Extensive mutagenesis of the conserved box E motif in duck hepatitis B virus P protein reveals multiple functions in replication and a common structure with the primer grip in HIV-1 reverse transcriptase.

Hepadnaviruses, including the pathogenic hepatitis B virus (HBV), replicate their small DNA genomes through protein-primed reverse transcription, mediated by the terminal protein (TP) domain in their P proteins and an RNA stem-loop, ε, on the pregenomic RNA (pgRNA). No direct structural data are available for P proteins, but their reverse transcriptase (RT) domains contain motifs that are conserved in all RTs (box A to box G), implying a similar architecture; however, experimental support for this notion is limited. Exploiting assays available for duck HBV (DHBV) but not the HBV P protein, we assessed the functional consequences of numerous mutations in box E, which forms the DNA primer grip in human immunodeficiency virus type 1 (HIV-1) RT. This substructure coordinates primer 3'-end positioning and RT subdomain movements during the polymerization cycle and is a prime target for nonnucleosidic RT inhibitors (NNRTIs) of HIV-1 RT. Box E was indeed critical for DHBV replication, with the mutations affecting the folding, ε RNA interactions, and polymerase activity of the P protein in a position- and amino acid side chain-dependent fashion similar to that of HIV-1 RT. Structural similarity to HIV-1 RT was underlined by molecular modeling and was confirmed by the replication activity of chimeric P proteins carrying box E, or even box C to box E, from HIV-1 RT. Hence, box E in the DHBV P protein and likely the HBV P protein forms a primer grip-like structure that may provide a new target for anti-HBV NNRTIs.

TP-RT domain interactions of duck hepatitis B virus reverse transcriptase in cis and in trans during protein-primed initiation of DNA synthesis in vitro.

The hepadnavirus reverse transcriptase (RT) has the unique ability to initiate viral DNA synthesis using RT itself as a protein primer. Protein priming requires complex interactions between the N-terminal TP (terminal protein) domain, where the primer (a specific Y residue) resides, and the central RT domain, which harbors the polymerase active site. While it normally utilizes the cis-linked TP to prime DNA synthesis (cis-priming), we found that the duck hepatitis B virus (DHBV) RT domain, in the context of the full-length RT protein or a mini-RT construct containing only truncated TP and RT domains, could additionally use a separate TP or RT domain in trans as a primer (trans-priming). trans interaction could also be demonstrated by the inhibitory effect (trans-inhibition) on cis-priming by TP and RT domain sequences provided in trans. Protein priming was further shown to induce RT conformational changes that resulted in TP-RT domain dissociation, altered priming site selection, and a gain of sensitivity to a pyrophosphate analog inhibitor. trans-priming, trans-inhibition, and trans-complementation, which requires separate TP and RT domains to reconstitute a functional RT protein, were employed to define the sequences in the TP and RT domains that could mediate physical or functional inter- and intradomain interactions. These results provide new insights into TP-RT domain interactions and conformational dynamics during protein priming and suggest novel means to inhibit protein priming by targeting these interactions and the associated conformational transitions.

RNA elements directing translation of the duck hepatitis B Virus polymerase via ribosomal shunting.

The duck hepatitis B virus (DHBV) reverse transcriptase (P) is translated from the downstream position on a bicistronic mRNA, called the pregenomic RNA, through a poorly characterized ribosomal shunt. Here, the positions of the discontinuous ribosomal transfer during shunting were mapped, and RNA elements important for shunting were identified as a prelude to dissecting the shunting mechanism. Mutations were introduced into the DHBV genome, genomic expression vectors were transfected into cells which support reverse transcription, and P translation efficiency was defined as the ratio of P/mRNA. Five observations were made. First, ribosomes departed from sequences that comprise the RNA stem-loop called ε that is key to viral replication, but the known elements of ε were not needed for shunting. Second, at least two landing sites for ribosomes were found on the mRNA. Third, all sequences upstream of ε, most sequences between the cap and the P AUG, and sequences within the P-coding region were dispensable for shunting. Fourth, elements on the mRNA involved in reverse transcription or predicted to be involved in shunting on the basis of mechanisms documented in other viruses, including short open reading frames near the departure site, were not essential for shunting. Finally, two RNA elements in the 5' portion of the mRNA were found to assist shunting. These observations are most consistent with shunting being directed by signals that act through an uncharacterized RNA secondary structure. Together, these data indicate that DHBV employs either a novel shunting mechanism or a major variation on one of the characterized mechanisms.

[An undamaged bulge in epsilon is essential for initiating priming of DHBV reverse transcriptase].

Previously, we have established an epsilon library and selected out a series of RNA aptamers with higher affinity to P protein based on the in vitro Systematic Evolution of Ligands by Exponential Enrichment (SELEX) in duck hepatitis B virus (DHBV) system. In order to study the structural elements within the epsilon that is essential for initiating priming of HBV reverse transcriptase (P protein), all selected aptamers were subjected to in vitro priming assay and RNA secondary structure probing. We found that all those aptamers supporting priming had an undamaged bulge, while those lacking of the bulge no more support priming. Our results suggest an undamaged bulge within Depsilon is indispensable for initiating priming of P protein.

Pre-P is a secreted glycoprotein encoded as an N-terminal extension of the duck hepatitis B virus polymerase gene.

The duck hepatitis B virus (DHBV) pregenomic RNA is a bicistronic mRNA encoding the core and polymerase proteins. Thirteen AUGs (C2 to C14) and 10 stop codons (S1 to S10) are located between the C1 AUG for the core protein and the P1 AUG that initiates polymerase translation. We previously found that the translation of the DHBV polymerase is initiated by ribosomal shunting. Here, we assessed the biosynthetic events after shunting. Translation of the polymerase open reading frame was found to initiate at the C13, C14, and P1 AUGs. Initiation at the C13 AUG occurred through ribosomal shunting because translation from this codon was cap dependent but was insensitive to blocking ribosomal scanning internally in the message. C13 and C14 are in frame with P1, and translation from these upstream start codons led to the production of larger isoforms of P. We named these isoforms "pre-P" by analogy to the pre-C and pre-S regions of the core and surface antigen open reading frames. Pre-P was produced in DHBV16 and AusDHBV-infected duck liver and was predicted to exist in 80% of avian hepadnavirus strains. Pre-P was not encapsidated into DHBV core particles, and the viable strain DHBV3 cannot make pre-P, so it is not essential for viral replication. Surprisingly, we found that pre-P is an N-linked glycoprotein that is secreted into the medium of cultured cells. These data indicate that DHBV produces an additional protein that has not been previously reported. Identifying the role of pre-P may improve our understanding of the biology of DHBV infection.

Functional and structural dynamics of hepadnavirus reverse transcriptase during protein-primed initiation of reverse transcription: effects of metal ions.

Reverse transcription in hepadnaviruses is primed by the viral reverse transcriptase (RT) (protein priming) and requires the interaction between the RT and a specific viral RNA template termed epsilon. Protein priming is resistant to a number of RT inhibitors that can block subsequent viral DNA elongation and likely requires a distinct "priming" conformation. Furthermore, protein priming may consist of two distinct stages, i.e., the attachment of the first deoxynucleotide to RT (initiation) and the subsequent addition of 2 or 3 deoxynucleotides (polymerization). In particular, a truncated duck hepatitis B virus RT (MiniRT2) is competent in initiation but defective in polymerization when tested in the presence of Mg(2+). Given the known effects of metal ions on the activities of various DNA and RNA polymerases, we tested if metal ions could affect hepadnavirus RT priming. We report here that Mn(2+), in comparison with Mg(2+), showed dramatic effects on the priming activity of MiniRT2 as well as the full-length RT. First and foremost, MiniRT2 exhibited full polymerization activity in the presence of Mn(2+), indicating that MiniRT2 contains all sequences essential for polymerization but is unable to transition from initiation to polymerization with Mg(2+). Second, the initiation activities of MiniRT2 and the full-length RT were much stronger with Mn(2+). Third, the nucleotide and template specificities during protein priming were decreased in the presence of Mn(2+). Fourth, polymerization was sensitive to inhibition by a pyrophosphate analog in the presence of Mn(2+) but not in the presence of Mg(2+). Finally, limited proteolysis provided direct evidence that the priming active MiniRT2 adopted distinct conformations depending on the presence of Mn(2+) versus that of Mg(2+) and that the transition from initiation to polymerization was accompanied by RT conformational change.

Chaperones activate hepadnavirus reverse transcriptase by transiently exposing a C-proximal region in the terminal protein domain that contributes to epsilon RNA binding.

All hepatitis B viruses replicate by protein-primed reverse transcription, employing a specialized reverse transcriptase, P protein, that carries a unique terminal protein (TP) domain. To initiate reverse transcription, P protein must bind to a stem-loop, epsilon, on the pregenomic RNA template. TP then provides a Y residue for covalent attachment of the first nucleotide of an epsilon-templated DNA oligonucleotide (priming reaction) that serves to initiate full-length minus-strand DNA synthesis. epsilon binding requires the chaperone-dependent conversion of inactive P protein into an activated, metastable form designated P*. However, how P* differs structurally from P protein is not known. Here we used an in vitro reconstitution system for active duck hepatitis B virus P combined with limited proteolysis, site-specific antibodies, and defined P mutants to structurally compare nonactivated versus chaperone-activated versus primed P protein. The data show that Hsp70 action, under conditions identical to those required for functional activation, transiently exposes the C proximal TP region which is, probably directly, involved in epsilon RNA binding. Notably, after priming and epsilon RNA removal, a very similar new conformation appears stable without further chaperone activity; hence, the activation of P protein is triggered by energy-consuming chaperone action but may be completed by template RNA binding.

Chaperone activation of the hepadnaviral reverse transcriptase for template RNA binding is established by the Hsp70 and stimulated by the Hsp90 system.

Hepadnaviruses are DNA viruses that replicate by protein-primed reverse transcription, employing a specialized reverse transcriptase (RT), P protein. DNA synthesis from the pregenomic RNA is initiated by binding of P to the epsilon signal. Using epsilon as template and a Tyr-residue for initiation, the RT synthesizes a DNA oligo (priming) as primer for full-length DNA. Priming strictly requires prior RT activation by chaperones. Active P-epsilon complexes have been reconstituted in vitro, but whether in addition to the heat-shock protein 70 (Hsp70) system the Hsp90 system is essential has been controversial. Here we quantitatively compared Hsp70 versus Hsp70 plus Hsp90 RT activation, and corroborated that the Hsp70 system alone is sufficient; however, Hsp90 as well the Hsp70 nucleotide exchange factor Bag-1 markedly stimulated activation by increasing the steady-state concentration of the activated metastable RT form P*, though by different mechanisms. Hsp90 inhibition in intact cells by geldanamycin analogs blocked hepadnavirus replication, however not completely and only at severely cytotoxic inhibitor concentrations. While compatible with a basal level of Hsp90 independent in vivo replication, unambiguous statements are precluded by the simultaneous massive upregulation of Hsp70 and Hsp90.

The duck hepatitis B virus reverse transcriptase functions as a full-length monomer.

Hepadnaviral reverse transcription occurs within cytoplasmic capsid particles and is catalyzed by a virally encoded reverse transcriptase, but the primary structure and multimeric state of the polymerase during reverse transcription are poorly understood. We measured these parameters for the duck hepatitis B virus polymerase employing active enzyme translated in vitro and derived from intracellular core particles and mature virions. In vitro-translated polymerase immunoprecipitated as a monomer, and polymerase molecules with complementary defects in the enzymatic active site and tyrosine 96, which primes DNA synthesis, could not complement or inhibit each other in priming assays. Western analysis using antibodies recognizing epitopes throughout the polymerase combined with nuclease digestion of permeabilized virion-derived capsid particles revealed that only full-length polymerase molecules were in virions and that they were all covalently attached to large DNA molecules. Because DNA synthesis is primed by the polymerase itself and only one copy of the viral DNA is in each capsid, the polymerase must function as an uncleaved monomer. Therefore, a single polymerase monomer is encapsidated, primes DNA synthesis, synthesizes both DNA strands, and participates in the three-strand transfers of DNA synthesis, with all steps after DNA priming performed while the polymerase is covalently coupled to the product DNA. Because the N-terminal domain of the polymerase is displaced from the active site on the same molecule by the viral DNA during reverse transcription, P must be structurally dynamic during DNA synthesis. Therefore, non-nucleoside compounds that interfere with this change may be novel antiviral agents.

Suppression of mRNA accumulation by the duck hepatitis B virus reverse transcriptase.

Hepadnaviruses establish chronic liver infections, but the mechanisms of persistence and immune evasion are poorly understood. We previously found that the duck hepatitis B virus (DHBV) and hepatitis B virus reverse transcriptases (P protein) unexpectedly accumulate in the cytoplasm where they could affect function(s) beyond viral DNA synthesis, such as gene expression. Therefore, we measured effects of DHBV P on gene expression from reporter constructs and the viral genome. P reduced reporter expression at the mRNA level to approximately 30-40%, independent of reporter tested. Accumulation of the viral pregenomic RNA from its native promoter was suppressed three-to four-fold by P, and accumulation of the capsid protein and intracellular core particles was similarly suppressed because the pregenomic RNA encodes the capsid protein. Therefore, suppression of the pregenomic RNA by DHBV P creates a negative feedback loop to limit viral antigen accumulation and replication, possibly contributing to maintenance of chronic infection.

Identification of an essential molecular contact point on the duck hepatitis B virus reverse transcriptase.

The hepadnaviral polymerase (P) functions in a complex with viral nucleic acids and cellular chaperones. To begin to identify contacts between P and its partners, we assessed the exposure of the epitopes of six monoclonal antibodies (MAbs) to the terminal protein domain of the duck hepatitis B virus P protein in a partially denaturing buffer (RIPA) and a physiological buffer (IPP150). All MAbs immunoprecipitated in vitro translated P well in RIPA, but three immunoprecipitated P poorly in IPP150. Therefore, the epitopes for these MAbs were obscured in the native conformation of P but were exposed when P was in RIPA. Epitopes for MAbs that immunoprecipitated P poorly in IPP150 were between amino acids (aa) 138 and 202. Mutation of a highly conserved motif within this region (T3; aa 176 to 183) improved the immunoprecipitation of P by these MAbs and simultaneously inhibited DNA priming by P. Peptides containing the T3 motif inhibited DNA priming in a dose-dependent manner, whereas eight irrelevant peptides did not. T3 function appears to be conserved among the hepadnaviruses because mutating T3 ablated DNA synthesis in both duck hepatitis B virus and hepatitis B virus. These results indicate that (i) the conserved T3 motif is a molecular contact point whose ligand can be competed by soluble T3 peptides, (ii) the occupancy of T3 obscures the epitopes for three MAbs, and (iii) proper occupancy of T3 by its ligand is essential for DNA priming. Therefore, small-molecule ligands that compete for binding to T3 with its natural ligand could form a novel class of antiviral drugs.

Sequence-specific inhibition of duck hepatitis B virus reverse transcription by peptide nucleic acids (PNA).

BACKGROUND/AIMS: Peptide nucleic acids (PNAs) appear as promising new antisense agents, that have not yet been examined as hepatitis B virus (HBV) inhibitors. Our aim was to study the ability of PNAs targeting the duck HBV (DHBV) encapsidation signal epsilon to inhibit reverse transcription (RT) and to compare their efficacy with phosphorothioate oligodeoxynucleotides (S-ODNs). METHODS: The effect of two partly overlapping PNAs targeting epsilon and of analogous S-ODNs was tested in cell-free transcription and translation system for DHBV RT expression. In addition their antiviral effect was investigated in primary duck hepatocytes (PDH). RESULTS: Both PNAs reproducibly inhibited DHBV RT in a dose-dependent manner with IC(50) of 10nM, whereas up to 600-fold higher concentration of S-ODNs was required for similar inhibition. The PNA targeting the bulge and upper stem of epsilon appeared as more efficient RT inhibitor than the PNA targeting only the bulge. Importantly, the inhibition was highly sequence-specific since double-mismatched PNA had no effect on the RT reaction. Moreover, in PDH the PNA coupled to Arg(7) cationic delivery peptide decreased DHBV replication. CONCLUSIONS: We provide the first evidence that PNAs targeting the bulge and upper stem of epsilon can efficiently and in a sequence-specific manner inhibit DHBV RT.

Requirement of heat shock protein 90 for human hepatitis B virus reverse transcriptase function.

The initiation of reverse transcription and nucleocapsid assembly in hepatitis B virus (HBV) depends on the specific recognition of an RNA signal (the packaging signal, epsilon) on the pregenomic RNA (pgRNA) by the viral reverse transcriptase (RT). RT-epsilon interaction in the duck hepatitis B virus (DHBV) was recently shown to require the molecular chaperone complex, the heat shock protein 90 (Hsp90). However, the requirement for RT-epsilon interaction in the human HBV has remained unknown due to the inability to obtain a purified RT protein active in specific epsilon binding. We now report that Hsp90 is also required for HBV RT-epsilon interaction. Inhibition of Hsp90 led to diminished HBV pgRNA packaging into nucleocapsids in cells, which depends on RT-epsilon interaction. Furthermore, using truncated HBV RT proteins purified from bacteria and five purified Hsp90 chaperone factors, we have developed an in vitro RT-epsilon binding assay. Our results demonstrate that Hsp90, in a dynamic process that was dependent on ATP hydrolysis, facilitated RT-epsilon interaction in HBV, as in DHBV. Specific epsilon binding required sequences from both the amino-terminal terminal protein and the carboxy-terminal RT domain. Only the cognate HBV epsilon, but not the DHBV epsilon, could bind the HBV RT proteins. Furthermore, the internal bulge, but not the apical loop, of epsilon was required for RT binding. The establishment of a defined in vitro reconstitution system has now paved the way for future biochemical and structural studies to elucidate the mechanisms of RT-epsilon interaction and chaperone activation.

Translation of duck hepatitis B virus reverse transcriptase by ribosomal shunting.

The duck hepatitis B virus (DHBV) polymerase (P) is translated by de novo initiation from a downstream open reading frame (ORF) that partially overlaps the core (C) ORF on the bicistronic pregenomic RNA (pgRNA). The DHBV P AUG is in a poor context for translational initiation and is preceded by 14 AUGs that could intercept scanning ribosomes, yet P translation is unanticipatedly rapid. Therefore, we assessed C and P translation in the context of the pgRNA. Mutating the upstream C ORF revealed that P translation was inversely related to C translation, primarily due to occlusion of P translation by ribosomes translating C. Translation of the pgRNA was found to be cap dependent, because inserting a stem-loop (BamHI-SL) that blocked >90% of scanning ribosomes at the 5' end of the pgRNA greatly inhibited C and P synthesis. Neither mutating AUGs between the C and P start sites in contexts similar to that of the P AUG nor blocking ribosomal scanning by inserting the BamHI-SL between the C and P start codons greatly altered P translation, indicating that most ribosomes that translate P do not scan through these sequences. Finally, optimizing the P AUG context did not increase P translation. Therefore, the majority of the ribosomes that translate P are shunted from a donor region near the 5' end of the pgRNA to an acceptor site at or near the P AUG, and the shunt acceptor sequences may augment initiation at the P AUG.

Efficient Hsp90-independent in vitro activation by Hsc70 and Hsp40 of duck hepatitis B virus reverse transcriptase, an assumed Hsp90 client protein.

Hsp90 is a specialized chaperone that controls the activity of many key regulator proteins such as steroid hormone receptors (SHRs). Hormone binding, and therefore SHR activation, requires Hsp90, which is loaded onto the receptors by a series of events involving Hsp70, Hsp40, Hop, and p23. The reverse transcriptase (RT) of hepatitis B viruses, small DNA-containing viruses that replicate via an RNA intermediate, has been reported to depend similarly on Hsp90 for enzymatic activity. Using an in vitro reconstitution system consisting of recombinant duck hepatitis B virus RT, purified chaperones, and the authentic RNA template Depsilon, we demonstrate here that this RT can be activated efficiently by just Hsp40 and Hsc70 plus energy, without the need for Hsp90 or other cofactors. The reaction appears to proceed selectively with the Hdj1 variant of Hsp40 but not Hdj2 or its yeast homolog Ydj1. The primary reaction product is a metastable, RNA binding-competent intermediate that decays quickly in the absence of its cognate RNA but, in its presence, accumulates in an initiation-competent form over several hours. Because deletion of the RNase H domain rendered the protein partly chaperone-independent, the chaperones may be needed indirectly to relieve occlusion of the RNA binding site by this domain. Our results do not exclude that other factors contribute to RT activation in vivo, but they challenge a fundamental SHR-like dependence on Hsp90. Thus Hsc70, mostly known for its role in general protein folding, is able to effect activation of a highly specialized target protein.

Heat shock protein 90-independent activation of truncated hepadnavirus reverse transcriptase.

The reverse transcriptase (RT) encoded by hepadnaviruses (hepatitis B viruses) is a multifunctional protein critical for several aspects of viral assembly and replication. Reverse transcription is triggered by the specific interaction between the RT and an RNA signal located on the viral pregenomic RNA, termed epsilon, and is initiated through a novel protein priming mechanism whereby the RT itself serves as a protein primer and epsilon serves as the obligatory template. Using the RT from duck hepatitis B virus as a model, we previously demonstrated that RT-epsilon interaction and protein priming require the assistance of a host cell chaperone complex, heat shock protein 90 (Hsp90) and its co-chaperones, which associates with the RT and facilitates the folding of the RT into an active conformation. We now report that extensive truncation removing the entire C-terminal RNase H domain and part of the central RT domain could relieve this dependence on Hsp90 for RT folding such that the truncated RT variants could function in epsilon interaction and protein priming independently of Hsp90. The presence of certain nonionic or zwitterionic detergent was sufficient to establish and maintain the truncated RT proteins in an active, albeit labile, state. Furthermore, we were able to refold an RT truncation variant de novo after complete denaturation. In contrast, the full-length RT and also RT variants with less-extensive C-terminal truncations required Hsp90 for activation. Surprisingly, the presence of detergent plus some yet-to-be-identified cytoplasmic factor(s) led to a dramatic suppression of the RT activities. These results have important implications for RT folding and conformational maturation, Hsp90 chaperone function, and potential inhibition of RT functions by host cell factors.

Kinetics of synthesis and turnover of the duck hepatitis B virus reverse transcriptase.

Hepadnaviral reverse transcription occurs in subviral capsids in which the core protein surrounds the reverse transcriptase ("polymerase") and the pregenomic RNA. The pregenomic RNA is the template for reverse transcription and also the bicistronic mRNA for core and polymerase. The pregenomic RNA structure and the capsid stoichiometry imply that vastly more core would be translated than polymerase. Previously, we found that duck hepatitis B virus polymerase unexpectedly accumulates in the cytoplasm (Yao, E., Gong, Y., Chen, N., and Tavis, J. E. (2000) J. Virol. 74, 8648-8657). The production mechanism and function of the excess polymerase are unknown. Here, we determined the kinetics of expression and degradation of polymerase and core in cells producing virus. Polymerase was translated 10% as rapidly as core, the half-life of nonencapsidated polymerase was very short, core had a very long half-life, and very few polymerase molecules were encapsidated. The presence of excess polymerase indicates that the translation rate of the polymerase is not limiting for encapsidation. Therefore, encapsidation must be regulated by other events, most likely binding of the polymerase to the pregenomic RNA. These data support the hypothesis that polymerase may have functions beyond copying the viral genome by demonstrating that the polymerase is a cytoplasmic protein that is only rarely encapsidated.

Expression of the active human and duck hepatitis B virus polymerases in heterologous system of Pichia methanolica.

We expressed the Hepatitis B virus polymerase (HBV P protein) using a recently introduced yeast system, Pichia methanolica. HBV (1-680 amino acids) and Duck Hepatitis B virus (DHBV, 1-780 amino acids) polymerase were expressed and showed DNA dependent DNA polymerase (DDDP). The DHBV polymerase had RNA dependent DNA polymerase (RDDP) and RNase H activities. We present a new simplified way of obtaining active viral P protein using the yeast expression system. The viral P proteins proved to be stable and were not aggregated in the yeast system.