Bernd Koeberlein

Impact of the hepatitis B virus genotype and genotype mixtures on the course of liver disease in Vietnam

Eight genotypes (A‐H) of hepatitis B virus (HBV) have been identified. However, the impact of different genotypes on the clinical course of hepatitis B infection remains controversial. We investigated the frequency and clinical outcome of HBV genotypes and genotype mixtures in HBV‐infected patients from Vietnam, Europe, and Africa. In addition, we analyzed the effects of genotype mixtures on alterations in in vitro viral replication. In Asian patients, seven genotypes (A‐G) were detected, with A, C, and D predominating. In European and African patients, only genotypes A, C, D, and G were identified. Genotype mixtures were more frequently encountered in African than in Asian (P = .01) and European patients (P = .06). In Asian patients, the predominant genotype mixtures included A/C and C/D, compared to C/D in European and A/D in African patients. Genotype A was more frequent in asymptomatic compared with symptomatic patients (P < .0001). Genotype C was more frequent in patients with hepatocellular carcinoma (HCC; P = .02). Genotype mixtures were more frequently encountered in patients with chronic hepatitis in comparison to patients with acute hepatitis B (P = .015), liver cirrhosis (P = .013), and HCC (P = .002). Viral loads in patients infected with genotype mixtures were significantly higher in comparison to patients with a single genotype (P = .019). Genotype mixtures were also associated with increased in vitro HBV replication. In conclusion, infection with mixtures of HBV genotypes is frequent in Asia, Africa, and Europe. Differences in the replication‐phenotype of single genotypes compared to genotype‐mixtures suggest that co‐infection with different HBV‐genotypes is associated with altered pathogenesis and clinical outcome. (HEPATOLOGY 2006;43:1375–1384.)

Hepatitis B virus overexpresses suppressor of cytokine signaling-3 (SOCS3) thereby contributing to severity of inflammation in the liver

The mechanism by which hepatitis B virus (HBV) infection causes severe inflammatory liver diseases is multifactorial and related to interactions with cell signaling pathways and the ensuing inflammatory response. Activation of JAK/STAT/SOCS signaling is essential for the induction of cellular antiviral responses, contributes to apoptosis and is negatively regulated by SOCS proteins. Recent reports have shown that SOCS3 activation interferes with viral protein expression and treatment response and thereby plays a major role in hepatitis virus infections. We analyzed the expression of SOCS3 in liver specimens from HBV-infected patients using immunohistochemistry (IHC) and determined the effect of HBV on STAT/SOCS signaling in functional cell culture experiments (HuH-7) using HBV-expressing adenoviral constructs (AdHBV). Increased expression of SOCS3 protein was identified in liver specimens from patients with chronic HBV-infection and this correlated with the severity of liver inflammation. In accordance with the IHC-findings, in vitro analyses demonstrated that HBV infection of HuH7 cells was associated with increased expression of SOCS3 protein. In spite of the over expression of its negative regulator SOCS3 we observed a constitutive activation of STAT3. SOCS1 levels were not increased while pSTAT1 was suppressed in HBV-infected HuH7 cells. Our results demonstrate that STAT/SOCS-signaling is dysregulated in HBV-infected hepatocytes both in vivo and in vitro and this correlated with the severity of liver inflammatory changes. This interference of STAT/SOCS signaling by HBV may result in an ineffective immune response against HBV and potentially contributes to viral pathogenesis, malignant transformation and may represent an important mechanism of viral persistence.

Subcellular Mislocalization of Mutant Hepatitis B X Proteins Contributes to Modulation of STAT/SOCS Signaling in Hepatocellular Carcinoma

Objective: The hepatitis B virus X (HBx) protein plays an important role in the pathogenesis of hepatocellular carcinoma (HCC). One potential mechanism by which HBx can cause liver cancer may involve intracellular distribution and consecutively modulation of the proliferative important STAT/SOCS signaling with upregulation of STAT3. Methods: 153 Vietnamese HBV-infected patients, including 48 patients with HCC, were analyzed. HBx sequences were determined by sequencing and subcloned for functional experiments. Intracellular localization of HBx mutants was determined by immunofluorescence assays. The impact of HBx mutants on JAK/STAT/SOCS signaling was investigated using Western blot and PCR analyses. Results: In 4/48 HCC patients, truncated HBx together with full-length mutated HBx proteins were observed. Expression of HBx mutant proteins demonstrated an atypical nuclear and perinuclear localization. Functional experiments to determine the effect of HBx mutants on STAT/SOCS signaling demonstrated a significantly increased upregulation of STAT3 activation (p > 0.001) in comparison to wild-type (wt)-HBx. STAT1 was not activated either by wt-HBx or HBx mutants. Interestingly, SOCS1 and SOCS3 expression was not activated by wt-HBx and HBx mutants. Conclusions: Our results suggest that atypical nuclear/perinuclear localization of HBx mutants might be responsible for an enhanced activation of STAT3, inhibition of STAT1 and silencing of SOCS1/SOCS3 expression. This observation points to an active role of HBx mutants in hepatocarcinogenesis that involves dysregulation of STAT/SOCS signaling.

Dysregulation of hepatocyte cell cycle and cell viability by hepatitis B virus.

BACKGROUND/AIMS Dysregulation of the cell cycle is frequently associated with tumor development. Hepatitis B virus (HBV) is associated with a significant risk of developing hepatocellular carcinoma but the effects of HBV on cell cycle regulation are not completely understood. METHODS We have used a recombinant adeno-HBV model system to investigate the effect of infection with HBV and the replication defective lamivudine resistant mutant rtM204I mutant on hepatocyte cell cycle and cell viability. RESULTS Huh7 cells synchronised at the G1/S phase of the cell cycle were arrested at the G2/M following infection with rAdHBV-wt and rAdHBV-M204I. This was accompanied by increased levels of p21(cip1), p-cdc2, cyclins D, A and B. Cell viability was reduced and cleaved caspase 3 levels were increased in HBV- and rtM204I-infected cells. rAdHBV-M204I-infected Huh7 cells also demonstrated significant up-regulation of phospho-ERK, phospho-Akt, p53 and phospho-Mdm2 compared to mock-infected cells. These changes were comparable to those following infection of Huh7 cells with rAdHBV-wt. CONCLUSION Our results suggest that HBV, regardless of phenotype, produces cell cycle arrest and reduced hepatocyte viability. Perturbations in these cellular processes are likely to underlie HBV-associated liver oncogenic transformation and may help explain the ongoing risk of developing hepatocellular carcinoma in individuals in whom the lamivudine resistant rtM204I mutant emerges.