Regulatory T Cells in Autoimmune Hepatitis: Unveiling Their Roles in Mouse Models and Patients.

Autoimmune hepatitis (AIH) is a severe and chronic liver disease, and its incidence has increased worldwide in recent years. Research into the pathogenesis of AIH remains limited largely owing to the lack of suitable mouse models. The concanavalin A (ConA) mouse model is a typical and well-established model used to investigate T cell-dependent liver injury. However, ConA-induced hepatitis is acute and usually disappears after 48 h; thus, it does not mimic the pathogenesis of AIH in the human body. Several studies have explored various AIH mouse models, but as yet there is no widely accepted and valid mouse model for AIH. Immunosuppression is the standard clinical therapy for AIH, but patient side effects and recurrence limit its use. Regulatory T cells (Tregs) play critical roles in the maintenance of immune homeostasis and in the prevention of autoimmune diseases, which may provide a potential therapeutic target for AIH therapy. However, the role of Tregs in AIH has not yet been clarified, partly because of difficulties in diagnosing AIH and in collecting patient samples. In this review, we discuss the studies related to Treg in various AIH mouse models and patients with AIH and provide some novel insights for this research area.

Different sites of xenoantigen delivery lead to a virally induced late-onset hepatitis in mice through molecular mimicry.

BACKGROUND: Epidemiological and laboratory evidences led to the hypothesis that molecular mimicry between viruses and self-proteins could be linked to the onset of autoimmune hepatitis (AIH). Hepatotropic viruses could be good candidates, as a pro-inflammatory environment may facilitate the development of AIH. AIMS: The aims of this study were to test a virus ability to induce an AIH through molecular mimicry and the influence of hepatic inflammation in this process. METHODS: C57BL/6 mice were injected i.v. or i.m. with recombinant adenoviral vectors (RecAdV) encoding for human type 2 AIH antigens to target xenoantigens expression in the liver and to create a transient hepatitis (i.v.) or for 'peripheral' xenoantigens expression (i.m.). Liver injury and B-cell response were evaluated. RESULTS: Late-onset hepatitis was observed 8 months after i.v. or i.m. RecAdV injections, despite presence or absence of an initial transient hepatitis. Intensity of B-cell response was similar for both type of injections, but the Ig isotypes produced were different. B-cell autoimmune response spread to several liver proteins. CONCLUSIONS: Liver autoimmune response can be initiated using molecular mimicry over a long period of time, validating the hit-and-run hypothesis. Initial liver inflammatory injury is neither necessary, nor detrimental to the development of AIH. These results highlight the significance of initial events on the pathogenesis of autoimmune liver injury.

Autoimmune hepatitis: evolving concepts.

The liver is continuously exposed to a large antigenic load that includes pathogens, toxins, tumor cells and dietary antigens. A loss of tolerance against its own antigens may result in autoimmune hepatitis (AIH). The current paradigm holds that the disease is the result of self-perpetuating autoimmune process triggered by yet unknown factors (infections, chemicals, drugs) in a genetically susceptible host. To date, several putative hepatocellular surface antigens have been identified: P450-IID6 (recognized by the anti-LKM-1 autoantibodies) a membrane bound asialoglycoprotein receptor (a liver-specific membrane protein), a cytosolic UGA-suppressor tRNA associated protein (recognized by anti-SMA and anti-LP antibodies) and argininosuccinate lysate and formiminotransferase cyclodeaminase (recognized by ant-LC1 antibodies). In contrast to other chronic hepatitides patients with AIH display significant T cell hypereactivity to autologous liver antigens. Tissue injury seems to be mediated by CD4+ or CD8+ T cells and/or by antibody-dependent cell mediated cytotoxicity.

Anti-LC1 autoantibodies in patients with chronic hepatitis C virus infection.

UNLABELLED: Various autoantibodies have been reported in patients chronically infected by hepatitis C virus. 2% to 10% of theses patients have anti-liver-kidney microsome type 1 (anti-LKM1) autoantibodies. In type 2 autoimmune hepatitis, anti-LKM1 autoantibodies are frequently associated with anti-liver-cytosol type 1 (anti-LC1) autoantibodies. AIMS: To determine the prevalence of anti-LC1 autoantibodies in a hepatitis C-positive population and characterize their reactivity. METHODS: 146 patients suffering from liver diseases, of which 99 were chronically infected by hepatitis C virus, were tested by Western blotting and immunoprecipitation to detect and characterize anti-LC1 autoantibodies. RESULTS: 12% of this hepatitis C population had anti-LC1 autoantibodies. LC1 positivity by Western blotting was 30% of LC1+ sera. Epitopes were found throughout the protein but linear epitopes were situated in the 395-541 amino acid region of formiminotransferase cyclodeaminase. Three putative conformational epitopes were identified by phage display. CONCLUSIONS: Anti-LC1 autoantibodies are as prevalent as anti-LKM1 autoantibodies in patients infected with hepatitis C virus and their production is not dependent of anti-LKM1 autoantibodies formation. Autoantibody reactivity against the anti-LC1 antigen is different in hepatitis C than in type 2 autoimmune hepatitis. Anti-LC1 autoantibodies can now be regarded as a serological marker of autoimmunity in chronic hepatitis C infection.

Characterization of the antigenicity of the formiminotransferase-cyclodeaminase in type 2 autoimmune hepatitis.

Human formiminotransferase-cyclodeaminase (hFTCD) is the autoantigen recognized by anti-liver cytosol type 1 (LC1) autoantibodies in type 2 autoimmune hepatitis (AIH) patients. In rats, this octameric protein is localized on the Golgi apparatus and binds brain microtubules (MTs) and vimentin. Subcellular localization of human formiminotransferase-cyclodeaminase and its implication in the pathogenesis of autoimmune hepatitis are unknown. Localization of the human formiminotransferase-cyclodeaminase in human hepatocytes was done using indirect immunofluorescence and subcellular fractionations followed by in vitro binding techniques. The formiminotransferase-cyclodeaminase antigen at two distinct locations in hepatocytes, free in the cytosol and associated with the Golgi membranes are recognized by anti-liver cytosol type 1 autoantibodies. The human formiminotransferase-cyclodeaminase binds reversibly to the Golgi membranes and this complex formation is increased by anti-liver cytosol type 1 autoantibodies. Finally, human formiminotransferase-cyclodeaminase does not interact with liver-specific cytoskeleton proteins. Anti-liver cytosol type 1 autoantibodies are directed against the mature high molecular form of human formiminotransferase-cyclodeaminase. Therefore, the subcellular location of the protein may influence the production of autoantibodies and their role in the pathogenesis of type 2 autoimmune hepatitis. This antigen-driven response does not appear to be facilitated or enhanced by a possible interaction between human formiminotransferase-cyclodeaminase and hepatocyte cytoskeleton proteins.

Characterization of the B cell response of patients with anti-liver cytosol autoantibodies in type 2 autoimmune hepatitis.

Anti-liver cytosol type 1 (LC1) autoantibody is detected in 30% of sera from patients with type 2 autoimmune hepatitis (AIH), and is the only circulating autoantibody in 10% of cases. Human formiminotransferase cyclodeaminase (FTCD) has been shown to be the specific liver antigen recognized by anti-LC1 autoantibodies. The aim of this study was to identify the dominant epitope on human FTCD and to analyze antigenic-site sequences for clues on the development of AIH. Recombinant proteins and peptides covering the entire cDNA of human FTCD were tested against anti-LC1 autoantibodies. Conformational epitopes were found throughout the protein but linear epitopes were found exclusively in the C-terminal 146 amino acids. Two groups of sera with different reactivities were found: 69%of the sera recognized two specific linear epitopes at positions 428-434 (NTPEEKD) and 440-447 (LQEGLRRA) of human FTCD; others reacted only with a discontinuous epitope between the amino acids at position 395 and 528. FTCD autoantibody production is thus a polyclonal-antigen-driven B cell response. Autoantibodies against conformational or discontinuous epitopes were found in all patients and two-thirds also recognized linear epitopes on human FTCD.

Distinct epitopes on formiminotransferase cyclodeaminase induce autoimmune liver cytosol antibody type 1.

Liver cytosol antibody type 1 (LC1) is regarded as a serologic marker of type 2 autoimmune hepatitis, in addition to liver kidney microsomal antibody type 1. Among 38 patients with type 2 autoimmune hepatitis, 23 were positive for LC1 antibodies. The antigen recognized by LC1 has been identified as a liver-specific 58-kd metabolic enzyme named formiminotransferase cyclodeaminase (FTCD). All 23 LC1-positive sera immunoprecipitated rat FTCD, and 22 gave an identity reaction with rat FTCD by immunodiffusion. No reaction was observed with sera from 10 patients with type 1 autoimmune hepatitis, 10 with primary biliary cirrhosis, 10 with chronic hepatitis C, and 10 healthy controls. By Western immunoblotting all 23 LC1-positive sera and all the controls tested negative, suggesting that all the antigenic epitopes were destroyed by denaturation. FTCD is a bifunctional protein composed of distinct globular FT and CD domains connected by a short linker. To identify epitopes that trigger the LC1 autoimmune response, we tested LC1 antibodies against FTCD constructs encoding the N-terminal FT domain (amino acids 1-339), or the C-terminal CD domain (amino acids 332-541). Of 20 sera positive against full-length FTCD, 8 (40%) recognized the FT domain and the CD domain, 7 (35%) recognized only the FT domain, and 5 (25%) did not recognize either construct. No sera reacted with only the CD domain. These data indicate that multiple regions of FTCD trigger the LC1 autoimmune response, and that LC1 reactivity is mainly directed to conformation-sensitive epitopes located in the FT region of FTCD.

Formiminotransferase cyclodeaminase is an organ-specific autoantigen recognized by sera of patients with autoimmune hepatitis.

BACKGROUND & AIMS: Anti-liver cytosol type 1 autoantibodies have been reported in association with anti-liver-kidney microsome type 1 autoantibodies in 30% of patients with autoimmune hepatitis type II. In 10% of cases, anti-liver cytosol type 1 antibodies are the only liver-related circulating autoantibodies. The liver cytosol antigen is a liver-specific 62-kilodalton protein present in the cell as an oligomer of approximately 240 kilodaltons. The aim of this study was to identify the antigen recognized by anti-liver cytosol antibody. METHODS: To identify the liver cytosol antigen, an anti-liver cytosol type 1-positive serum was used for the screening of a complementary DNA library from HepG2 cells. Double immunodiffusion method was used to show the identity between the cytosolic and the cloned protein. RESULTS: The sequence of two isolated clones showed 85.2% homology with the formiminotransferase cyclodeaminase (FTCD) enzyme from pig liver. Antibodies purified by affinity with the recombinant protein and sera from mice immunized with FTCD recognized a 62-kilodalton human cytosolic protein when tested by immunoblot. The identity of precipitation lines was found between the cytosolic antigen and FTCD. CONCLUSIONS: This enzyme is a liver-specific antigen recognized by the sera of patients with autoimmune hepatitis.

Immunological relatedness of histidine ammonia-lyases from some species of Pseudomonas: taxonomic implication.

1. Histidine ammonia-lyases (histidase EC 4.3.1.3) from Pseudomonas testosteroni NCIB 10808 and Pseudomonas putida NCIB 10807 were purified and specific antibody was raised to each separately in a rabbit. 2. Immunological cross-reactions of each antibody to histidine ammonia-lyases from various species of Pseudomonas were examined by the enzyme inhibition test. 3. The immunological data obtained suggest that these Pseudomonas species can be classified into three groups. These cross-reactions tend to indicate a certain degree of homology within species in a group but not between groups.