTP nick end-labelling assay. In 16 patients, part of the biopsy was processed for electron microscopy. Twenty histologically normal liver biopsies were used for control purposes. RESULTS: According to Scheuer's classification, 29 patients were classified as stage I-II, and 11 as stage III-IV. A strong staining of bile ducts was evident after immunohistochemistry for cytokeratin 7, often associated with ductular metaplasia in lobular zone 1. Cytokeratin 7-positive cells occupied 3.0+/-1.3% of liver mass as compared to 0.25+/-0.03% in controls. Ductular metaplasia accounted for 1.4+/-0.07% of all cytokeratin 7-positive cells. Regardless of staging, apoptotic bodies were seen only exceptionally in epithelial wall of bile ducts, whereas cholangiocyte damage leading to extensive lytic necrosis appeared responsible for most of the bile duct mass loss, as also confirmed by ultrastructural studies. A few terminal deoxynucleotidyl transferase-mediated dUTP nick end-labelling-positive nuclei were occasionally associated with the inflammatory infiltrate and evidence of apoptosis in hepatocytes was frequent, especially in zone 1. CONCLUSION: Regardless of staging, lytic necrosis and not apoptosis accounts for most of the bile duct loss in primary biliary cirrhosis. Furthermore, ductular metaplasia appears as a late event with highly variable pattern being observed between patients.     

The finest branches of the biliary tree might induce biliary vascularization necessary for biliary regeneration

BACKGROUND/AIMS: The finer branches of the biliary tree play an important role in biliary regeneration. They are consistently escorted by microvessels. Defects in the vascularization of these structures could impair bile duct regeneration. Therefore, we investigated the pattern of the escorting microvessels during the development of bile duct loss in the human liver, using chronic rejection as a model. METHODS: The number of interlobular bile ducts, bile ductules and extraportal biliary cells with and without escorting microvessels and the expression of VEGF-A were studied in follow-up biopsies of 12 patients with chronic rejection and 16 control patients with acute rejection without progression to chronic rejection. RESULTS: The controls showed a proliferation of bile ductules at 1-week and 1-month. Proliferation of bile ductules without microvessels preceded proliferation of bile ductules with microvessels. Proliferation of the microvascular compartment followed biliary proliferation. This sequence of events was not observed in the chronic rejection group, in which all biliary structures decreased in time. VEGF-A expression was increased at 1-week and 1-month in both groups. CONCLUSIONS: An immediate proliferative response of the finer branches of the biliary tree followed by proliferation of the microvascular compartment after biliary injury seems to be a prerequisite for bile duct regeneration.     

Cellular and humoral autoimmunity directed at bile duct epithelia in murine biliary atresia

Biliary atresia is an inflammatory fibrosclerosing lesion of the bile ducts that leads to biliary cirrhosis and is the most frequent indication for liver transplantation in children. The pathogenesis of biliary atresia is not known; one theory is that of a virus-induced, subsequent autoimmune-mediated injury of bile ducts. The aim of this study was to determine whether autoreactive T cells and autoantibodies specific to bile duct epithelia are present in the rotavirus (RRV)- induced murine model of biliary atresia and whether the T cells are sufficient to result in bile duct inflammation. In vitro analyses showed significant increases in IFN-gamma-producing T cells from RRV-diseased mice in response to bile duct epithelial autoantigen. Adoptive transfer of the T cells from RRV-diseased mice into na?ve syngeneic SCID recipients resulted in bile duct-specific inflammation. This induction of bile duct pathology occurred in the absence of detectable virus, indicating a definite response to bile duct autoantigens. Furthermore, periductal immunoglobulin deposits and serum antibodies reactive to bile duct epithelial protein were detected in RRV-diseased mice. In conclusion, both cellular and humoral components of autoimmunity exist in murine biliary atresia, and the progressive bile duct injury is due in part to a bile duct epithelia-specific T cell-mediated immune response. The role of cellular and humoral autoimmunity in human biliary atresia and possible interventional strategies therefore should be the focus of future research.     

Temporal-spatial activation of apoptosis and epithelial injury in murine experimental biliary atresia

Biliary atresia is a fibro-inflammatory cholangiopathy that obstructs the extrahepatic bile ducts in young infants. Although the pathogenesis of the disease is undefined, studies in livers from affected children and neonatal mice with experimental biliary atresia have shown increased expression of proapoptosis molecules. Therefore, we hypothesized that apoptosis is a significant mechanism of injury to duct epithelium. To test this hypothesis, we quantified apoptosis using terminal transferase dUTP nick end labeling and active caspase-3 staining in livers and extrahepatic bile ducts from Balb/c mice infected with Rhesus rotavirus (RRV) within 24 hours of birth. RRV induced a significant increase in labeled cells in the portal tracts and in epithelial and subepithelial compartments of extrahepatic bile ducts, with onset within 3 days and peaks at 5-10 days. Exploring mechanisms of injury, we found increased biliary expression of caspases 1 and 4 and of interferon-gamma (IFNgamma)-related and tumor necrosis factor-alpha (TNFalpha)-related genes. Using a cholangiocyte cell line, we found that neither IFNgamma nor TNFalpha alone affected cell viability; however, simultaneous exposure to IFNgamma and TNFalpha activated caspase-3 and decreased cell viability. Inhibition of caspase activity blocked apoptosis and restored viability to cultured cholangiocytes. In vivo, administration of the caspase inhibitor IDN-8050 decreased apoptosis in the duct epithelium and the extent of epithelial injury after RRV challenge. Conclusion: The biliary epithelium undergoes early activation of apoptosis in a mouse model of biliary atresia. The synergistic role of IFNgamma and TNFalpha in activating caspase-3 in cholangiocytes and the decreased apoptosis following pharmacologic inhibition of caspases support a prominent role for apoptosis in the pathogenesis of experimental biliary atresia.     

Effector role of neonatal hepatic CD8+ lymphocytes in epithelial injury and autoimmunity in experimental biliary atresia

BACKGROUND & AIMS: Lymphocytes populate the livers of infants with biliary atresia, but it is unknown whether neonatal lymphocytes regulate pathogenesis of disease. Here, we investigate this question by examining the role of T lymphocytes in the destruction of extrahepatic bile ducts of neonatal mice using an experimental model of biliary atresia. METHODS: Inoculation of neonatal mice with rhesus rotavirus followed by multistaining flow cytometry to quantify expression of interferon-gamma by hepatic lymphocytes, and real-time polymerase chain reaction for mRNA expression of pro-inflammatory cytokines. This was followed by determining the consequences of antibody-mediated depletion of lymphocyte subtypes on the development of biliary obstruction, and coculture and cell transfer experiments to investigate the effector role of lymphocyte subtypes on neonatal biliary disease. RESULTS: Rotavirus infection results in overexpression of interferon-gamma by neonatal hepatic T cells. Among these cells, depletion of CD4(+) cells did not change the course of inflammatory injury and obstruction of neonatal bile ducts. In contrast, loss of CD8(+) cells remarkably suppressed duct injury, prevented luminal obstruction, and restored bile flow. Coculture experiments showed that rotavirus-primed, but not na?ve, CD8(+) cells were cytotoxic to cholangiocytes. In adoptive transfer experiments, we found that primed CD8(+) cells preferentially homed to extrahepatic bile ducts of neonatal mice and invaded their epithelial lining. CONCLUSIONS: Primed neonatal CD8(+) cells can activate a pro-inflammatory program, target diseased and healthy duct epithelium, and drive the phenotypic expression of biliary atresia, thus constituting a potential therapeutic target to halt disease progression.     

Bile duct cell apoptosis is a rare event in primary biliary cirrhosis

BACKGROUND: The frequency of apoptosis in bile duct cells of primary biliary cirrhosis is still unclear spanning from rare to 50% in the various reports. AIM: To study bile duct cell apoptosis in stage I primary biliary cirrhosis lesions. PATIENTS: Nine stage I-II biopsies with a total number of 26 bile ducts of different sizes, selected from a larger series on the basis of the expression on serial frozen sections of HLA-DR and Fas antigens. METHODS: Apoptosis was evaluated by a DNA fragmentation assay on frozen sections, according to the manufacturer's protocol and by expression of apoptosis related cytokeratin neoepitopes. Bile duct cell proliferation was assessed by MIB1 (Ki-67) expression. RESULTS: Apoptosis was frequently found in inflammatory cells of portal tracts and sinusoids. Apoptosis of hepatocytes was also systematically observed. Only 4 positive bile duct cells were found in 3 bile ducts from 3 biopsies. Quantitative evaluation was not attempted. Cholangiocyte proliferation was observed in the same ducts and occasionally in other biopsies. CONCLUSIONS: These data suggest that cholangiocyte death by apoptosis at the level of typical primary biliary cirrhosis lesions is a rare event, at least in early stages of the disease. The observed rate of proliferation was consistent with the rate of apoptosis.     

Significance of periductal Langerhans cells and biliary epithelial cell‐derived macrophage inflammatory protein‐3α in the pathogenesis of primary biliary cirrhosis

Background/aims: To clarify the primary biliary cirrhosis (PBC)‐specific antigen‐presenting mechanism, we examined the distribution and phenotypic characteristics of infiltrating dendritic cells (DCs) with respect to bile ducts and the mechanism of migration in terms of the periductal cytokine milieu and biliary innate immunity. Methods and results: Immunohistochemistry using liver sections from patients with PBC and controls revealed that blood dendritic cell antigen (BDCA)‐2⁺ plasmacytoid DCs were found mainly in the portal tracts in PBC and the controls, but their distribution was not related to bile ducts. BDCA‐1⁺ and CD19^? myeloid DCs were also found in portal tracts in PBC and the controls and, in particular, Langerin+Langerhans cells (LCs) were dominantly scattered around or within biliary epithelial layers of the damaged bile ducts in PBC. Moreover, experiments with cultured human biliary epithelial cells (BECs) showed that an LC‐attracting chemokine, macrophage inflammatory protein‐3α, was produced by BECs in the response to cytokines [interleukin (IL)‐1β, tumour necrosis factor‐α and IL‐17] and pathogen‐associated molecular patterns. Conclusions: LCs existing around or within biliary epithelial layers are important as periductal antigen‐presenting cells in PBC and the migration of LCs into bile ducts is closely associated with the periductal cytokine milieu and biliary innate immunity in PBC.     

Intracellular balance of oxidative stress and cytoprotective molecules in damaged interlobular bile ducts in autoimmune hepatitis and primary biliary cirrhosis: In situ detection of 8-hydroxydeoxyguanosine and glutathione-S-transferase-pi

Aim: Bile duct injury has been thought to be absent in autoimmune hepatitis (AIH), but recent studies have indicated that AIH patients do have bile duct injury. In this study, the intracellular balance of oxidative stress and cytoprotection in biliary epithelial cells was investigated to clarify the pathogenesis of bile duct injury in AIH. Methods: The intracellular status of oxidative DNA damage caused by oxidative stress and glutathione, an endogenous cytoprotective molecule, were examined in patients with AIH, primary biliary cirrhosis (PBC), and normal controls by immunostaining of 8-hydroxydeoxyguanosine (8-OHdG) and glutathione-S-transferase-pi. Results: Immunohistochemically, 8-OHdG expression was detected as abundantly in the damaged bile ducts of AIH patients as in PBC patients. Moreover, in AIH, 8-OHdG expression was detected in damaged bile ducts more than in undamaged bile ducts. Glutathione-S-transferase-pi expression was relatively preserved in the damaged bile ducts of AIH patients compared to PBC patients, reflecting preservation of intracellular glutathione. Conclusions: In AIH, oxidative stress and DNA damage may be involved in the pathogenesis of bile duct injury in a manner similar to that found in PBC. However, relatively preserved intracellular glutathione may play a key role in preventing progressive bile duct loss following bile duct injury in AIH.     

Fas ligand expressing mononuclear cells around intrahepatic bile ducts co-express CD68 in primary biliary cirrhosis

AIMS/BACKGROUND: Apoptosis, including the Fas system, has been implicated in progressive bile duct loss in primary biliary cirrhosis (PBC). In this study, we attempted to analyze Fas ligand (FasL) expressing mononuclear cells infiltrating in the portal tracts of PBC. METHODS: We immunohistochemically assessed co-expression of leukocyte markers and FasL on infiltrating mononuclear cells in 18 patients with PBC. Twenty-five patients with chronic hepatitis C (CH-C) were used as controls. RESULTS: In PBC, FasL expressing cells were scattered in the portal tracts, and some were accentuated around the damaged bile ducts. In addition, these cells co-expressed CD68 (71%), a marker of monocytes, but not UCHL-1, CD3 and CD57, markers of activated T cells and natural killer cells. By contrast, in CH-C, the biliocentric pattern of FasL expression was not evident, and about half of FasL expressing cells (42-56%) co-expressed UCHL-1, CD3 or CD57. CD14, a receptor for bacterial products such as lipopolysaccharides, was also detected on a proportion of FasL expressing mononuclear cells around the damaged bile ducts in PBC. CONCLUSION: The results suggest that in PBC, FasL expressing CD68+ monocytes are at least partly involved in apoptotic bile duct loss mediated by the Fas system, and a surface molecule, CD14, participates in this process.     

Site-characteristic expression and induction of trefoil factor family 1, 2 and 3 and malignant brain tumor-1 in normal and diseased intrahepatic bile ducts relates to biliary pathophysiology.

BACKGROUND/AIM: Trefoil factor family (TFF)1,2,3 are involved in a homeostasis/repair process of mucosal epithelia. In this study, the significance of TFF family and deleted in the malignant brain tumor-1 (DMBT1), a putative receptor of TFF2, in the intrahepatic biliary tree was investigated in normal and diseased livers. MATERIALS AND METHODS: Expression of TFF1,2,3 and DMBT1 were examined immunohistochemically in primary biliary cirrhosis (PBC), primary sclerosing cholangitis (PSC), chronic viral hepatitis (CVH), extrahepatic biliary obstruction (EBO), and normal livers. RESULTS: In normal livers, TFF1,3 and DMBT1 were infrequently detectable in large and rarely in small bile ducts, respectively. TFF2 was not detectable in large bile ducts. In large bile duct diseases (PSC and EBO), expression of TFF3 and DMBT1 were increased. In small bile duct diseases (PBC and CVH), expression of TFF2/DMBT1 was induced in moderately to severely damaged ducts irrespective of etiology. CONCLUSION: The intrahepatic biliary tree shows a site-characteristic expression and induction of TFF1,2,3 and DMBT1. In large bile ducts, TFF1,3 were constitutively expressed and increased in pathologic bile ducts. In small bile ducts, TFF2/DMBT1 is induced in damaged ducts irrespective of etiologies. However, the cytoprotective/repair property of TFF2/DMBT1 may not be enough to prevent the following bile duct loss in PBC.