Molecular basis of the interaction of the human tyrosine phosphatase PTPN3 with the hepatitis B virus core protein.

Interactions between the hepatitis B virus core protein (HBc) and host cell proteins are poorly understood, although they may be essential for the propagation of the virus and its pathogenicity. HBc has a C-terminal PDZ (PSD-95, Dlg1, ZO-1)-binding motif (PBM) that is responsible for interactions with host PDZ domain-containing proteins. In this work, we focused on the human protein tyrosine phosphatase non-receptor type 3 (PTPN3) and its interaction with HBc. We solved the crystal structure of the PDZ domain of PTPN3 in complex with the PBM of HBc, revealing a network of interactions specific to class I PDZ domains despite the presence of a C-terminal cysteine in this atypical PBM. We further showed that PTPN3 binds the HBc protein within capsids or as a homodimer. We demonstrate that overexpression of PTPN3 significantly affects HBV infection in HepG2 NTCP cells. Finally, we performed proteomics studies on both sides by pull-down assays and screening of a human PDZ domain library. We identified a pool of human PBM-containing proteins that might interact with PTPN3 in cells and that could be in competition with the HBc PBM during infection, and we also identified potential cellular partners of HBc through PDZ-PBM interactions. This study opens up many avenues of future investigations into the pathophysiology of HBV.

BAY 41-4109-mediated aggregation of assembled and misassembled HBV capsids in cells revealed by electron microscopy.

HBc is a small protein essential for the formation of the icosahedral HBV capsid. Its multiple roles in the replication cycle make this protein a promising target for the development of antiviral molecules. Based on the structure of HBc, a series of HBV assembly inhibitors, also known as capsid assembly modulators, were identified. We investigated the effect of BAY 41-4109, a heteroaryldihydropyrimidine derivative that promotes the assembly of a non-capsid polymer. We showed, by confocal microscopy, that BAY 41-4109 mediated HBc aggregation, mostly in the cytoplasm of Huh7 cells. Image analysis revealed that aggregate size depended on BAY 41-4109 concentration and treatment duration. Large aggregates in the vicinity of the nucleus were enclosed by invaginations of the nuclear envelope. This deformation of the nuclear envelope was confirmed by transmission electron microscopy (TEM) and immuno-TEM. These two techniques also revealed that the HBc aggregates were accumulations of capsid-like shells with an electron-dense material consisting of HBV core fragments. These findings, shedding light on the ultrastructural organization of HBc aggregates, provide insight into the mechanisms of action of BAY 41-4109 against HBV and will serve as a basis for comparison with other HBV capsid assembly inhibitors.

Recombinant hepatitis B virus core particles: association, dissociation and encapsidation of green fluorescent protein.

The recombinant hepatitis B virus (HBV) core antigen (HBcAg) expressed in Escherichia coli self-assembles into icosahedral capsids of about 35 nm which can be exploited as gene or drug delivery vehicles. The association and dissociation properties of the C-terminally truncated HBcAg with urea and guanidine hydrochloride (GdnHCl) were studied. Transmission electron microscopy (TEM) revealed that the dissociated HBcAg was able to re-associate into particles when the applied denaturing agents were physically removed. In order to evaluate the potential of the particles in capturing molecules, purified green fluorescent protein (GFP) was applied to the dissociated HBcAg for encapsidation. The HBcAg particles harbouring the GFP molecules were purified using sucrose density gradient ultracentrifugation and analysed using native agarose gel electrophoresis and TEM. A method for the encapsidation of GFP in HBcAg particles which has the potential to capture drugs or nucleic acids was established.

Epitope diversity of hepatitis B virus capsids: quasi-equivalent variations in spike epitopes and binding of different antibodies to the same epitope.

To investigate the range of antigenic variation of HBV capsids, we have characterized the epitopes for two anti-capsid antibodies by cryo-electron microscopy and image reconstruction of Fab-labeled capsids to approximately 10A resolution followed by molecular modeling. Both antibodies engage residues on the protruding spikes but their epitopes and binding orientations differ. Steric interference effects limit maximum binding to approximately 50% average occupancy in each case. However, the occupancies of the two copies of a given epitope that are present on a single spike differ, reflecting subtle distinctions in structure and hence, binding affinity, arising from quasi-equivalence. The epitope for mAb88 is conformational but continuous, consisting of a loop-helix motif (residues 77-87) on one of the two polypeptide chains in the spike. In contrast, the epitope for mAb842, like most conformational epitopes, is discontinuous, consisting of a loop on one polypeptide chain (residues 74-78) combined with a loop-helix element (residues 78-83) on the other. The epitope of mAb842 is essentially identical with that previously mapped for mAb F11A4, although the binding orientations of the two monoclonal antibodies (mAbs) differ, as do their affinities measured by surface plasmon resonance. From the number of monoclonals (six) whose binding had to be characterized to give the first duplicate epitope, we estimate the total number of core antigen (cAg) epitopes to be of the order of 20. Given that different antibodies may share the same epitope, the potential number of distinct anti-cAg clones should be considerably higher. The observation that the large majority of cAg epitopes are conformational reflects the relative dimensions of a Fab (large) and the small size and close packing of the motifs that are exposed and accessible on the capsid surface.

Expression and purification of the recombinant HBcAg core particles derived from methyltrophic Pichia pastoris, and TEM and AFM of the core particles and their natural aggregates.

The recombinant hepatitis B virus core antigen (rHBcAg) core particles derived from Pichia pastoris were purified from a crude lysate of the yeast by three steps: Sephrose CL-4B chromatography, sucrose step-gradient ultracentrifugation and CsCl-isopycnic ultracentrifugation. Results of ELISA test and density analysis of CsCl-isopycnic ultracentrifugation indicate that the purified rHBcAg particles with HBcAg antigenicity mainly locate at the densities of 1.2576 and 1.3013 g.mL(-1), respectively. After purification, a portion of purified sample of rHBcAg particles was immediately subjected to detection using transmission electron microscopy (TEM) and atomic force microscopy (AFM), the remainder were kept in -20 degrees C for 1 month or longer. After 30 days, the sample of rHBcAg particles previously frozen was imaged by TEM and AFM. The detection results indicate that the stored rHBcAg particles aggregated into a string of beads. The above results suggested that the rHBcAg particles expressed and self-assembled in P. pastoris, which were stored at -20 degrees C, can gradually and naturally aggregate with storage time.

Evolutionary conservation in the hepatitis B virus core structure: comparison of human and duck cores.

BACKGROUND: Hepatitis B virus is a major human pathogen which has been extensively studied, yet its structure is unknown. Cryo-electron microscopy of the viral cores expressed in Escherichia coli or isolated from infected liver provides a means for determining the structure of the hepatitis B nucleocapsid. RESULTS: Using cryo-electron microscopy and three-dimensional image reconstruction, we have determined the structures of duck and human hepatitis B virus cores and find that they have similar dimer-clustered T = 3 and T = 4 icosahedral organizations. The duck virus core protein sequence differs from the human in both length and amino acid content; however, the only significant structural differences observed are the lobes of density on the lateral edges of the projecting (distal) domain of the core protein dimer. The different cores contain varying amounts of nucleic acid, but exhibit similar contacts between the core protein and the nucleic acid. Immunoelectron microscopy of intact cores has localized two epitopes on the core surface corresponding to residues 76-84 and 129-132. CONCLUSIONS: The bacterial expression system faithfully reproduces the native hepatitis B virus core structure even in the absence of the complete viral genome. This confirms that proper assembly of the core is independent of genome packaging. Difference imaging and antibody binding map three sequence positions in the structure: the C terminus and the regions near amino acids 80 and 130. Finally, we suggest that the genome-core interactions and the base (proximal) domain of the core dimer are evolutionarily conserved whereas the projecting domain, which interacts with the envelope proteins, is more variable.

The Structural Biology of Hepatitis B Virus: Form and Function.

Hepatitis B virus is one of the smallest human pathogens, encoded by a 3,200-bp genome with only four open reading frames. Yet the virus shows a remarkable diversity in structural features, often with the same proteins adopting several conformations. In part, this is the parsimony of viruses, where a minimal number of proteins perform a wide variety of functions. However, a more important theme is that weak interactions between components as well as components with multiple conformations that have similar stabilities lead to a highly dynamic system. In hepatitis B virus, this is manifested as a virion where the envelope proteins have multiple structures, the envelope-capsid interaction is irregular, and the capsid is a dynamic compartment that actively participates in metabolism of the encapsidated genome and carries regulated signals for intracellular trafficking.

Interaction of wild-type and naturally occurring deleted variants of hepatitis B virus core polypeptides leads to formation of mosaic particles.

The simultaneous presence of hepatitis B virus (HBV) genomes carrying wild-type (wt) and in-frame deleted variants of the HBV core gene has been identified as a typical feature of HBV-infected renal transplant patients with severe liver disease. To investigate possible interactions of wt and deleted core polypeptides a two-vector Escherichia coli expression system ensuring their concomitant synthesis has been developed. Co-expression of wt and a mutant core lacking 17 amino acid residues (77-93) within the immunodominant region led to the formation of mosaic particles, whereas the mutant alone was incapable of self-assembly.

Localization of the amino terminus of the hepatitis B virus core antigen within the core particle.

The position of the amino terminus of the hepatitis B virus core antigen (HBcAg) within the core particle was studied. For this purpose, three recombinant analogs of HBcAg were designed. One analog, HBcAgR, was identical in amino acid sequences to the core polypeptide of the hepatitis B virus; the second, HBeAgR, differed from the authentic protein in deletion of 39 carboxy-terminal amino acids. The amino acid sequences of the third polypeptide, HBe delta N and of HBeAgR were similar, HBe delta N differed from HBeAgR only in replacement of 3 N-terminal amino acids by 16 amino acids of beta-galactosidase. The HBcAg analogs were compared with respect to their reaction with monoclonal antibody (mAb E1A7) to the amino-terminal linear epitope of hepatitis B virus e antigen. Although able to assemble into virus-like particles, the three analogs of HBcAg, reacted differently with mAb E1A7. It was demonstrated that mAb E1A7 reacted with both native and denatured HBeAgR. HBe delta N was not recognized by mAb E1A7. In contrast, HBcAgR reacted with mAb E1A7 only when denatured. Native HBcAgR did not react with mAb E1A7 when assembled into particles. Thus evidence was obtained that the amino terminus of HBcAg is not exposed on the particle surface.

Purification of E. coli-expressed HIS-tagged hepatitis B core antigen by Ni2+ -chelate affinity chromatography.

Hepatitis B virus is a major cause of human liver disease. In the case of chronic infection the virus can lead to liver cancer and cirrhosis. The virion consists of an outer envelope containing lipids of the endoplasmic reticulum and virally-encoded surface proteins. This lipoprotein shell encloses the nucleocapsid or core antigen (HBcAg), which contains the viral genome. The capsid consists of dimers of a 183-residue protein, which can be divided into an assembly (residues 1-149) and a protamin-like domain (residues 150-183), responsible for polymerization into particles and RNA packaging, respectively. Upon expression of the core gene in bacteria the products are assembled into capsids resembling those of wild type particles. A purification protocol was developed for unpolymerised (dimeric) and polymerized HBcAg by fusion of six histidine residues to a C-terminal deletion mutant of the core protein allowing the isolation of the respective antigens after denaturing Ni2+-chelate affinity chromatography and renaturing dialysis. The possible incorporation of E. coli proteins during the assembly process and the inclusion of nucleic acids can be avoided. The method might be an attractive alternative to common purification protocols of hybrid virus-like particles (VLPs) for vaccine use.

Purification of the recombinant hepatitis B virus core antigen (rHBcAg) produced in the yeast Saccharomyces cerevisiae and comparative observation of its particles by transmission electron microscopy (TEM) and atomic force microscopy (AFM).

Hepatitis B virus core antigen (HBcAg) gene (C gene) was expressed in Saccharomyces cerevisiae and the products (rHBcAg or core particles) were purified from a crude lysate of the yeast by three steps: Sephrose CL-4B chromatography, Sucrose step-gradient ultracentrifugation and CsCl-isopycnic ultracentrifugation. It has been observed that HBcAg was synthesized in yeast cells as a particle consisting of polypeptides with a molecular weight of 21.5 kDa (p21.5). Results of ELISA test and density analysis of CsCl-isopycnic ultracentrifugation indicated that the purified products (rHBcAg particles) with HBcAg antigenicity mainly located at the densities of 1.27 and 1.40 g ml(-1), respectively. Observation and analysis of the purified rHBcAg products by TEM indicated that rHBcAg peptides could mainly self-assemble into two size classes of core particles. The larger particles were approximately 30.1 nm and the smaller were approximately 21.5 nm in mean diameter. Further observation and analysis of the same rHBcAg (core) particles by AFM also indicated that rHBcAg (core) particles were similar to the native HBcAg (core) particles from infected human hepatocytes and mainly composed of two size classes of partides core. The larger particles were approximately 31.3 nm and the smaller were approximately 22.5 nm in mean diameter which was similar to the results obtained by TEM. All results from both TEM and AFM suggested that core particles (capsids) produced in S. cerevisiae possessed dimorphism.

Chimpanzee livers after infection with human hepatitis viruses A and B: Ultrastructural studies.

Electron microscopical studies were carried out on coded liver biopsy specimens from chimpanzees inoculated with human hepatitis A or B virus. Hepatitis B was recognized by the presence of hepatitis B core particles in hepatocellular nuclei. Hepatitis A was characterized by unidentified large, dense, and more irregular heterochromatin-like particles in hepatocellular nuclei coincidental with peak aminotransferase activities. As type A hepatitis illness became manifest in the chimpanzees, mitochondrial cristae were curled and attenuated, and clusters of endoplasmic reticulum were tightly packed. In contrast, the livers in viral hepatitis B showed mainly hypertrophy of tubular smooth endoplasmic reticulum. This suggested different pathogenetic mechanisms in A and B chimpanzee viral hepatitis.

A VLP library of C-terminally truncated Hepatitis B core proteins: correlation of RNA encapsidation with a Th1/Th2 switch in the immune responses of mice.

An efficient pBR327- and Ptrp-based E. coli expression system was used to generate a large-scale library of virus like particles (VLP) formed by recombinant hepatitis B virus (HBV) core (HBc) protein derivatives. To construct the library, the gene of HBc protein of the genotype D/subtype ayw2 virus was gradually truncated from the 3`-end and twenty-two HBc variants (with truncation up to 139 aa) were expressed at high levels. The proteins were purified by salt precipitation and gel filtration. Background RNA binding was observed for VLPs formed by HBc1-149, which lacked all C-terminal Arg blocks, and the addition of three Arg residues (HBc1-152) only slightly increased RNA binding. The presence of two Arg blocks (proteins HBc1-162 and HBc1-163) resulted in approximately half of the typical level of RNA binding, and the presence of three blocks (protein HBc1-171) led to approximately 85% of the typical level of binding. Only a small increase in the level of RNA binding was found for the HBc1-175 VLPs, which contained all four Arg blocks but lacked the last 8 aa of the full-length HBc protein. VLPs containing high levels of RNA had higher antigenicity according to an ELISA with anti-HBc mAbs than the VLPs formed by HBc variants without C-terminal Arg blocks and lacking RNA. The results indicate that the VLPs were stabilised by nucleic acids. The immunogenicity in BALB/c mice was comparable for VLPs formed by different HBc proteins, but a clear switch from a Th1 response to a Th2 response occurred after the loss of encapsidated RNA. We did not observe significant differences in lymphocyte proliferation in vitro for the tested VLP variants; however, the loss of RNA encapsidation correlated with a decreased level of IFN-γ induction, which is a measure of the potential CTL activity of immunogens.

Three-dimensional structure of the hepatitis B core antigen particle truncated at residue 154.

The three-dimensional structure of recombinant hepatitis B core antigen (HBcAg) particles truncated at residue 154 (HBcAg-154) was determined to 7.8 Å resolution by cryo-electron microscopy (cryoEM) and computer reconstruction. The capsid of HBcAg-154 is mainly constituted by α-helical folds, highly similar to that of HBcAg-149. The C-terminal region between residues 155 and 183 of the core protein is more crucial to the encapsidation of RNA, and the short C-terminal tail of HBcAg-154 results in a nearly empty capsid.

Structural comparisons of hepatitis B core antigen particles with different C-terminal lengths.

Core protein of hepatitis B virus (HBV) with various C-terminal lengths (residue 154, 164, 167 and 183) can self-assemble into recombinant hepatitis B core antigen (HBcAg) particles. To understand the RNA encapsidation mechanism of HBV, the three-dimensional structures of these particles were reconstructed by cryo-electron microscopy (cryoEM). Detailed structural comparisons showed that their capsid structures are highly similar, while the RNA content is increased upon the retention of more amino acid residues at the C-terminus of core protein, suggesting the crucial role of the basic C-terminal tail on determining the genome size.

Enhanced capacity of antigen presentation of HBc-VLP-pulsed RAW264.7 cells revealed by proteomics analysis.

Many recent studies have indicated that virus-like particles (VLPs) have many potential applications in the fields of vaccine development and gene therapy. However, we still know little about the subtle mechanisms involved in the presentation of VLPs by antigen presenting cells (APCs). To illustrate the mechanisms, we utilized two-dimensional electrophoresis and tandem MS to compare and identify differentially expressed proteins between hepatitis B virus core antigen VLP (HBc-VLP)-pulsed and control RAW264.7 cells. Of the 25 spots identified as differentially expressed ( p < 0.05) between the two cell lines, 11 (corresponding to 11 unique proteins) were positively identified. Further analysis of two proteins, prohibitin and heat shock protein 70, confirmed that these proteins are expressed at higher levels in HBc-VLP-pulsed RAW264.7 cells compared with control cells. The proteins identified in this study will be useful in revealing the mechanisms that underlie VLP-APC interactions. Overall, this study also provides some useful suggestions for vaccine development and gene therapy.

Identification of hepatitis B virus core protein regions exposed or internalized at the surface of HBcAg particles by scanning with monoclonal antibodies.

Hepatitis B virus (HBV) core antigen (HBcAg) particles purified from Escherichia coli were probed in a competition enzyme immunoassay (EIA) with a panel of 16 murine monoclonal antibodies (MAbs) directed to different forms of core protein. The linear binding sites of the MAbs were mapped by combination of solid-phase and competition EIA using synthetic peptides covering the complete sequence of HBV core protein. Relative accessibilities of the linear binding sites at the HBcAg surface were investigated by comparing reactivities in solution of the MAbs to (i) two genetic variants of particulate HBcAg, (ii) denatured core protein, and (iii) synthetic peptides mimicking the appropriate linear binding sites. Further, accessibilities of HBV preS1 and preS2 epitopes (introduced into core protein at positions 77 or 144) at the surface of chimeric HBcAg particles were investigated. The previously described surface localization of core protein region 78-83 at the core particle surface was confirmed. In addition, another region, encompassing residues 127-133, was found to occupy a surface position at particulate HBcAg, whereas regions 9-20 and 133-145 were exposed after denaturation of the core protein and at synthetic peptides but not at particulate HBcAg.

Three-dimensional structure of hepatitis B virus core particles determined by electron cryomicroscopy.

Human hepatitis B virus core protein expressed in E. coli assembles into two sizes of particle. We have determined their three-dimensional structures by electron cryomicroscopy and image processing. The large and small particles correspond to triangulation number T = 4 and T = 3 dimer clustered packings, containing 240 and 180 protein subunits, respectively. The local packing of subunits is very similar in the two sizes of particle and shows holes or channels through the shell. The native viral core particle packages RNA and is active in reverse transcription to DNA. The holes we observe may provide access for the necessary small molecules. Shells assembled from the intact core protein contain additional material, probably RNA, which appears as an icosahedrally ordered inner shell in the three-dimensional map.

A protease-sensitive hinge linking the two domains of the hepatitis B virus core protein is exposed on the viral capsid surface.

Core particles of hepatitis B virus are assembled from dimers of a single 185-residue (subtype adw) viral capsid or core protein (p21.5) which possesses two distinct domains: residues 1 to 144 form a minimal capsid assembly domain, and the arginine-rich, carboxyl-terminal residues 150 to 185 form a protamine-like domain that mediates nucleic acid binding. Little is known about the topography of the p21.5 polypeptide within either the p21.5 capsids or dimers. Here, using site-specific proteases and monoclonal antibodies, we have defined the accessibility of p21.5 residues in dimers and capsids assembled from wild-type and mutant hepatitis B virus core proteins in Xenopus oocytes and in vitro. The data reveal the protamine region to be accessible to external reagents in p21.5 dimers but largely cryptic in wild-type capsids. Strikingly, in capsids the only protease target region was a 9-residue peptide covering p21.5 residues Glu-145 to Asp-153, which falls largely between the two core protein domains. By analogy with protease-sensitive interdomain regions in other proteins, we propose that this peptide constitutes a hinge between the assembly and nucleic acid binding domains of p21.5. We further found that deletion or replacement of the terminal Cys-185 residue greatly increased surface exposure of the protamine tails in capsids, suggesting that a known disulfide linkage involving this residue tethers the protamine region inside the core particles. We propose that disruption of this disulfide linkage allows the protamine region to appear transiently on the surface of the core particle.