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.     

Biosynthesis of the secretory core protein of duck hepatitis B virus: intracellular transport, proteolytic processing, and membrane expression of the precore protein.

The biosynthesis of the secretory core gene product of the duck hepatitis B virus (DHBe protein) was examined. Recombinant vaccinia viruses were constructed encoding either the full-length or C-terminally truncated forms of the DHBe precursor protein (precore protein) and used to express these proteins in the human hepatoma cell line HepG2. Western immunoblot analysis of core gene products isolated from cells producing the full-length precore protein revealed the presence of DHBe precursor proteins containing the strongly basic C-terminal sequence which is lacking in the mature DHBe protein. These proteins were not secreted, suggesting that C-terminal proteolytic processing of the precore protein represents an obligatory step for DHBe biosynthesis. Pulse-chase experiments showed that this cleavage reaction occurs late during DHBe synthesis. Interestingly, when mutated precore proteins were expressed which lacked the basic C-terminal domain, proteins were produced which were glycosylated but not secreted. This shows that the transient presence of this region is essential for intracellular transport of the precore protein. Cell sorter analyses revealed that production of a cell surface-expressed variant of the secretory core protein is a feature conserved between the duck and the human hepatitis B viruses. Surprisingly, the C terminus of the membrane-expressed DHBe protein was accessible from the outside, showing that the topology of this interesting protein is more complicated than expected.     

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.     

Antigenic determinants and functional domains in core antigen and e antigen from hepatitis B virus.

The precore/core gene of hepatitis B virus directs the synthesis of two polypeptides, the 21-kilodalton subunit (p21c) forming the viral nucleocapsid (serologically defined as core antigen [HBcAg]) and a secreted processed protein (p17e, serologically defined as HBe antigen [HBeAg]). Although most of their primary amino acid sequences are identical, HBcAg and HBeAg display different antigenic properties that are widely used in hepatitis B virus diagnosis. To locate and to characterize the corresponding determinants, segments of the core gene were expressed in Escherichia coli and probed with a panel of polyclonal or monoclonal antibodies in radioimmunoassays or enzyme-linked immunosorbent assays, Western blots, and competition assays. Three distinct major determinants were characterized. The single conformational determinant responsible for HBc antigenicity in the assembled core (HBc) and a linear HBe-related determinant (HBe1) were both mapped to an overlapping hydrophilic sequence around amino acid 80; a second HBe determinant (HBe2) was assigned to a location in the vicinity of amino acid 138 but found to require for its antigenicity the intramolecular participation of the extended sequence between amino acids 10 and 140. It is postulated that HBcAg and HBeAg share common basic three-dimensional structure exposing the common linear determinant HBe1 but that they differ in the presentation of two conformational determinants that are either introduced (HBc) or masked (HBe2) in the assembled core. The simultaneous presentation of HBe1 and HBc, two distinctly different antigenic determinants with overlapping amino acid sequences, is interpreted to indicate the presence of slightly differently folded, stable conformational states of p21c in the hepatitis B virus nucleocapsid.     

The duck hepatitis B virus pre-C region encodes a signal sequence which is essential for synthesis and secretion of processed core proteins but not for virus formation.

Analysis of the serum of duck hepatitis B virus (DHBV)-infected ducks has revealed the presence of C-terminally truncated viral core proteins (e antigens). These proteins are glycosylated and therefore were not released from infected cells by lysis but rather by active secretion, indicating that the DHBV core protein can be synthesized alternatively as a cytoplasmic or a secretory protein. Transient expression of cloned wild-type DHBV DNA and of a specifically designed viral mutant in a human hepatoma cell line (Hep-G2) showed that the DHBV core gene promoter is active in differentiated human liver cells and that synthesis and secretion of the processed core proteins are dependent on the expression of the pre-C region, a small open reading frame which precedes the core gene. In addition, these experiments showed that the mechanism of core protein processing and secretion is conserved between DHBV and the human hepatitis B virus and therefore might be important for the hepatitis B virus life cycle in general. In spite of this, intrahepatic injection of the pre-C mutant into uninfected ducks resulted in viremia without concomitant e-antigen synthesis, indicating that virus formation is independent of pre-C expression.     

The hepatitis B virus precore protein is retrotransported from endoplasmic reticulum (ER) to cytosol through the ER-associated degradation pathway

The hepatitis B virus precore protein is closely related to the nucleocapsid core protein but is processed distinctly in the cell and plays a different role in the viral cycle. Precore is addressed to the endoplasmic reticulum (ER) through a signal peptide, and the form present in the ER is the P22 protein. P22 is then cleaved in its C-terminal part to be secreted as HBe antigen. In addition, a cytosolic form of 22 kDa less characterized has been observed. Precore gene was shown to be implicated in viral persistence, but until now, the actual protein species involved has not been determined. Our work focuses on the cytosolic form of precore. Using human cells expressing precore and a convenient fractionation assay, we demonstrated that the cytosolic form is identical to the ER form and retrotransported in the cytoplasm through the ER-associated degradation pathway. This cellular machinery translocates misfolded proteins to the cytoplasm, where they are ubiquitinated on lysine residues and degraded by proteasome. We showed that precore escapes proteasome due to its low lysine content and accumulates in the cytosol. The role of this retrotransport was investigated. In the presence of precore, we found a specific redistribution of the Grp78/BiP chaperone protein to cytosol and demonstrated a specific interaction between precore and Grp78/BiP. Altogether, these data support the idea that the hepatitis B virus develops a strategy to take advantage of the ER-associated degradation pathway, allowing distinct subcellular localization and probably distinct roles for the viral precore protein.     

Transport of hepatitis B virus precore protein into the nucleus after cleavage of its signal peptide.

The precore and core proteins of hepatitis B virus have identical deduced amino acid sequences other than a 29-residue amino-terminal extension (precore region) on the precore protein. The first 19 of these residues serve as a signal sequence to direct the precore protein to the endoplasmic reticulum, where they are cleaved off with formation of precore protein derivative P22 for secretion. In this report, we show that P22 can alternatively be transported into the nucleus following signal peptide cleavage. Experiments with deletion mutants indicated that this nuclear transport proceeds via the cytosol and is dependent on the amino-terminal portion of P22. Thus, the hepatitis B virus precore protein is a secreted, cytosolic, and nuclear protein.     

Hepatitis B Virus with X Gene Mutation Is Associated with the Majority of Serologically “Silent” Non-B,Non-C Chronic Hepatitis

Hepatitis B virus (HBV) with X gene mutations has been a putative pathogen of chronic hepatitis without serological markers of known hepatitis viruses. The aim of this study was to reconfirm whether the HBV with the X gene mutation is associated with these serologically “silent” non-B, non-C (NBNC) chronic hepatitis, alcoholic liver disease (ALD) and autoimmune hepatitis (AIH). HBV DNA was amplified from serum and sequenced in 30 patients with NBNC chronic hepatitis in comparison with 20 patients with ALD and 5 patients with AIH. HBV DNA was identified in 21 patients (70%) in NBNC chronic hepatitis by nested polymerase chain reaction while only one patient (5%) in ALD and none in AIH showed HBV DNA. Eighteen (85.7%) of the 21 identified HBV DNAs had an identical 8-nucleotide deletion mutation at the distal part of the X region. This mutation affected the core promoter and the enhancer II sequence of HBV DNA and created a translational stop codon which truncated the X protein by 20 amino acids from the C-terminal end. All the HBV DNAs had a precore mutation at the 83rd nucleotide resulting in disruption of HBe antigen synthesis. These results indicate that HBV mutants are closely associated with the majority of serologically “silent” NBNC chronic hepatitis cases and the population of such mutant HBV DNAs is not uniform.     

Phosphorylation of hepatitis B virus precore and core proteins.

Hepatitis B virus precore and core proteins are related. The precore protein contains the entire sequence of the core protein plus an amino-terminal extension of 29 amino acids. The amino-terminal extension of the precore protein contains a signal sequence for the secretion of the precore protein. This signal sequence is removed after the translocation of the precore protein across the endoplasmic reticulum membrane to produce the precore protein derivative named P22. We demonstrate that both P22 and the core protein can be phosphorylated in cells. Microsomal fractionation and trypsin digestion experiments demonstrate that a fraction of phosphorylated P22 is located in the endoplasmic reticulum lumen. Phosphorylation of P22 likely occurs in the carboxy terminus, since the P22 derivative P16, which lacks the carboxy terminus of P22, is not phosphorylated. Linking the carboxy terminus of the precore-core protein to heterologous secretory and cytosolic proteins led to the phosphorylation of the resulting chimeric proteins. These results indicate that phosphorylation of P22 and the core protein is likely mediated by cellular kinases.     

Constrained evolution of overlapping genes in viral host adaptation: Acquisition of glycosylation motifs in hepadnaviral precore/core genes

Hepadnaviruses use extensively overlapping genes to expand their coding capacity, especially the precore/core genes encode the precore and core proteins with mostly identical sequences but distinct functions. The precore protein of the woodchuck hepatitis virus (WHV) is N-glycosylated, in contrast to the precore of the human hepatitis B virus (HBV) that lacks N-glycosylation. To explore the roles of the N-linked glycosylation sites in precore and core functions, we substituted T77 and T92 in the WHV precore/core N-glycosylation motifs (⁷⁵NIT⁷⁷ and ⁹⁰NDT⁹²) with the corresponding HBV residues (E77 and N92) to eliminate the sequons. Conversely, these N-glycosylation sequons were introduced into the HBV precore/core gene by E77T and N92T substitutions. We found that N-glycosylation increased the levels of secreted precore gene products from both HBV and WHV. However, the HBV core (HBc) protein carrying the E77T substitution was defective in supporting virion secretion, and during infection, the HBc E77T and N92T substitutions impaired the formation of the covalently closed circular DNA (cccDNA), the critical viral DNA molecule responsible for establishing and maintaining infection. In cross-species complementation assays, both HBc and WHV core (WHc) proteins supported all steps of intracellular replication of the heterologous virus while WHc, with or without the N-glycosylation sequons, failed to interact with HBV envelope proteins for virion secretion. Interestingly, WHc supported more efficiently intracellular cccDNA amplification than HBc in the context of either HBV or WHV. These findings reveal novel determinants of precore secretion and core functions and illustrate strong constraints during viral host adaptation resulting from their compact genome and extensive use of overlapping genes.     

The arginine-rich domain of hepatitis B virus precore and core proteins contains a signal for nuclear transport.

Precore and core proteins are two related co-carboxy-terminal proteins of hepatitis B virus. Precore protein contains the entire sequence of core protein plus an amino-terminal extension of 29 amino acid residues. Both proteins can display a common antigenic determinant known as core antigen (HBcAg). Clinically, HBcAg is detected in the nucleus, cytoplasm, or both of hepatitis B virus-infected hepatocytes. In order to understand the mechanism that regulates nuclear transport of HBcAg, various portions of precore and core proteins were linked to a reporter protein, human alpha-globin, and expressed in mammalian cells. Our results indicate that the precore protein-specific sequence, although important for nuclear transport, does not contain a nuclear localization signal. Instead, a signal for nuclear transport is located near the carboxy termini of precore and core proteins in the arginine-rich domain. This signal is made up of a set of two direct PRRRRSQS repeats and is highly conserved among mammalian hepadnaviruses.     

HBV core particles allow the insertion and surface exposure of the entire potentially protective region of Puumala hantavirus nucleocapsid protein

Core particles of the hepatitis B virus (HBV) potentiate the immune response against foreign epitopes presented on their surface. Potential insertion sites in the monomeric subunit of the HBV core protein were previously identified at the N- and C-terminus and in the immunodominant c/e1 region. In a C-terminally truncated core protein these sites were used to introduce the entire 120 amino acid (aa)-long potentially immunoprotective region of the hantavirus (serotype Puumala) nucleocapsid protein. The N- and C-terminal fusion products were unable to form core-like particles in detectable amounts. However, a suppressable stop codon located between the HBV core and the C-terminally fused hantavirus sequence restored the ability to form particles ('mosaic particles'); in contrast to the C-terminal fusion product the mosaic construct allowed the formation of particles built up by the core protein itself and the HBV core-Puumala nucleocapsid-readthrough protein. The mosaic particles exposed the 120 aa region of the PUU nucleocapsid protein on their surface as demonstrated by ELISA and immuno electron microscopy applying different monoclonal antibodies. Insertion of the hantaviral sequence into the c/e1 region not only allowed the formation of chimeric particles, but again the surface accessibility of the sequence. HBV core antigenicity itself was, however, reduced in the particles carrying insertions in the c/e1 region, probably due to a masking effect of the 120 aa long insert.     

Expression of hepatitis B virus surface and core antigens: influences of pre-S and precore sequences.

Amphotropic retroviral expression systems were used to synthesize hepatitis B virus surface antigen (HBsAg) and core antigen. The vectors permitted establishment of cell lines which expressed antigen from either the retroviral long terminal repeat or the mouse metallothionein-I promoter. HBsAgs were synthesized containing no pre-S sequences, pre-S(2) sequences alone, or pre-S(1) plus pre-S(2) sequences. Inclusion of pre-S(2) sequences did not affect the secretion or density of HBsAg particles but did reduce their mass by approximately 30%. Addition of pre-S(1) sequences almost completely abolished secretion of HBsAg and resulted in its localization in an aqueous-nonextractable pre- or early-Golgi cellular compartment. HBsAg was localized to the cytoplasm of the cell. This localization was unaffected by the presence of pre-S sequences in the antigen. Cell lines synthesizing hepatitis B antigens from core DNA fragments, containing or not containing precore sequences, secreted hepatitis B e antigen. However, the absence of precore DNA sequences resulted in additional synthesis of hepatitis core antigen, which was predominantly nuclear in localization.     

Evidence for a base-paired region of hepatitis B virus pregenome encapsidation signal which influences the patterns of precore mutations abolishing HBe protein expression.

In two natural HBe-minus hepatitis B virus mutants, expression of HBe protein was abrogated by a nonsense mutation at precore codon 28 and a frameshift mutation at codon 29, respectively. Both mutants contained an additional nucleotide substitution(s) which was found by transfection experiments to be required for efficient packaging of pregenomic RNA. The observed mutational profiles were consistent with the presence of a base-paired region of the pregenome encapsidation signal overlapping the HBe-coding sequence. Results obtained with artificial mutants with significant changes in the primary sequence suggested that base pairing is required but insufficient for efficient pregenome packaging. However, the predicted first four base pairs of the stem are dispensable.     

Mutational analysis of hepatitis B surface antigen particle assembly and secretion.

Cells infected with hepatitis B virus produce both virions and 20-nm subviral (surface antigen or HBsAg) particles; the latter are composed of viral envelope proteins and host-derived lipid. Although hepatitis B virus encodes three envelope proteins (L, M, and S), all of the information required to produce an HBsAg particle resides within the S protein. This polypeptide spans the bilayer at least twice and contains three hydrophobic regions, two of which are known to harbor topogenic signal sequences that direct this transmembrane orientation. We have examined the effects of mutations in these and other regions of the S protein on particle assembly and export. Lesions in the N terminal signal sequence (signal I) can still insert into the endoplasmic reticulum bilayer but do not participate in any of the subsequent steps in assembly. Deletion of the major internal signal (signal II) completely destabilizes the chain. Deletion of the C-terminal hydrophobic domain results in a stable, glycosylated, but nonsecreted chain. However, when coexpressed with wild-type S protein this mutant polypeptide can be incorporated into particles and secreted, indicating that the chain is still competent for some of the distal steps in particle assembly. The correct transmembrane disposition of the N terminus of the molecule is important for particle formation: addition of a heterologous (globin) domain to this region impairs secretion, but the defect can be corrected by provision of an N-terminal signal sequence that restores the proper topology of this region. The resulting chimeric chain is assembled into subviral particles that are secreted with normal efficiency.     

Hepatitis B viruses with precore region defects prevail in persistently infected hosts along with seroconversion to the antibody against e antigen.

The C gene of hepatitis B virus (HBV) codes for a nucleocapsid protein made of 183 amino acid residues and is preceded in phase by the precore (pre-C) region, encoding 29 residues. The pre-C-region product is required for the synthesis and secretion of hepatitis B e antigen (HBeAg), which is made of the C-terminal 10 amino acid residues of the pre-C-region product and the N-terminal 149 residues of the C-gene product. HBV mutants with pre-C-region defects prevailed in the circulation of three asymptomatic carriers as they seroconverted from HBeAg to the corresponding antibody (anti-HBe), and these mutants finally replaced nondefective HBV. HBV DNA clones were propagated from sera of an additional 15 carriers with anti-HBe and sequenced for the pre-C region. Essentially all HBV DNA clones (56 of 57 [98%]) revealed mutations that prohibited the translation of a functional pre-C-region product. A point mutation from G to A at nucleotide 83, converting Trp-28 (TGG) to a stop codon (TAG), was by far the commonest and was observed in HBV DNA clones from 16 (89%) of 18 carriers seropositive for anti-HBe. In addition, there were point mutations involving ATG codon to abort the translation initiation of the pre-C region, as well as deletion and insertion to induce frameshifts. Such mutations leading to pre-C-region defects were rarely observed in persistently infected individuals positive for HBeAg or in patients with type B acute hepatitis after they had seroconverted to anti-HBe. These results would indicate a selection of pre-C-defective mutants in persistently infected hosts, along with seroconversion to anti-HBe, by immune elimination of hepatocytes harboring nondefective HBV with the expression of HBeAg.     

Functions of the internal pre-S domain of the large surface protein in hepatitis B virus particle morphogenesis.

The large hepatitis B virus (HBV) surface protein (L) forms two isomers which display their N-terminal pre-S domain at the internal and external side of the viral envelope, respectively. The external pre-S domain has been implicated in binding to a virus receptor. To investigate functions of the internal pre-S domain, a secretion signal sequence was fused to the N terminus of L (sigL), causing exclusive expression of external pre-S domains. A fusion construct with a nonfunctional signal (s25L), which corresponds in its primary sequence to sigL cleaved by signal peptidase, was used as a control. SigL was N glycosylated in transfected COS cells at both potential sites in pre-S in contrast to s25L or wild-type L, confirming the expected transmembrane topologies of sigL and s25L. Phenotypic characterization revealed the following points. (i) SigL lost the inhibitory effect of L or s25L on secretion of subviral hepatitis B surface antigen particles, suggesting that the retention signal mapped to the N terminus of L is recognized in the cytosol and not in the lumen of the endoplasmic reticulum. (ii) SigL was secreted into the culture medium even in the absence of the major HBV surface protein (S), while release of an L mutant lacking the retention signal was still dependent on S coexpression. (iii) s25L but not sigL could complement an L-negative HBV genome defective for virion secretion in cotransfections. This suggests that the cytosolic pre-S domain, like a matrix protein, is involved in the interaction of the viral envelope with preformed cytosolic nucleocapsids during virion assembly.