Induction of anti-proliferative mechanisms in hepatitis B virus producing cells.

BACKGROUND/AIMS: Hepatitis B virus (HBV) preferentially replicates in quiescent cells. It was analyzed whether HBV affects cell cycle control. METHODS: The amount of EGF-receptor (EGFR) and the binding capacity for 125I-EGF was determined. Expression of mdm2 and p21 and relevance of p53 for it were analyzed by reporter gene assays and western blotting. Cyclin A/E associated cdk2 activities were determined by immunocomplex assays. Cell proliferation was quantified by measurement of BrdU incorporation. RESULTS: In HBV producing cells a significant reduction of EGFR expression, diminished 125I-EGF-binding capacity and insensitivity to EGF-stimulation were observed as compared to the control. Moreover, c-Raf-1-dependent induction of mdm2-P2 and p21cip1/waf1-promoter and elevated amounts of the respective proteins were observed in HBV producing cells. Whereas activation of mdm2-P2-promoter requires p53, activation of p21cip1/waf1-promoter is mediated partially by a p53-independent process. Induction of p21cip1/waf1 is reflected by a reduction of cyclin A associated cdk2 activity and an increase of cyclin E associated cdk2 activity. In accordance with this proliferation rate of HBV-producing hepatocytes is reduced as compared to control cells. CONCLUSIONS: These results describe novel cell-cycle inhibitory functions of HBV that correlate well with the general concept of enhanced HBV replication in quiescent cells.

Integrity of c-Raf-1/MEK signal transduction cascade is essential for hepatitis B virus gene expression.

The genome of hepatitis B virus (HBV) encodes two transcriptional activators: the HBx protein and the PreS2-activator large surface protein (LHBs). Both proteins trigger activation of c-Raf-1/MEK kinase cascade. In case of HBx this can be mediated by a PKC-independent and Ras-dependent mechanism, in case of LHBs activation is PKC-dependent and does not require Ras. Selective destruction of either LHBs- or of HBx-specific activation does not result in significant decrease of viral production from transfected HepG2 cells. Simultaneous inhibition of LHBs- and HBx-dependent activation by blocking signaling steps common to both activators, using trans dominant negative c-Raf-1- or MEK-specific inhibitors, abolished HBV gene expression. In accordance with this no HBV propagation was observed after transfection of a mutated HBV genome defective for HBx- and PreS2-activator function. A detailed analysis revealed that the observed inhibition of HBV- propagation is because of a significant reduction of HBV-specific RNA resulting in an inhibition of the de novo synthesis of viral compounds (viral proteins and nucleic acid) and not by blocking secretion or assembly of the virus. Based on these results we conclude that transcriptional-activator function, mediated by the c-Raf-1/MEK signaling cascade, is essential for HBV gene expression.