Project description:Background & Aims: The precise mechanism underlying the attenuation of the antigen-specific B cell response induced by therapeutic vaccination during chronic HBV infection remains unclear. The development of vaccines or strategies targeting this impediment through rational design could potentially result in significant advancements in the treatment of chronic hepatitis B. Methods: A mouse model with a knock-in of a B cell receptor specific to the hepatitis B virus surface antigen was generated under the name E6F6-B. This model was utilized to investigate the temporal and spatial patterns of humoral responses induced by therapeutic vaccination in the presence of persistent antigen stimulation. Through the use of multiple transcriptome sequencing techniques, the differentiation trajectory of HBsAg-specific B cells post therapeutic vaccination during chronic hepatitis B infection was elucidated. Results: In light of the E6F6-B transfer model, a significant reduction in antibody secreting cells were observed two weeks after vaccination. Additionally, an atypical pre-plasma cell population (BLIMP-1+ IRF4+ CD40- CD138-) was identified as a consequence of persistent BCR signaling in the absence of CD40 co-stimulation. A therapeutic antibody-induced suppression of BCR signaling revitalized the HBsAg-specific B cell response.

Project description:Hepatitis B surface antigen (HBsAg) secretion may impact the immune response in chronic hepatitis B virus (HBV) infection. Therapeutic approaches to suppress HBsAg production are being investigated. Our study aims to examine the immunomodulatory effects of high and low levels of circulating HBsAg by analyzing single-cell RNA sequencing data (scRNAseq) from blood and liver fine-needle aspirates (FNA). This will help to better understand anti-HBV immunity.

Project description:We used immunocompetent Fah-/- mice as the recipients and adoptively transferred HBsAg+ hepatocytes from HBs-Tg mice to replace the recipient hepatocytes (HBs-HepR). HBs-HepR mice maintained persistent HBsAg expression with chronic hepatitis and spontaneous liver fibrosis, and eventually developed HCC with a prevalence of 100%.

Project description:We used immunocompetent Fah-/- mice as the recipients and adoptively transferred HBsAg+ hepatocytes from HBs-Tg mice to replace the recipient hepatocytes (HBs-HepR). HBs-HepR mice maintained persistent HBsAg expression with chronic hepatitis and spontaneous liver fibrosis, and eventually developed HCC with a prevalence of 100%.

Project description:Previous studies have paid more attention to hepatitis B e antigen (HBeAg) intrauterine exposure, however the effect of solely hepatitis B surface antigen (HBsAg) exposure on the immune response of offspring against hepatitis B virus (HBV) is still unclear. In this study, we investigated whether HBsAg intrauterine exposure affected the offspring's immune response against HBV and the relevant mechanism, which is important for the prevention of HBV mother-to-infant transmission.

Project description:Hepatitis B virus (HBV) can integrate into the chromosomes of infected hepatocytes, contributing to the production of hepatitis B surface antigen (HBsAg) and to hepatocarcinogenesis. We performed spatial transcriptomics to investigate the intrahepatic cell heterogeneity and the spatial distribution of transcriptionally active HBV integration events in different phases of chronic HBV infection. Our analysis revealed that transcriptionally active HBV integration occurred in chronically HBV-infected patients in different phases, including those patients with HBsAg loss, and antiviral treatment was associated with a decreased number and extent of viral integrations.

Project description:We analyzed three clinical parameters with gene expression data from 122 liver tissues. Six healthy samples were used in validation. All hepatitis samples were HBV infected, which was validated by positive HBsAg or serum HBV-DNA. The samples with HCV infection or metabolic liver injury (e.g. fatty liver, chronic alcoholic hepatitis, etc.) were excluded. This dataset is part of the TransQST collection.

Project description:To understand why cancer vaccine-induced T cells often fail to eradicate tumors, we studied immune responses in mice vaccinated with gp100 peptide emulsified in incomplete Freund's adjuvant (IFA), commonly used in clinical cancer vaccine trials. After gp100 peptide/IFA vaccination, tumor-specific CD8+ T cells (adoptively transferred from gp100-specific TCR-transgenic pmel-1 mice) accumulated not in tumors but at the persisting, antigen-rich vaccination site. Once there, primed T cells became dysfunctional and underwent antigen-driven, IFN-γ and FasL-mediated apoptosis, resulting in systemic hyporesponsiveness to subsequent vaccination. Provision of anti-CD40 antibody, TLR7 agonist and interleukin-2 (covax) reduced T cell apoptosis but did not prevent vaccination site sequestration. A non-persisting vaccine formulation shifted T cell localization towards tumors, inducing superior anti-tumor activity. Short-lived formulation also reduced systemic T cell dysfunction and promoted memory formation, as shown by gene expression profiling and other measures. Persisting peptide/IFA vaccine depots, currently used to vaccinate cancer patients, can induce specific T cell sequestration at vaccination sites followed by dysfunction and deletion; short-lived depot formulations may overcome these limitations and result in greater therapeutic efficacy of peptide-based cancer vaccines. To study the fate of melanoma-specific CD8+ T cells after peptide vaccination, we tracked T cell receptor-transgenic pmel-1 T cells in mice vaccinated with heteroclitic gp100_25-33 peptide emulsified in IFA. Splenic pmel-1 CD8+ T cells were purified at 6 and 21 days after vaccination with either gp100/IFA/covax or gp100/saline/covax, and then their total RNA was extracted and used for comparison by gene expression profiling.

Project description:Chronic viral hepatitis after infection with hepatotropic viruses like hepatitis B virus (HBV) affects 300 million persons worldwide, which as the result of chronic immune-mediated hepatic inflammation cause liver cirrhosis and cancer being responsible for 800.000 deaths per year3. Chronic viral hepatitis is maintained by failure of the host´s immune response to control viral infection, but the mechanisms for this inability of virus-specific CD8 T cells to eliminate HBV-infected hepatocytes remain unclear. Here, we demonstrate that during persistent experimental infection with hepatotropic viruses and HBV replication in hepatocytes all virus-specific CD8 T cells present in the liver expressed the tissue-residency markers CXCR6 and CD69. However, RNAseq analysis revealed that CXCR6+CD8 T cells during persistent hepatotropic infection were retained in the liver because of antigen-recognition rather than a transcriptional tissue-residency program, in contrast to canonical liver-resident memory CXCR6+CD8 T cells emerging after resolved infection. Whereas during persistent infection with a model virus like lymphocytic choriomeningitis virus with broad tissue and cell tropism exhausted CD8 T cells show graded loss of effector functions, hepatic virus-specific CXCR6+CD8 T cells during persistent infection with hepatotropic viruses were blinded and completely non-responsive to stimulation in absence of a canonical tox exhaustion signature. Rather, in blinded liver CXCR6+CD8 T cells, transcription factor network analysis revealed Crem, the cAMP-responsive-element-modulator, as the only transcription factor discreetly active in CD8 T cells with complete loss of effector function during persistent hepatotropic infection. Similarly, single cell RNA-sequencing of peripheral blood HBcore-specific CD8 T cells from chronic hepatitis B patients also revealed enhanced CREM activity. Notably, knock-out of the inhibitory CREM/ICER gene in T cells failed to rescue protective T cell immunity during persistent infection with hepatotropic viruses pointing towards post-translational mechanisms relevant for enhanced Crem activity and loss of effector function. Indeed, T cell receptor-associated signalling was blocked in blinded antigen-specific CXCR6+CD8 T cells, that in situ during persistent hepatotropic infection were in close proximity to liver sinusoidal endothelial cells producing high amounts of cAMP-inducing prostanoids. Inhibitory cAMP/PKA/CSK activity increased CREM activity and disconnected CXCR6+CD8 T cells from activation signalling through the T cell receptor. Thus, enhanced CREM expression identifies blinded liver CXCR6+CD8 T cells, but loss of effector functions is caused by post-translational prevention of signalling, which identifies novel molecular targets for immune monitoring and immune therapy of chronic hepatitis B.

Project description:BACKGROUND: Hepatocellular carcinoma (HCC) is a common complication of chronic viral hepatitis. In support of this notion, we have reported that hepatitis B surface antigen (HBsAg)-specific CD8+ T lymphocytes critically contribute to inducing chronic liver cell injury that exerts high carcinogenic potential in a hepatitis B virus (HBV) Tg mouse model. The dynamics of the molecular signatures responsible for hepatocellular carcinogenesis are not fully understood. The current study was designed to determine the serial changes in gene expression profiles in a model of chronic immune-mediated hepatitis. METHODS: Three-month-old HBV Tg mice were immunologically reconstituted with bone marrow cells and splenocytes from syngeneic nonTg donors. Liver tissues were obtained every three months until 18 months at which time all mice developed multiple liver tumors. Nitrative DNA lesions and hepatocyte turnover were assessed immunohistochemically. Gene expression profiles were generated by extracting total RNA from the tissues and analyzing by microarray. RESULTS: The nitrative DNA lesions and the regenerative proliferation of hepatocytes were increased during the progression of chronic liver disease. In a gene expression profile analysis of liver samples, the chemokine- and T cell receptor (TCR)-mediated pathways were enhanced during chronic hepatitis, and the EGF- and VEGF-mediated pathways were induced in HCC. Among these molecules, the protein levels of STAT3 were greatly enhanced in all hepatocyte nuclei and further elevated in the cytoplasm in HCC tissue samples at 18 months, and the levels of phosphorylated TP53 (p-p53-Ser 6 and -Ser 15) were increased in liver tissues. CONCLUSIONS: HBV-specific immune responses caused unique molecular signatures in the liver tissues of chronic hepatitis and triggered subsequent carcinogenic gene expression profiles in a mouse model. The results suggest a plausible molecular basis responsible for HBV-induced immune pathogenesis of HCC.