Jing-hsiung Ou

Hepatitis C Virus F Protein Is a Short-Lived Protein Associated with the Endoplasmic Reticulum

ABSTRACT Hepatitis C virus (HCV) F protein is a newly discovered HCV gene product that is expressed by translational ribosomal frameshift. Little is known about the biological properties of this protein. By performing pulse-chase labeling experiments, we demonstrate here that the F protein is a labile protein with a half-life of <10 min in Huh7 hepatoma cells and in vitro. The half-life of the F protein could be substantially increased by proteasome inhibitors, suggesting that the rapid degradation of the F protein is mediated by the proteasome pathway. Further immunofluorescence staining and subcellular fractionation experiments indicate that the F protein is primarily associated with the endoplasmic reticulum. This subcellular localization is similar to those of HCV core and NS5A proteins, raising the possibility that the F protein may participate in HCV morphogenesis or replication.

Regulation of Hepatitis B Virus Replication by the Ras-Mitogen-Activated Protein Kinase Signaling Pathway

ABSTRACT The replication of hepatitis B virus (HBV) can be regulated by a variety of factors, including hormones, growth factors, and cytokines. However, the molecular mechanisms of these regulations are largely unknown. Ras is a small GTPase that responds to many of these external stimuli. In this study, we investigated the possible effect of Ras on the replication of HBV. Our results indicated that activated Ras could suppress the replication of HBV in both Huh7 and HepG2 cells. This suppression was independent of the X protein and most likely occurred at the transcriptional level. Deletion-mapping analysis of the HBV core promoter and its upstream ENI and ENII enhancers revealed multiple elements responsive to activated Ras. This suppression of HBV replication by activated Ras was apparently mediated by the mitogen-activated protein (MAP) kinase pathway, as it was accompanied by activation of ERK1/2 and abolished by the MEK1/2 inhibitor U0126. Our results thus indicate that external stimuli may suppress HBV replication through the Ras-MAP kinase pathway.

Regulation of Hepatocyte Nuclear Factor 1 Activity by Wild-Type and Mutant Hepatitis B Virus X Proteins

ABSTRACT The hepatitis B virus (HBV) core promoter regulates the transcription of two related RNA products named precore RNA and core RNA. Previous studies indicate that a double-nucleotide mutation that occurs frequently during chronic HBV infection converts a nuclear receptor binding site in the core promoter to the binding site of the transcription factor hepatocyte nuclear factor-1 (HNF-1) and specifically suppresses the transcription of the precore RNA. This mutation also changes two codons in the overlapping X protein coding sequence. In this report, we demonstrate that the X protein and its mutant Xmt can physically bind to HNF-1 both in vitro and in vivo. Further analyses indicate that both X and Xmt can enhance the gene transactivation and the DNA binding activities of HNF-1. This finding demonstrates for the first time that the X protein can stimulate the DNA binding activity of a homeodomain transcription factor. Interestingly, while both X and Xmt can stimulate the HNF-1 activities, they differ in their effects: a smaller amount of Xmt is needed to generate greater transactivation and DNA binding activities of HNF-1. This functional difference between X and Xmt may have important implications in HBV pathogenesis and is apparently why they have different effects on the core promoter bearing the HNF-1 binding site.

Hepatitis C virus ARFP/F protein interacts with cellular MM-1 protein and enhances the gene trans-activation activity of c-Myc

The ARFP/F protein is synthesized from the +1 reading frame of the hepatitis C virus (HCV) core protein gene. The function of this protein remains unknown. To study the function of the HCV ARFP/F protein, we have conducted the yeast two-hybrid screening experiment to identify cellular proteins that may interact with the ARFP/F protein. MM-1, a c-Myc interacting protein, was found to interact with HCV ARFP/F protein in this experiment. The physical interaction between ARFP/F and MM-1 proteins was further confirmed by the GST pull-down assay, the co-immunoprecipitation assay and confocal microscopy. As MM-1 can inhibit the gene transactivation activity of c-Myc, we have conducted further analysis to examine the possible effect of the ARFP/F protein on c-Myc. Our results indicate that the HCV ARFP/F protein can enhance the gene trans-activation activity of c-Myc, apparently by antagonizing the inhibitory effect of MM-1. The ability of the ARFP/F protein to enhance the activity of c-Myc raises the possibility that ARFP/F protein might play a role in hepatocellular transformation in HCV patients.

Expression and Dimerization of Hepatitis C Virus Core Protein in E. coli.

Hepatitis C virus (HCV) is a positive-stranded RNA virus with a genome size of about 9-10 kb. The genome of this virus encodes a polyprotein with a length of over 3000 amino acids. This polyprotein is cleaved by cellular and viral proteases to generate at least 10 viral gene products. Recent reports have indicated that there are extensive interactions between various HCV proteins: the core (capsid) protein can interact with itself (1) and with the El envelope protein (2); El protein can interact with the E2 envelope protein (3,4) which in turn can be covalently linked to its following p7 protein and interact with another integral membrane protein named NS2 (5); NS2 can also interact with NS5A and NS5B nonstructural proteins (6); and NS3 proteinase/helicase has also been shown to complex with the NS4A protein (6,7). Thus, most of the known HCV proteins interact with at least another HCV protein. These interactions are presumably very important for morphogenesis and replication of HCV.

Characterization of nuclear localization of a hepatitis B virus precore protein derivative P22

SummaryBoth of hepatitis B virus core protein and a precore protein derivative, named P22, have been shown to localize in the nucleus. Although P22 has ten additional amino acid residues at its amino-terminus, both proteins contain the same nuclear localization signal. In order to understand the mechanism that regulates the activity of this signal, we have studied the nuclear localization of P22 and compared it with that of core protein. It was found that both cytosolic and nuclear fractions of P22 were phosphorylated but to a lesser extent when compared with cytosolic core protein. This distinction was likely attributed to different conformations between these two proteins since the density gradient analysis revealed a different particle formation for P22 in the cytosol. When expressed in Vero cells synchronized by serum deprivation, P22 remained in the cytosol during G0 and G1 phases, accumulated gradually in the nucleus during S phase, and largely localized in the nucleus when cells were confluent. On the other hand, the core protein was transported into the nucleus during mid-G1 phase, shuttled back to the cytosol in S phase and again accumulated in the nucleus when cells were confluent. Interestingly, when aphidicolin was used to arrest the cells in late G1 phase, both proteins were found to accumulate in the nuclei. These results indicated that although both P22 and core proteins possessed the same nuclear localization signal, the cellular regulation of their nuclear transport was not identical and might involve different molecular mechanisms.