Precore Protein Research Articles

Hepatitis B virus p25 precore protein accumulates in Xenopus oocytes as an untranslocated phosphoprotein with an uncleaved signal peptide

We have analyzed the translocation of hepatitis B virus (HBV) precore (PC) proteins by using Xenopus oocytes injected with a synthetic PC mRNA. The PC region is a 29-amino-acid sequence that precedes the 21.5-kDa HBV capsid or core (C) protein (p21.5) and directs the secretion of core-related proteins. The first 19 PC amino acids provide a signal peptide that is cleaved with the resultant translocation of a 22.5-kDa species (p22.5), in which the last 10 PC residues precede the complete p21.5 C polypeptide. Most p22.5 is matured to 16-20 kDa species by carboxyl-terminal proteolytic cleavage prior to secretion. Here we show that some four unexpected PC proteins of 24 to 25 kDa are produced in addition to the secretion products described above. Protease protection and membrane cosedimentation experiments reveal that all PC proteins behave as expected for proteins that are translocated into the lumen of the endoplasmic reticulum except for the single largest PC protein (p25), which is not translocated. Like p21.5, p25 is a phosphoprotein that localizes to the oocyte cytosol and nucleus, and protease digestion studies suggest that the two molecules have similar two-domain structures. Radiosequencing of immobilized p25 demonstrates that it contains the intact PC signal peptide and represents the unprocessed translation product of the entire PC/C locus. Thus, while many HBV PC protein molecules are correctly targeted to intracellular membranes and translocated, a significant fraction of these molecules can evade translocation and processing.

Does the precore mutant of hbv cause fulminant hepatitis?

Background. A nosocomial outbreak of fulminant hepatitis B occurred in five patients in Haifa, Israel. Previous investigations identified the suspected source as a carrier of hepatitis B surface antigen who was positive for antibodies to hepatitis B e antigen and had chronic liver disease. We examined the strain of hepatitis B virus (HBV) that caused this epidemic, in order to identify specific mutations in the precore or core region. Methods. The presence of HBV was identified by polymerase-chain-reaction amplification of viral DNA in serum from the source patient, the five patients with fulminant hepatitis B, and five controls with acute, self-limited hepatitis B. The amplified viral HBV DNA samples were then cloned and sequenced. Results. Sequence analysis of viral DNA established that the same HBV mutant with two mutations in the precore region was present in the source patient and the five patients with fulminant hepatic failure. This HBV mutant had significant sequence divergence from other known HBV subtypes in the X, precore, and core regions. Cloned HBV DNA derived from a hospitalized patient who had subclinical hepatitis B at the same time as the outbreak and from four other control subjects with acute, self-limited hepatitis B all contained the wild-type sequence in the precore region. Conclusions. In the outbreak we studied, a mutant hepatitis B viral strain was transmitted from a common source to five patients who subsequently died of fulminant hepatitis B infection. Naturally occurring viral mutations in the HBV genome may predispose the infected host to more severe liver injury. Background. The presence of the hepatitis B e antigen (HBeAg) in serum is known to be a marker of a high degree of viral infectivity. However, fulminant hepatitis may occur in persons who are negative for HBeAg. A single point mutation has been reported to produce a stop codon in the precore region of hepatitis B virus DNA and prevent the formation of the precore protein required to make HBeAg. To determine whether a precore-mutant virus is causally related to severe liver injury, we analyzed the entire precore region in viral strains isolated from patients with fatal cases and uncomplicated cases of hepatitis B. Methods. Serum was obtained from 9 patients with fatal hepatitis B (5 with fulminant and 4 with severe exacerbations of chronic hepatitis) and 10 patients with acute, self-limited hepatitis B. Serum samples from a sex partner implicated as the source of the virus in one case of fulminant hepatitis were also studied. The 87 nucleotides in the precore region of the hepatitis B virus were amplified by the polymerase chain reaction and then directly sequenced. Results. Of the nine patients with fatal hepatitis, seven had retrievable hepatitis B DNA. In all seven there was a point mutation from G to A at nucleotide 1896 of the precore region, converting tryptophan (TGG) to a stop codon (TAG). In contrast, this mutation was not found in the 10 patients with acute, self-limited hepatitis B. The hepatitis B DNA from the implicated source contained a sequence with the stop-codon mutation that was identical to the sequence in her partner, who had fulminant hepatitis. Conclusions. The presence of a mutant viral strain is associated with and may be involved in the pathogenesis of fulminant hepatitis B and severe exacerbations of chronic hepatitis B.

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.

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.

Mutations in the Precore Region of Hepatitis B Virus DNA in Patients with Fulminant and Severe Hepatitis

The presence of the hepatitis B e antigen (HBeAg) in serum is known to be a marker of a high degree of viral infectivity. However, fulminant hepatitis may occur in persons who are negative for HBeAg. A single point mutation has been reported to produce a stop codon in the precore region of hepatitis B virus DNA and prevent the formation of the precore protein required to make HBeAg. To determine whether a precore-mutant virus is causally related to severe liver injury, we analyzed the entire precore region in viral strains isolated from patients with fatal cases and uncomplicated cases of hepatitis B. Serum was obtained from 9 patients with fatal hepatitis B (5 with fulminant and 4 with severe exacerbations of chronic hepatitis) and 10 patients with acute, self-limited hepatitis B. Serum samples from a sex partner implicated as the source of the virus in one case of fulminant hepatitis were also studied. The 87 nucleotides in the precore region of the hepatitis B virus were amplified by the polymerase chain reaction and then directly sequenced. Of the nine patients with fatal hepatitis, seven had retrievable hepatitis B DNA: In all seven there was a point mutation from G to A at nucleotide 1896 of the precore region, converting tryptophan (TGG) to a stop codon (TAG). In contrast, this mutation was not found in the 10 patients with acute, self-limited hepatitis B. The hepatitis B DNA from the implicated source contained a sequence with the stop-codon mutation that was identical to the sequence in her partner, who had fulminant hepatitis. The presence of a mutant viral strain is associated with and may be involved in the pathogenesis of fulminant hepatitis B and severe exacerbations of chronic hepatitis B.

Mechanism, kinetics, and role of duck hepatitis B virus e-antigen expression in vivo

No duck hepatitis B virus (DHBV) pre-C transcript has been identified so far, and neither the interrelationship of e-antigen (DHBeAg) with the expression of other viral antigens or virus replication nor its function is known. In this study we identified in infected livers a minor transcript from which the precursor protein of DHBeAg could be synthesized. Mutation of the first AUG on this transcript abolished expression of DHBeAg. DHBV genomes containing this mutation were infectious in Pekin ducks, the kinetics of pre-S envelope protein expression and virus secretion were not significantly different from wild-type, and the mutant genomes did not revert to wild-type to a detectable level after several passages. In contrast to pre-S protein, the level of DHBeAg in the serum was independent of the level of viremia, accumulated gradually to a high and constant level after a lag phase, and was also easily detectable in a mixed infection containing less than 0.1 % of wild-type in a pre-C mutant virus containing inoculum. These data indicate that precore protein is synthesized from a minor pre-C mRNA with translation initiation at the pre-C AUG codon, and leads to high levels of DHBeAg rather late in infection. High levels of DHBeAg can even be produced efficiently by a very small subpopulation of wild-type virus in a mixed infection with predominantly pre-C mutant virus. Lack of DHBeAg appears to have no effect on DHBV viability and kinetics of virus secretion into the bloodstream when ducklings are infected with the pre-C AUG mutant virus a few days after birth.

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.

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.

Intrahepatic expression of HBcAg in chronic HBV hepatitis: Lessons from molecular biology

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.

Preferred translation of human hepatitis B virus polymerase from core protein- but not from precore protein-specific transcript

In the human hepatitis B virus (HBV) genome, the 5' end of the polymerase coding sequence overlaps with the 3' end of the core protein coding sequence. Recent results obtained from genetic studies have suggested that translation of HBV polymerase initiates from the first ATG codon of the polymerase reading frame and is not a result of frameshift translation from the core protein reading frame, as in the case of retroviruses. By using in vitro-synthesized SP6 RNA transcripts, we now demonstrate that HBV core protein-specific mRNA can direct the synthesis of polymerase from the internal polymerase ATG codon in rabbit reticulocyte lysates and Xenopus oocytes. A related message with an additional 60 nucleotides at the 5' end (pre-core protein mRNA) was not as efficient as the core protein mRNA for translation of polymerase. Furthermore, translation of polymerase from the core protein mRNA was not inhibited by the cap analog m7GpppG. This result, together with the results described above, indicates that translation of HBV polymerase occurs in a novel, cap-independent manner.

Comparative studies of hepatitis B virus precore and core particles

Hepatitis B virus core antigen gene expresses two coca rboxy-terminal proteins, termed precore and core proteins. Both precore and core proteins can form nucleocapsid-like particles. In order to understand the mechanism that leads to the formation of the nucleocapsid, we have expressed precore and core protein sequences in COS cells, a monkey kidney cell line, and compared the properties of these two particles. Our results show that core protein can form particles with various densities and they are present mostly in the cytosol. Precore protein, on the other hand, forms particles with one predominant density, and a majority of these particles are present in the lumen of the endoplasmic reticulum (ER). Furthermore, our results show that, when coexpressed in the same cells, core protein and the ER-associated surface antigens (envelope protein) show colocalization, indicating interaction between these two viral structural proteins.

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.

Expression mechanism of the hepatitis B virus (HBV) C gene and biosynthesis of HBe antigen

The C gene of the hepatitis B virus, which contains two in-phase initiation codons delimiting the pre-C sequence and the C region, directs the synthesis of the major protein of the capsid (HBcAg) and of a precore protein which upon processing results in the secretion of the HBeAg. We used an adenovirus-based vector to study in the human 293 cell line the C gene products, the intermediates of the precore protein processing and the kind of protease involved in this processing. The synthesis of the 21-kDa HBcAg polypeptide was dependent on the deletion of the pre-C sequence suggesting that a pre-C mRNA is not used for the synthesis of the major capsid protein. With the construct containing the complete C gene, two proteins of 25 and 22 kDa were detected intracellularly, corresponding to the unprocessed and partially processed precore protein, respectively. In addition, a 15-kDa protein (HBeAg) was secreted in the culture medium. Using pepstatin, an inhibitor specific for aspartyl proteinases, reduction of HBeAg secretion and accumulation of the 22-kDa processing intermediate were observed, suggesting the involvement of an aspartyl proteinase in the conversion of the 22-kDa protein into HBeAg.

A signal peptide encoded within the precore region of hepatitis B virus directs the secretion of a heterogeneous population of e antigens in Xenopus oocytes.

Using synthetic hepatitis B virus (HBV) mRNAs, we have shown that expression of HBV core-antigen gene sequences in Xenopus oocytes leads to the stable accumulation of 21-kDa cytoplasmic core protein (P21). In contrast, expression of precore plus core sequences leads mainly to the secretion of a heterogeneous population of proteins ranging in size from 15 to 22 kDa that collectively display viral e antigen (HBeAg) activity. We demonstrate that the precore region contains a cleavable 19 amino acid signal peptide that targets the precore proteins to the secretory pathway. The initial product of translocation (P22) is further processed during migration through the secretory pathway, apparently by a series of cleavage events at the arginine-rich carboxyl terminus, to yield multiple proteins of 15-18 kDa (P15-P18) that are secreted along with some P22. Our results indicate that serum HBeAg is generated by a signal peptide-mediated secretion event dependent on precore sequences.

Targeting of the hepatitis B virus precore protein to the endoplasmic reticulum membrane: after signal peptide cleavage translocation can be aborted and the product released into the cytoplasm.

The major hepatitis B virus (HBV) core protein is a viral structural protein involved in nucleic acid binding. Its coding sequence contains an extension of 29 codons (the "precore" region) at the amino terminus of the protein which is present in a fraction of the viral transcripts. This region is evolutionarily conserved among mammalian and avian HBVs, suggesting it has functional importance, although at least for duck HBV it has been shown to be nonessential for replication of infectious virions. Using in vitro assays for protein translocation across the endoplasmic reticulum membrane, we found that the precore region of the HBV genome encodes a signal sequence. This signal sequence was recognized by signal recognition particle, which targeted the nascent precore protein to the endoplasmic reticulum membrane with efficiencies comparable to those of other mammalian secretory proteins. A 19-amino acid signal peptide was removed by signal peptidase on the lumenal side of the microsomal membrane, generating a protein similar to the HBV major core protein, but containing 10 additional amino acids from the precore region at its amino terminus. Surprisingly, we found that 70-80% of this signal peptidase-cleaved product was localized on the cytoplasmic side of the microsomal vesicles and was not associated with the membranes. We conclude that translocation was aborted by an unknown mechanism, then the protein disengaged from the translocation machinery and was released back into the cytoplasm. Thus, a cytoplasmically disposed protein was created whose amino terminus resulted from signal peptidase cleavage. The remaining 20-30% appeared to be completely translocated into the lumen of the microsomes. A deletion mutant lacking the carboxy-terminal nucleic acid binding domain of the precore protein was similarly partitioned between the lumen of the microsomes and the cytoplasmic compartment, indicating that this highly charged domain is not responsible for the aborted translocation. We discuss the implications of our findings for the protein translocation process and suggest a possible role in the virus life cycle.

Expression of the hepatitis B virus core gene in vitro and in vivo.

The core gene of hepatitis B virus contains two in-phase AUG codons which may both be used in the viral life cycle. By in vitro translation of transcripts produced in vitro, we investigated the corresponding core gene products and their counterparts in vivo. Depending on the location of the 5' end of the transcripts, two major core gene-derived proteins were obtained. In transcripts with both in-phase AUGs, only the first one was efficiently used and resulted in synthesis of a 25-kilodalton protein (precore). This protein contains a leader sequence and could be cotranslationally processed to a protein of 22.3 kilodaltons. Translation of transcripts lacking the first AUG of the core gene produced a core protein of 21.5 kilodaltons which comigrated with the core antigen expressed in infected livers. These data suggest that the major nucleocapsid protein expressed in vivo is initiated at the second ATG of the C gene and that a precore protein is probably synthesized as a precursor protein which is cotranslationally processed. Proteins consistent in size with processed and unprocessed precore proteins detected in woodchuck hepatitis virus-infected livers support this conclusion.