Immune tolerance split between hepatitis B virus precore and core proteins

The function of the hepatitis B virus (HBV) precore or HBeAg is largely unknown because it is not required for viral assembly, infection, or replication. However, the HBeAg does appear to play a role in viral persistence. It has been suggested that the HBeAg may promote HBV chronicity by functioning as an immunoregulatory protein. As a model of chronic HBeAg exposure and to examine the tolerogenic potential of the HBV precore and core (HBcAg) proteins, HBc/HBeAg-transgenic (Tg) mice crossed with T cell receptor (TCR)-Tg mice expressing receptors for the HBc/HBeAgs (i.e., TCR-antigen double-Tg pairs) were produced. This study revealed three phenotypes of HBe/HBcAg-specific T-cell tolerance: (i) profound T-cell tolerance most likely mediated by clonal deletion, (ii) T-cell clonal ignorance, and (iii) nondeletional T-cell tolerance mediated by clonal anergy and dependent on the structure, location, and concentration of the tolerogen. The secreted HBeAg is significantly more efficient than the intracellular HBcAg at eliciting T-cell tolerance. The split T-cell tolerance between the HBeAg and the HBcAg and the clonal heterogeneity of HBc/HBeAg-specific T-cell tolerance may have significant implications for natural HBV infection and especially for precore-negative chronic hepatitis.     

Production of hepatitis delta virus and suppression of helper hepatitis B virus in a human hepatoma cell line.

The hepatitis delta virus (HDV) is a defective virus with a coat composing of the surface antigen of its helper virus, hepatitis B virus (HBV). Replication of HDV in the absence of HBV has been shown in cell cultures by transient transfection of the HDV plasmid. However, the formation and release of HDV virions have not been observed. In this report, a human hepatoma cell line HuH-7 was transiently cotransfected with HDV and HBV plasmids. The production of monomeric and multimeric antigenomic RNAs of HDV in the transfected cells indicated replication of the HDV genome. The major 3.5- and 2.1-kb RNAs of HBV were also expressed. Virions of both HDV and HBV were released from the cotransfected cells, as shown by the detection of monomeric genomic HDV RNA and partially double-stranded HBV DNA in the culture medium. Thus, this is the first report that describes the assembly and the release of HDV viral particles in an in vitro cell culture. The HDV virions released possessed physicochemical properties identical to those of the HDV virions found in infected human serum. Furthermore, expression of both the 3.5- and 2.1-kb RNAs of HBV was shown to be dramatically decreased by the presence of HDV, indicating suppression of the expression of HBV genes by HDV. The amount of HBV virions released was similarly suppressed by HDV. Cotransfection of HBV with an expression plasmid of the HDV delta antigen remarkably reduced the levels of the 3.5- and 2.1-kb HBV RNAs, indicating that suppression of the expression of HBV RNAs by HDV occurs via the action of the delta antigen. This HBV- and HDV-cotransfected human hepatoma cell line should provide an excellent system for the study of the function of the delta antigen and the interaction between HDV and its helper, HBV.     

Immune recruitment or suppression by glycan engineering of endogenous and therapeutic antibodies

Human serum IgG contains multiple glycoforms which exhibit a range of binding properties to effector molecules such as cellular Fc receptors. Emerging knowledge of how the Fc glycans contribute to the antibody structure and effector functions has opened new avenues for the exploitation of defined antibody glycoforms in the treatment of diseases. Here, we review the structure and activity of antibody glycoforms and highlight developments in antibody glycoengineering by both the manipulation of the cellular glycosylation machinery and by chemoenzymatic synthesis. We discuss wide ranging applications of antibody glycoengineering in the treatment of cancer, autoimmunity and inflammation. This article is part of a Special Issue entitled "Glycans in personalised medicine" Guest Editor: Professor Gordan Lauc.     

Multiplication of hepatitis B virus in fulminant hepatitis B.

The presence in serum of hepatitis B e antigen (HBeAg) and hepatitis B virus DNA, which are each regarded as reflecting multiplication of hepatitis B virus, were looked for one to five days after the onset of hepatic encephalopathy in 64 patients with fulminant hepatitis B. HBeAg and hepatitis B virus DNA were found in the serum of only 24 (37%) and six (9%) patients, respectively. Hepatitis B virus DNA was absent from the serum in all 13 patients positive for anti-HBs. These findings indicate that replication of hepatitis B virus stopped after the onset of hepatic encephalopathy in most of the patients and support the view that an enhanced immune response stops the replication. Agents that inhibit viral multiplication would probably not have any effect at this stage of the disease.     

Prevalence of hepatitis B virus in chronic hepatitis B patients

The aim of the current study was to detect HBV by Real time - PCR in chronic hepatitis B patients. Fifty-eight sera of chronic hepatitis B patients were subjected during the period March 2009 to April 2010 in Ilam cities in West of Iran. Sera assayed by real-time PCR and ELISA methods. Twenty serum samples from healthy volunteers and non-hepatitis B patients and negative for hepatitis B seromarkers served as negative controls for the study. Among fifty-eight sera, ELISA showed fifty-five (94.8%) of the samples were positive for HBsAg and three (5.2%) negative results obtained while real-time PCR specified fifty-eight (100%) positive results in chronic hepatitis B patients. HBsAg status did not necessarily reflect HBV DNA level in the serum, as 5.2% of chronic Hepatitis B patients were positive for HBV DNA but negative for HBsAg. HBV DNA was not found to be positive amongst any of the negative controls. Real time - PCR is a sensitive and reproducible assay for HBV DNA quantization.     

Immune downregulation leads to upregulation of an antiviral response: a lesson from the hepatitis B virus

Induction of tolerance towards antigens that drive susceptibility or pathology may be considered a new mode of treatment for several infections. Hepatitis B virus is a non-cytopathic virus, and oral immune regulation was shown to be effective in modulation of the immune-mediated liver injury.     

减毒HAV在体外抑制HBV表达HBeAg和HBsAg的实验研究

目的　探索减毒甲型肝炎病毒( HAV) ( H2减毒株)在Hep G2 .2 .15细胞中对乙型肝炎病毒( HBV)表达HBs Ag和HBe Ag的影响。方法　在Hep G2 .2 .15细胞中,加入含3×10 - 2 ( 3×10 4 .5CCID50 / ml) ,3×10 - 3( 3×10 3.5CCID50 / ml)浓度的减毒HAV。按不同疫苗浓度,每4 d换液1次,留取第12和第16天的培养上清液;同时设立对照组。用微粒子酶免分析法检测培养上清液中的HBs Ag和HBe Ag含量。计算减毒HAV在不同浓度,以及不同作用时间长度的条件下,对Hep G2 .2 .15细胞表达HBs Ag和HBe Ag的影响。结果　3×10 - 2 Ampoule/ ml的减毒HAV作用Hep G2 .2 .5细胞12 d后,培养上清液的HBe Ag浓度为( 4 7.2 3±6 .18) S/ CO,低于对照组的( 10 1.15±15 .77) S/ CO,2组比较差异有非常显著性( P<0 .0 1) ;16 d后,上清液HBe Ag含量为( 4 0 .2 7±13.30 ) S/ CO,也显著低于对照组的( 6 5 .85±3.4 6 ) S/ CO( P<0 .0 5 ) ;HBs Ag含量为( 2 .6 8±0 .31) S/ N,低于对照组的( 5 .10±1.2 7)S/ N,差异有显著性( P<0 .0 5 )。而3×10 - 3Ampoule/ ml的减毒HAV作用Hep G2 .2 .15细胞12 d后,培养上清液的HBs Ag浓度与对照组比较有显著性下降( P<0 .0 5 )。结论　一定浓度的减毒HAV可能有直接抑制HBV表达HBs Ag,HBe Ag的作用     

Immunopathogenesis of hepatitis B virus infection

Hepatitis B virus (HBV) infection is a non-cytopathic hepatotropic virus that can lead to severe liver disease including acute hepatitis, cirrhosis and hepatocellular carcinoma. Successful clearance of the virus as well as the establishment of liver disease is largely driven by a complex interaction between the virus and the host immune response. In this review, the immunological events, including both the innate and adaptive immune response are discussed in the setting of both acute and chronic HBV infection and liver disease.     

Dynamics of hepatitis B virus infection

Mathematical models of the dynamics of HIV and hepatitis C virus infection have proven to be of great utility in understanding pathogenesis and designing better treatments. Here, we review the state of the art in modeling and interpreting data obtained from hepatitis B virus infected patients treated with antiviral agents.     

Structure of the hepatitis B virus genome.

The extent and position of the single-stranded gap in DNA molecules from Dane particles isolated from two donors of the adw serotype were determined by molecular hybridization and electron microscopic methods. The results showed that in each preparation more than 99% of the circular molecules are of uniform length and contain both single- and double-stranded regions. They confirmed that one end of the short strand is fixed with respect to the single EcoRI site within the molecule and to the nick in the long strand, but they also showed that although the position of the other end is variable, there is a preferred minimum length of about 650 to 700 nucleotides for the single-stranded region.     

Molecular evolution of the hepatitis B virus genome

The hepatitis B virus (HBV) has a circular DNA genome of about 3,200 base pairs. Economical use of the genome with overlapping reading frames may have led to severe constraints on nucleotide substitutions along the genome and to highly variable rates of substitution among nucleotide sites. Nucleotide sequences from 13 complete HBV genomes were compared to examine such variability of substitution rates among sites and to examine the phylogenetic relationships among the HBV variants. The maximum likelihood method was employed to fit models of DNA sequence evolution that can account for the complexity of the pattern of nucleotide substitution. Comparison of the models suggests that the rates of substitution are different in different genes and codon positions; for example, the third codon position changes at a rate over ten times higher than the second position. Furthermore, substantial variation of substitution rates was detected even after the effects of genes and codon positions were corrected; that is, rates are different at different sites of the same gene or at the same codon position. Such rates after the correction were also found to be positively correlated at adjacent sites, which indicated the existence of conserved and variable domains in the proteins encoded by the viral genome. A multiparameter model validates the earlier finding that the variation in nucleotide conservation is not random around the HBV genome. The test for the existence of a molecular clock suggests that substitution rates are more or less constant among lineages. The phylogenetic relationships among the viral variants were examined. Although the data do not seem to contain sufficient information to resolve the details of the phylogeny, it appears quite certain that the serotypes of the viral variants do not reflect their genetic relatedness. Correspondence to: Z. Yang     

Hybrid hepatitis B virus nucleocapsid bearing an immunodominant region from hepatitis B virus surface antigen.

A hepatitis B core antigen (HBcAg) gene bearing the 39-amino-acid-long domain A of hepatitis B surface antigen (HBsAg) within the HBcAg immunodominant loop has been constructed and expressed in Escherichia coli. Chimeric capsids demonstrated HBs but not HBc antigenicity and elicited in mice B-cell and T-cell responses against native HBcAg and HBsAg.     

Natural history and treatment of hepatitis B virus and hepatitis C virus coinfection

Hepatitis B virus (HBV) and hepatitis C virus (HCV) coinfection is not uncommon as a result of similar routes of infection. Patients who are coinfected represent a unique group with diverse serologic profiles. Combined chronic hepatitis B and C leads to more severe liver disease and an increased risk of hepatocellular carcinoma. Furthermore, coinfected patients represent a treatment challenge. No standard recommendations exist for treatment of viral hepatitis due to dual HBV/HCV infection, and therefore treatment must be individualized based on patient variables such as serologic and virologic profiles, patient's prior exposure to antiviral treatment, and the presence of other parenterally transmitted viruses such as hepatitis D virus and human immunodeficiency virus. The natural history and treatment of patients with HBV and HCV coinfection is reviewed.     

Characterization of hepatitis B virus DNA polymerase

Hepatitis B virus (HBV) particles were separated from the blood-plasma containing HBe and HBs antigens (subtype adr) and the nature of the endogenous DNA polymerase in the HBV core particles was studied. The HBV endogenous DNA polymerase activity was examined under the conditions used for preparation of HBV vaccine. The endogenous DNA polymerase activity was reduced slowly upon the heat treatment or the formalin treatment. The reductions of the activity were 65% and 70% upon the heat treatment at 60 C for 10 hr and the formalin treatment at 37 C for 90 hr, respectively. Properties of the HBV endogenous DNA polymerase were studied by utilizing specific inhibitors against the eukaryotic DNA polymerases. Our results showed that the HBV endogenous DNA polymerase is resistant to aphidicolin and N-ethylmaleimide, and sensitive to 2',3'-dideoxythymidine 5'-triphosphate, phosphonoformic acid and 9-beta-D-arabinofuranosyladenosine 5'-triphosphate.