Transcriptional repression of the human p53 gene by hepatitis B viral core protein (HBc) in human liver cells

Hepatitis B virus (HBV) is a causative agent of chronic and acute hepatitis, and is associated with the development of hepatocellular carcinoma (HCC). We demonstrate here that the Hepatitis B viral core protein (HBc) functions as a repressor on the promoter activity of the human p53 gene. The functional analyses of the promoter of the p53 gene by serial deletion, site-directed mutagenesis, and the heterologous promoter system revealed that the promoter activity was repressed through the E2F1-binding site (nucleotides -28 to -8) by HBc. An electrophoretic mobility shift assay (EMSA) showed that the HBc reduced the DNA-binding ability of E2F1 to the binding site of the p53 promoter. The interaction of HBc with E2F1 was also observed by glutathione S-transferase (GST) fusion protein binding assay. Furthermore, HBc represses the expression of the p53 gene in the human liver cell line HepG2. Finally, HBc and HBx synergistically repress both the promoter activity and the expression of the p53 gene in HepG2 cells. These results, together with our previous study, strongly suggest that HBc, like HBx, represses the expression of the human p53 tumor suppressor gene.     

Characterization of the major duck hepatitis B virus core particle protein.

The amino acid composition of the major duck hepatitis B virus (DHBV) core particle proteins was determined. The results of this analysis indicated that cores are composed of a single major protein that initiates translation from the second available AUG in the DHBV core gene. Proteins isolated from core particles purified from the cytoplasm of DHBV-infected duck hepatocytes exhibited heterogeneity in sodium dodecyl sulfate-polyacrylamide gel electrophoresis, independent of the stage of viral DNA maturation. Incubation of native cores with alkaline phosphatase removed this heterogeneity, indicating that phosphorylation of external amino acids was responsible. Core protein isolated from mature DHBV purified from serum of infected animals did not display heterogeneity, suggesting a possible role for dephosphorylation in virus maturation.     

DNA-binding activity of hepatitis B e antigen polypeptide lacking the protaminelike sequence of nucleocapsid protein of human hepatitis B virus.

The characteristics of binding of hepatitis B core antigen (HBcAg) and hepatitis B e antigen (HBeAg) polypeptides to hepatitis B virus (HBV) DNA were analyzed. HBcAg polypeptide from recombinant HBV core particles and HBeAg polypeptide from partially purified serum HBeAg were prepared and verified to have molecular weights of 21,500 (P21.5) and of 17,000 (P17) and 18,000 (P18), respectively, by immunoblot analysis. By reaction of these proteins on a nitrocellulose membrane with cloned 32P-HBV DNA, it was revealed that the HBeAg polypeptide, which lacks the C-terminal 34 amino acids of P21.5, as well as the HBcAg polypeptide, bound to the DNA. The secondary structures of nucleocapsid proteins of HBV, woodchuck hepatitis virus, and ground squirrel hepatitis virus were predicted by the Garnier algorithm. Amino acid sequences which, in addition to those of the C-terminal regions, may contribute to binding were proposed to be the 21-amino-acid residues located at amino acids 100 to 120 of the nucleocapsid proteins of these hepadnaviruses.     

Delivery of chimeric hepatitis B core particles into liver cells

Aims: To display a liver‐specific ligand on the hepatitis B virus core particles for cell‐targeting delivery. Methods and Results: A liver cell–binding ligand (preS1) was fused at the N‐terminal end of the hepatitis B core antigen (HBcAg), but the fusion protein (preS1His₆HBcAg) was insoluble in Escherichia coli and did not form virus‐like particles (VLPs). A method to display the preS1 on the HBcAg particle was established by incorporating an appropriate molar ratio of the truncated HBcAg (tHBcAg) to the preS1His₆HBcAg. Gold immunomicroscopy showed that the subunit mixture reassembled into icosahedral particles, displaying the preS1 ligand on the surface of VLPs. Fluorescence microscopy revealed that the preS1 ligand delivered the fluorescein‐labelled VLPs into the HepG2 cells efficiently. Conclusions: Chimeric VLPs containing the insoluble preS1His₆HBcAg and highly soluble tHBcAg were produced by a novel incorporation method. The preS1 ligand was exposed on the surface of the VLPs and was shown to deliver fluorescein molecules into liver cells. Significance and Impact of Study: The newly established incorporation method can be used in the development of chimeric VLPs that could serve as potential nanovehicles to target various cells specifically by substituting the preS1 ligand with different cell‐specific ligands.     

Relevance of cysteine residues for biosynthesis and antigenicity of human hepatitis B virus e protein.

The mature form of the secretory core protein (HBe protein) of human hepatitis B virus contains four cysteines which are located at amino acid positions -7, 48, 61, and 107 relative to the HBc start methionine. In addition, there is a cysteine, Cys-183, located in the C-terminal domain of the HBe precursor, which is cleaved during HBe maturation. Here, the significance of these cysteines for biosynthesis and antigenicity of the HBe protein was examined. The cysteines at positions -7 and 61 were found to be crucial for HBe biosynthesis. As has already been described, if the Cys at position -7 is mutated, disulfide-linked HBe homodimers which have both HBe antigenicity and HBc antigenicity are expressed. Here we show that these dimers are due to Cys-61-Cys-61 disulfide bridges which are formed only if the Cys at position -7 is not present. In the wild-type protein, this dimerization appears to be inhibited by formation of intramolecular disulfide bridges between the Cys at -7 and one of the internal cysteines. Moreover, Cys-61 is important for HBe biosynthesis in general since mutation of this amino acid results in production of HBe proteins which are either only poorly secreted or possess a different antigenicity.     

Self-assembly of nucleocapsid-like particles from recombinant hepatitis C virus core protein

Little is known about the assembly pathway and structure of hepatitis C virus (HCV) since insufficient quantities of purified virus are available for detailed biophysical and structural studies. Here, we show that bacterially expressed HCV core proteins can efficiently self-assemble in vitro into nucleocapsid-like particles. These particles have a regular, spherical morphology with a modal distribution of diameters of approximately 60 nm. Self-assembly of nucleocapsid-like particles requires structured RNA molecules. The 124 N-terminal residues of the core protein are sufficient for self-assembly into nucleocapsid-like particles. Inclusion of the carboxy-terminal domain of the core protein modifies the core assembly pathway such that the resultant particles have an irregular outline. However, these particles are similar in size and shape to those assembled from the 124 N-terminal residues of the core protein. These results provide novel opportunities to delineate protein-protein and protein-RNA interactions critical for HCV assembly, to study the molecular details of HCV assembly, and for performing high-throughput screening of assembly inhibitors.     

N-ethylmaleimide inhibition of the DNA-binding activity of the herpes simplex virus type 1 major DNA-binding protein.

The major herpes simplex virus DNA-binding protein, designated ICP8, binds tightly to single-stranded DNA and is required for replication of viral DNA. The sensitivity of the DNA-binding activity of ICP8 to the action of the sulfhydryl reagent N-ethylmaleimide has been examined by using nitrocellulose filter-binding and agarose gel electrophoresis assays. Incubation of ICP8 with N-ethylmaleimide results in a rapid loss of DNA-binding activity. Preincubation of ICP8 with single-stranded DNA markedly inhibits this loss of binding activity. These results imply that a free sulfhydryl group is involved in the interaction of ICP8 with single-stranded DNA and that this sulfhydryl group becomes less accessible to the environment upon binding. Agarose gel electrophoretic analysis of the binding interaction in the presence and absence of N-ethylmaleimide indicates that the cooperative binding exhibited by ICP8 is lost upon treatment with this reagent but that some residual noncooperative binding may remain. This last result was confirmed by equilibrium dialysis experiments with the 32P-labeled oligonucleotide dT10 and native and N-ethylmaleimide-treated ICP8.     

Effect of core protein phosphorylation by protein kinase C on encapsidation of RNA within core particles of hepatitis B virus.

Phosphorylation of core particles derived either from hepatitis B viruses or from livers of hepatitis B-infected individuals has been long recognized, but the nature and function of the phosphorylating enzyme remained unknown. By immunoblotting with a monoclonal antibody, we have now detected protein kinase C within the liver-derived core particles. To study the significance of the encapsidated protein kinase C for the viral life cycle, we established an in vitro assembly system consisting of Escherichia coli-expressed core protein, protein kinase C, and in vitro-synthesized hepatitis B virus RNA. Phosphorylation of the core protein led to a reduced RNA encapsidation capacity of the core particles. Furthermore, RNA and protein kinase C competed for their target sequence, which is the carboxy-terminal arginine-rich domain of the core protein. This finding implies that phosphorylation of the nucleic acid binding site in the core protein occurs within the particles after encapsidation of protein kinase C, pregenomic RNA, and viral polymerase at a later step during viral genome maturation.     

Intracellular hepatitis B virus increases hepatic cholesterol deposition in alcoholic fatty liver via hepatitis B core protein

Hepatitis B virus (HBV) infection is a prevalent infectious disease with serious outcomes like chronic and acute hepatitis, cirrhosis, and hepatocellular carcinoma. However, the metabolic alteration by HBV is rarely taken into consideration. With the high prevalence of alcohol consumption and chronic HBV infection, their overlap is assumed to be an increasing latent hazard; although the extent has not been calculated. Moreover, the impact of chronic alcohol consumption combined with HBV on cholesterol metabolism is unknown. Six-week-old male FVB/Ncrl mice were hydrodynamically injected with a pGEM-4Z-1.3HBV vector and then fed an ethanol diet for 6 weeks. Serum biomarkers and liver histology, liver cholesterol levels, and cholesterol metabolism-related molecules were measured. In vitro assays with HBx, hepatitis B surface (HBs), or hepatitis B core (HBc) protein expression in HepG2 cells costimulated with ethanol were conducted to assess the cholesterol metabolism. HBV expression synergistically increased cholesterol deposition in the setting of alcoholic fatty liver. The increase of intrahepatic cholesterol was due to metabolic alteration in cholesterol metabolism, including increased cholesterol synthesis, decreased cholesterol degradation, and impaired cholesterol uptake. Overexpression of HBV component HBc, but not HBs or HBx, selectively promoted the hepatocellular cholesterol level.     

Variability and conservation in hepatitis B virus core protein

Background  

Hepatitis B core protein (HBVc) has been extensively studied from both a structural and immunological point of view, but the evolutionary forces driving sequence variation within core are incompletely understood.     

Expression and characterization of hepatitis C virus core protein fused to hepatitis B virus core antigen

Recombinant plasmids were constructed by fusing the gene fragments encoding the full-length (1-191aa) and the truncated (1-40aa and l-69aa) HCV core proteins (HCc) respectively to the core gene of HBV at the position of amino acid 144 and expressed inE. coli. The products were analyzed by ELISA, Western blotting as well as the immunization of the mice. The results showed that those fusion proteins (B144C191, B144C69, B144C40) possessed the dual antigenicity and immunogenicity of both hepatitis B virus core antigen (HBcAg) and hepatitis C virus core protein (HCc). Analysis by electron microscopy and CsCI density gradient ultra-centrifugation revealed that similar to the HBcAg itself, all fusion proteins were able to form particles. Comparison of the antigenicity and immunogenicity of those fusion proteins showed that the length of HCc gene fused to HBcAg had no much effect on the antigenicity and immunogenicity of HBcAg, however, B144C69 and B144C40 induced higher titres antibodies against HCc than B144C191. Using those fusion proteins, ELISA for screening of antibodies against both HBV and HCV in human sera was also established.     

Production of hepatitis B virus nucleocapsidlike core particles in Xenopus oocytes: assembly occurs mainly in the cytoplasm and does not require the nucleus.

The location of hepatitis B virus (HBV) nucleocapsid (core particle) assembly in infected cells remains controversial. Some lines of evidence implicate the nucleus; others favor the cytoplasm. Via injection of a synthetic mRNA encoding the HBV nucleocapsid protein (p21.5), we have expressed both unassembled p21.5 and nucleocapsidlike core particles in Xenopus oocytes. Subcellular fractionation reveals that approximately 91% of the unassembled p21.5 and 95% of the core particles are cytoplasmic, with only 9 and 5%, respectively, in the nucleus. We present evidence showing that unassembled p21.5 equilibrates between nucleus and cytoplasm by passive diffusion and that intact core particles do not enter the nucleus. To examine the role of the nucleus in core particle formation, we expressed p21.5 in surgically anucleate oocytes. We show that anucleate oocytes support efficient core particle formation, indicating that (i) the nucleus is not essential for assembly and (ii) the cytoplasm can assemble most core particles found in oocytes. On the basis of our data, we propose that in oocytes, most core particle assembly (up to 95%) occurs in the cytoplasm, but that at least approximately 5% of the cellular core particles are assembled in the nucleus and remain there. We discuss the implications of these findings for the formation of replication-competent core particles in infected cells.     

DNA-binding properties of the major core protein of adenovirus 2.

The major adenovirus core protein (P.VII) binds to various species of duplex and single-stranded DNA molecules as a linear function of P.VII concentration. P.VII progressively condenses 32S Ad2 DNA into rapidly sedimenting forms having an S value of around 2,280. P.VII does not coat DNA like cytochrome C, instead DNA-protein beads are visualized in the electron microscope at low protein concentration. These beads appear to interact forming larger structures and at high P.VII concentrations the DNA molecule becomes highly compacted. Analysis of DNA fragments formed after digestion of P.VII-DNA complexes and isolated cores with micrococcal nuclease suggest that the organization of the DNA in the two structures is essentially identical. The initial P.VII and DNA interaction is sensitive to both ionic and hydrophobic environments, whereas the in vitro DNA-P.VII complexes are extremely stable and are not disrupted in the presence of 3 M NaCl, 1% sarcosyl or 5% deoxycholate. Properties of these in vitro DNA-protein VII complexes share striking similarities to isolated viral core particles.     

Expression and characterization of hepatitis C virus core protein fused to hepatitis B virus core antigen

Recombinant plasmids were constructed by fusing the gene fragments encoding the full-length (1-191aa) and the truncated (1-40aa and 1-69aa) HCV core proteins (HCc) respectively to the core gene of HBV at the position of amino acid 144 and expressed in E. coli. The products were analyzed by ELISA, Western blotting as well as the immunization of the mice. The results showed that those fusion proteins (B144C191, B144C69, B144C40) possessed the dual antigenicity and immunogenicity of both hepatitis B virus core antigen (HBcAg) and hepatitis C virus core protein (HCc). Analysis by electron microscopy and CsCl density gradient ultra-centrifugation revealed that similar to the HBcAg itself, all fusion proteins were able to form particles. Comparison of the antigenicity and immunogenicity of those fusion proteins showed that the length of HCc gene fused to HBeAg had no much effect on the antigenicity and immunogenicity of HBcAg, however, B144C69 and B144C40 induced higher titres antibodies against HCc than B14d     

Nuclear export and import of human hepatitis B virus capsid protein and particles

It remains unclear what determines the subcellular localization of hepatitis B virus (HBV) core protein (HBc) and particles. To address this fundamental issue, we have identified four distinct HBc localization signals in the arginine rich domain (ARD) of HBc, using immunofluorescence confocal microscopy and fractionation/Western blot analysis. ARD consists of four tight clustering arginine-rich subdomains. ARD-I and ARD-III are associated with two co-dependent nuclear localization signals (NLS), while ARD-II and ARD-IV behave like two independent nuclear export signals (NES). This conclusion is based on five independent lines of experimental evidence: i) Using an HBV replication system in hepatoma cells, we demonstrated in a double-blind manner that only the HBc of mutant ARD-II+IV, among a total of 15 ARD mutants, can predominantly localize to the nucleus. ii) These results were confirmed using a chimera reporter system by placing mutant or wild type HBc trafficking signals in the heterologous context of SV40 large T antigen (LT). iii) By a heterokaryon or homokaryon analysis, the fusion protein of SV40 LT-HBc ARD appeared to transport from nuclei of transfected donor cells to nuclei of recipient cells, suggesting the existence of an NES in HBc ARD. This putative NES is leptomycin B resistant. iv) We demonstrated by co-immunoprecipitation that HBc ARD can physically interact with a cellular factor TAP/NXF1 (Tip-associated protein/nuclear export factor-1), which is known to be important for nuclear export of mRNA and proteins. Treatment with a TAP-specific siRNA strikingly shifted cytoplasmic HBc to nucleus, and led to a near 7-fold reduction of viral replication, and a near 10-fold reduction in HBsAg secretion. v) HBc of mutant ARD-II+IV was accumulated predominantly in the nucleus in a mouse model by hydrodynamic delivery. In addition to the revised map of NLS, our results suggest that HBc could shuttle rapidly between nucleus and cytoplasm via a novel TAP-dependent NES.     

The quaternary structure, antigenicity, and aggregational behavior of the secretory core protein of human hepatitis B virus are determined by its signal sequence.

Human hepatitis B virus encodes a secretory core protein, referred to as the HBe protein, whose secretion is mediated by the pre-C signal sequence. Here we examined whether this sequence is important only for translocation of the HBe precursor (the precore protein) or whether it also contributes to the structural and biophysical properties of the mature HBe protein. When a truncated hepatitis B virus precore protein, lacking the basic C-terminal domain which is cleaved from the wild-type protein during its conversion into HBe, was expressed in human hepatoma cells, only a small amount of HBe-like protein was produced. This protein was slightly smaller than the wild-type HBe protein, suggesting that C-terminal cleavage of the precore protein does not occur at the suggested site. When the authentic signal sequence of the precore protein (the pre-C sequence) was replaced by the unrelated signal sequence of an influenza virus hemagglutinin, not only the full-length but also the C-terminally truncated protein was expressed and secreted with high efficiency. Western blot (immunoblot) analyses with nonreducing gels and conformation-specific monoclonal antibodies revealed that the HBe protein secreted under control of the pre-C signal sequence was a monomer with HBe antigenicity, whereas the HBe-like protein secreted under control of the hemagglutinin signal sequence was a disulfide-bridge-linked dimer with both HBe and HBc antigenicity. Electron microscopic examination of gradient-purified particulate core gene products showed that HBe protein secreted under control of the hemagglutinin signal sequence forms core particles, whereas HBe protein secreted under control of the pre-C sequence does not. Thus, the pre-C sequence not only mediates the secretion but also determines the structural and aggregational properties of the HBe protein.     

A cysteine and a hydrophobic sequence in the noncleaved portion of the pre-C leader peptide determine the biophysical properties of the secretory core protein (HBe protein) of human hepatitis B virus.

The molecular basis of the biophysical and antigenic differences between the cellular core protein (HBc protein) and the secreted core protein (HBe protein) of human hepatitis B virus was examined. The data show that the properties which distinguish the HBe protein from the HBc protein are due mostly to the 10-amino-acid portion of the HBe leader sequence which remains attached to the HBe protein after cleavage. A cysteine located within this region determines the quaternary structure and the antigenicity of the HBe protein. If this cysteine is lacking, the HBe protein, which is predominantly a monomer with only HBe antigenicity, is expressed as a disulfide-linked homodimer showing both HBe and HBc antigenicity. However, dimerization of the HBe protein was found to be neither sufficient nor required for particle formation. In fact, aggregation of the HBe protein was found to be inhibited by the strongly hydrophobic tripeptide Trp-Leu-Trp, which is also located in the noncleaved portion of the signal sequence. If this tripeptide was converted into either Asp-Asn-Asn or Ala-Asp-Leu, the HBe protein assembled into particles, independent of the presence of the cysteine.     

The secretory core protein of human hepatitis B virus is expressed on the cell surface.

Human hepatitis B virus (HBV) causes acute and chronic liver disease, which can result in tumor formation. An as yet unexplained phenomenon is that virus elimination usually correlates with the development of antibodies directed against the HBeAg, a secretory HBV core gene product which can be detected in the serum of infected patients. Expression of HBeAg in a human hepatoma cell line by using recombinant vaccinia viruses revealed that the HBeAg is not only secreted from HBeAg-producing cells but also incorporated into the outer cell membrane. No membrane-expressed core gene product could be detected when the cytoplasmic core protein (HBcAg) was expressed. Immune sera from patients who developed anti-HBe antibodies efficiently recognized the membrane-bound HBeAg, suggesting that surface-expressed HBeAg can serve as a target for an antibody-mediated elimination of HBV-infected cells.     

Differential formation of disulfide linkages in the core antigen of extracellular and intracellular hepatitis B virus core particles.

Our understanding of the assembly of hepatitis B virus is still very limited. We present evidence to demonstrate that the HBc antigen formed oligomers through disulfide linkages in the extracellular hepatitis B virus core (HBc) particles. However, the intracellular HBV core particles did not contain disulfide-linked HBc antigens. Furthermore, the extracellular particles which had disulfide bonds were more stable than intracellular particles at pH 7.5 and 10 and in 3 M NaCl and 4 M urea. These data suggest that the formation of disulfide bonds in the HBc antigen is important for the integrity of the viral core particles.