Interaction between nucleophosmin and HBV core protein increases HBV capsid assembly

Host factors are involved in Hepatitis B virus (HBV) genome replication and capsid formation during the viral life cycle. A host factor, nucleophosmin (B23), was found to bind to HBV core protein dimers, but its functional role has not been studied. This interaction promoted HBV capsid assembly and decreased the degree of capsid dissociation when subjected to denaturant treatments in vitro. In addition, inhibition of B23 reduced intracellular capsid formation resulting in a decrease of HBV production in HepG2.2.15 cells. These results provide important evidence that B23 acts on core capsid assembly via its interaction with HBV core dimers.     

Conformational equilibria and rates of localized motion within hepatitis B virus capsids

Functional analysis of hepatitis B virus (HBV) core particles has associated a number of biological roles with the C terminus of the capsid protein. One set of functions require the C terminus to be on the exterior of the capsid, while others place this domain on the interior. According to the crystal structure of the capsid, this segment is strictly internal to the capsid shell and buried at a protein-protein interface. Using kinetic hydrolysis, a form of protease digestion assayed by SDS-PAGE and mass spectrometry, the structurally and biologically important C-terminal region of HBV capsid protein assembly domain (Cp149, residues 1-149) has been shown to be dynamic in both dimer and capsid forms. HBV is an enveloped virus with a T = 4 icosahedral core that is composed of 120 copies of a homodimer capsid protein. Free dimer and assembled capsid forms of the protein are readily hydrolyzed by trypsin and thermolysin, around residues 127-128, indicating that this region is dynamic and exposed to the capsid surface. The measured conformational equilibria have an opposite temperature dependence between free dimer and assembled capsid. This work helps to explain the previously described allosteric regulation of assembly and functional properties of a buried domain. These observations make a critical connection between structure, dynamics, and function: made possible by the first quantitative measurements of conformational equilibria and rates of conversion between protein conformers for a megaDalton complex.     

乙肝病毒核心蛋白钉突部位基因工程改造对其功能的影响

通过在乙肝病毒核心蛋白钉突部位插入标签蛋白EGFP及小片段多肽,研究各种改造对HBc功能的影响。采用RLIC方法,构建野生型HBc、HBc钉突部位带不同接头的EGFP融合重组体、缩短的EGFP融合重组体,并构建与HBc功能互补的质粒HBV1.1c－,将不同重组体与HBV1.1c－共转染HEK293细胞,通过观察荧光及Southern blotting检测病毒复制中间体,判断相应基因工程改造对重组蛋白中不同结构域功能的影响。RLIC方法可有效地用来进行片段缺失,且缺失片段大小及位置无明显限制。带柔性或刚性接头的重组HBc-EGFP均可产生绿色荧光,但荧光在细胞内分布形态不同,两种重组HBc-EGFP均不能支持正常的HBV复制,各种截短的插入片段以及aa79-80单独缺失体亦不能支持HBV复制。结果表明RLIC方法是一种基因工程改造的有力工具,不同类型接头对重组蛋白的结构和功能有不同影响,aa79-80对维持HBc的主要功能之一——支持HBV复制有重要作用。     

Structure-based design and biochemical evaluation of sulfanilamide derivatives as hepatitis B virus capsid assembly inhibitors

Virus capsid structure is essential in virion maturation and durability, so disrupting capsid assembly could be an effective way to reduce virion count and cure viral diseases. However, currently there is no known antiviral which affects capsid inhibition, and only a small number of assembly inhibitors were experimentally successful. In this present study, we aimed to find hepatitis B virus (HBV) capsid assembly inhibitor which binds to the HBV core protein and changes protein conformation. Several candidate molecules were found to bind to certain structure in core protein with high specificity. Furthermore, these molecules significantly changed the protein conformation and reduced assembly affinity of core protein, leading to decrease of the number of assembled capsid or virion, both in vitro and in vivo. In addition, prediction also suggests that improvements in inhibition efficiency could be possible by changing functional groups and ring structures.     

Packaging of up to 240 subunits of a 17 kDa nuclease into the interior of recombinant hepatitis B virus capsids

The icosahedral nucleocapsid of hepatitis B virus (HBV) consists of multiple subunits of a single 183 amino acids (aa) core protein encasing the viral genome. However, recombinant core protein alone also forms capsid-like particles. We have recently shown that a 238 aa protein centrally inserted into the core protein can be displayed on the particle surface. Here we demonstrate that replacement of the C-terminal basic domain by the 17 kDa Staphylococcus aureus nuclease also yields particles but that in these the foreign domains are located in the interior. The packaged nuclease is enzymatically active, and the chimeric protein forms mosaic particles with the wild-type core protein. Hence the HBV capsid is useful as a molecular platform which, dependent on the fusion site, allows foreign protein domains to either be packaged into or be exposed on the exterior of the particle. These results are of relevance for the use of the HBV capsid as a vaccine carrier, and as a target for antiviral therapy.     

Hepatitis B virus nucleocapsid assembly: primary structure requirements in the core protein.

As a step toward understanding the assembly of the hepatitis B virus (HBV) nucleocapsid at a molecular level, we sought to define the primary sequence requirements for assembly of the HBV core protein. This protein can self assemble upon expression in Escherichia coli. Applying this system to a series of C-terminally truncated core protein variants, we mapped the C-terminal limit for assembly to the region between amino acid residues 139 and 144. The size of this domain agrees well with the minimum length of RNA virus capsid proteins that fold into an eight-stranded beta-barrel structure. The entire Arg-rich C-terminal domain of the HBV core protein is not necessary for assembly. However, the nucleic acid content of particles formed by assembly-competent core protein variants correlates with the presence or absence of this region, as does particle stability. The nucleic acid found in the particles is RNA, between about 100 to some 3,000 nucleotides in length. In particles formed by the full-length protein, the core protein mRNA appears to be enriched over other, cellular RNAs. These data indicate that protein-protein interactions provided by the core protein domain from the N terminus to the region around amino acid 144 are the major factor in HBV capsid assembly, which proceeds without the need for substantial amounts of nucleic acid. The presence of the basic C terminus, however, greatly enhances encapsidation of nucleic acid and appears to make an important contribution to capsid stability via protein-nucleic acid interactions. The observation of low but detectable levels of nucleic acid in particles formed by core protein variants lacking the Arg-rich C terminus suggests the presence of a second nucleic acid-binding motif in the first 144 amino acids of the core protein. Based on these findings, the potential importance of the C-terminal core protein region during assembly in vivo into authentic, replication-competent nucleocapsids is discussed.     

Weak protein-protein interactions are sufficient to drive assembly of hepatitis B virus capsids

Hepatitis B virus (HBV) is an enveloped DNA virus with a spherical capsid (or core). The capsid is constructed from 120 copies of the homodimeric capsid protein arranged with T = 4 icosahedral symmetry. We examined in vitro assembly of purified E. coli expressed HBV capsid protein. After equilibration, concentrations of capsid and dimer were evaluated by size exclusion chromatography. The extent of assembly increased as temperature and ionic strength increased. The concentration dependence of capsid assembly conformed to the equilibrium expression: K(capsid) = [capsid]/[dimer](120). Given the known geometry for HBV capsids and dimers, the per capsid assembly energy was partitioned into energy per subunit-subunit contact. We were able to make three major conclusions. (i) Weak interactions (from -2.9 kcal/mol at 21 degrees C in low salt to -4.4 kcal/mol at 37 degrees C in high salt) at each intersubunit contact result in a globally stable capsid; weak intersubunit interactions may be the basis for the phenomenon of capsid breathing. (ii) HBV assembly is characterized by positive enthalpy and entropy. The reaction is entropy-driven, consistent with the largely hydrophobic contacts found in the crystal structure. (iii) Increasing NaCl concentration increases the magnitude of free energy, enthalpy, and entropy, as if ionic strength were increasing the amount of hydrophobic surface buried by assembly. This last point leads us to suggest that salt acts by inducing a conformational change in the dimer from an assembly-inactive form to an assembly-active form. This model of conformational change linked to assembly is consistent with immunological differences between dimer and capsid.     

Alix regulates egress of hepatitis B virus naked capsid particles in an ESCRT-independent manner

Hepatitis B virus (HBV) is an enveloped DNA virus that exploits the endosomal sorting complexes required for transport (ESCRT) pathway for budding. In addition to infectious particles, HBV-replicating cells release non-enveloped (nucleo)capsids, but their functional implication and pathways of release are unclear. Here, we focused on the molecular mechanisms and found that the sole expression of the HBV core protein is sufficient for capsid release. Unexpectedly, released capsids are devoid of a detectable membrane bilayer, implicating a non-vesicular exocytosis process. Unlike virions, naked capsid budding does not require the ESCRT machinery. Rather, we identified Alix, a multifunctional protein with key roles in membrane biology, as a regulator of capsid budding. Ectopic overexpression of Alix enhanced capsid egress, while its depletion inhibited capsid release. Notably, the loss of Alix did not impair HBV production, furthermore indicating that virions and capsids use diverse export routes. By mapping of Alix domains responsible for its capsid release-mediating activity, its Bro1 domain was found to be required and sufficient. Alix binds to core via its Bro1 domain and retained its activity even if its ESCRT-III binding site is disrupted. Together, the boomerang-shaped Bro1 domain of Alix appears to escort capsids without ESCRT.     

Phosphorylation of hepatitis B virus core C-terminally truncated protein (Cp149) by PKC increases capsid assembly and stability

The HBV (hepatitis B virus) core is a phosphoprotein whose assembly, replication, encapsidation and localization are regulated by phosphorylation. It is known that PKC (protein kinase C) regulates pgRNA (pregenomic RNA) encapsidation by phosphorylation of the C-terminus of core, which is a component packaged into capsid. Neither the N-terminal residue phosphorylated by PKC nor the role of the C-terminal phosphorylation have been cleary defined. In the present study we found that HBV Cp149 (core protein C-terminally truncated at amino acid 149) expressed in Escherichia coli was phosphorylated by PKC at Ser(106). PKC-mediated phosphorylation increased core affinity, as well as assembly and capsid stability. In vitro phosphorylation with core mutants (S26A, T70A, S106A and T114A) revealed that the Ser(106) mutation inhibited phosphorylation of core by PKC. CD analysis also revealed that PKC-mediated phosphorylation stabilized the secondary structure of capsid. When either pCMV/FLAG-Cp149[WT (wild-type)] or pCMV/FLAG-S106A Cp149 was transfected into Huh7 human hepatoma cells, mutant capsid level was decreased by 2.06-fold with the S106A mutant when compared with WT, although the same level of total protein was expressed in both cases. In addition, when pUC1.2x and pUC1.2x/S106A were transfected, mutant virus titre was decreased 2.31-fold compared with WT virus titre. In conclusion, PKC-mediated phosphorylation increased capsid assembly, stability and structural stability.     

Native hepatitis B virions and capsids visualized by electron cryomicroscopy

Hepatitis B virus (HBV) infects more than 350 million people, of which one million will die every year. The infectious virion is an enveloped capsid containing the viral polymerase and double-stranded DNA genome. The structure of the capsid assembled in vitro from expressed core protein has been studied intensively. However, little is known about the structure and assembly of native capsids present in infected cells, and even less is known about the structure of mature virions. We used electron cryomicroscopy (cryo-EM) and image analysis to examine HBV virions (Dane particles) isolated from patient serum and capsids positive and negative for HBV DNA isolated from the livers of transgenic mice. Both types of capsids assembled as icosahedral particles indistinguishable from previous image reconstructions of capsids. Likewise, the virions contained capsids with either T = 3 or T = 4 icosahedral symmetry. Projections extending from the lipid envelope were attributed to surface glycoproteins. Their packing was unexpectedly nonicosahedral but conformed to an ordered lattice. These structural features distinguish HBV from other enveloped viruses.     

Peptide aptamer-mediated inhibition of target proteins by sequestration into aggresomes

Peptide aptamers (PAs) can be employed to block the intracellular function of target proteins. Little is known about the mechanism of PA-mediated protein inhibition. Here, we generated PAs that specifically bound to the duck hepatitis B virus (HBV) core protein. Among them, PA34 strongly blocked duck HBV replication by inhibiting viral capsid formation. We found that PA34 led to a dramatic intracellular redistribution of its target protein into perinuclear inclusion bodies, which exhibit the typical characteristics of aggresomes. As a result, the core protein is efficiently removed from the viral life cycle. Corresponding findings were obtained for bioactive PAs that bind to the HBV core protein or to the human papillomavirus-16 (HPV16) E6 protein, respectively. The observation that PAs induce the specific sequestration of bound proteins into aggresomes defines a novel mechanism as to how this new class of intracellular inhibitors blocks the function of their target proteins.     

Cys residues of the hepatitis B virus capsid protein are not essential for the assembly of viral core particles but can influence their stability.

In the spherical capsid of hepatitis B virus (HBV), intermolecular disulfide bonds cross-link the approximately 180 p21.5 capsid protein subunits into a stable lattice. In this study, we used mutant capsid proteins to investigate the role that disulfide bonds and the four p21.5 Cys residues (positions 48, 61, 107, and 185) play in capsid assembly and/or stabilization. p21.5 Cys residues were either replaced by Ala or removed (Cys-185) by carboxyl-terminal truncation, creating Cys-minus mutants which were expressed in Xenopus oocytes via microinjected synthetic mRNAs. Fractionation of radiolabeled oocyte extracts on 10 to 60% sucrose gradients revealed that Cys-minus core proteins resolved into the nonparticulate and capsid forms seen for wild-type p21.5. On 5 to 30% sucrose gradients, nonparticulate Cys-minus core proteins sedimented as dimers of approximately 40 kDa. We conclude that Cys residues and disulfides are not required for the assembly of either HBV capsids or the dimers that provide the precursors for capsid assembly. Since assembly presumably demands an appropriate p21.5 tertiary structure, it is unlikely that Cys residues are required for proper p21.5 folding. However, Cys residues stabilize isolated p21.5 structures, as evidenced by the marked reduction in stability of Cys-minus dimers and capsids (i) in nonreducing sodium dodecyl sulfate-polyacrylamide gel electrophoresis and (ii) upon protease digestion. We discuss these results in the context of the HBV life cycle and the role of Cys residues in other proteins.     

Replication advantage and host factor-independent phenotypes attributable to a common naturally occurring capsid mutation (I97L) in human hepatitis B virus

Mutations of human hepatitis B virus (HBV) occur frequently within the capsid (core) protein in natural infections. The most frequent mutation of the core protein in HBV from Southeast Asia occurs at amino acid 97, changing an isoleucine (I) to a leucine (L). In our systematic study of virus-host interactions, we have examined the replication efficiency of a site-directed mutant, I97L, and its parental wild-type HBV in several different hepatoma cell lines. Interestingly, we found that this capsid variant replicated in human Huh7 hepatoma cells approximately 4.8-fold better than its parental wild-type HBV. A similar phenomenon was observed in another hepatoma cell line, J3. In addition, the level of encapsidated RNA pregenome in mutant I97L was about 5.7-fold higher than that of the wild-type HBV in Huh7 cells. Unlike Huh7 cells, no significant difference in viral DNA replication between the same I97L mutant and its parental wild-type HBV was observed in HepG2, a human hepatoblastoma cell line. This finding of a profound replication advantage for mutant I97L in Huh7 and J3 cells but not in HepG2 cells may have important implications for the emergence of this mutant in chronic HBV carriers. We speculate here that the mutation confers a host factor-independent growth advantage for the survival of HBV variants in gradually dedifferentiating hepatocytes and thus helps prolong viral persistence.     

Mapping of amino acid side chains on the surface of hepatitis B virus capsids required for envelopment and virion formation

The crystal structure of recombinant hepatitis B virus (HBV) capsids formed by 240 core proteins has recently been published. We wanted to map sites on the surface of the icosahedral 35-nm particle that are important for nucleocapsid envelopment by HBV surface proteins during virion morphogenesis. For this purpose, we individually mutated 52 amino acids (aa) within the N-terminal 140 aa of the 185-aa long core protein displaying their side chains to the external surface of the capsid to alanine residues. The phenotype of the mutations with respect to virion formation was tested by transcomplementation of a core gene-negative HBV genome in transiently cotransfected cells, immunoprecipitation of nucleocapsids from cells and secreted virions from culture media, and detection of the particles by radioactive endogenous polymerase reactions. Thirteen point mutations impeded nucleocapsid detection by endogenous polymerase reactions. Twenty-seven mutations were compatible with virion formation. Among these were all capsid-forming mutations in the upper half of the spike protruding from the particle shell and two additional triple mutations at tip of the spike. Eleven mutations (S17, F18, L60, L95, K96, F122, I126, R127, N136, A137, and I139) allowed nucleocapsid formation but blocked particle envelopment and virion formation to undetectable levels. These mutations map to a ring-like groove around the base of the spike and to a small area at the capsid surface close to the pores in the capsid shell. These residues are candidate sites for the interaction with envelope proteins during virion morphogenesis.