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.

In vitro reconstitution of functional hepadnavirus reverse transcriptase with cellular chaperone proteins.

Initiation of reverse transcription in hepadnaviruses (hepatitis B viruses) depends on the specific binding of an RNA signal (the packaging signal, epsilon) on the pregenomic RNA template by the viral reverse transcriptase (RT) and is primed by the RT itself (protein priming). We have previously shown that the RT-epsilon interaction and protein priming require the cellular heat shock protein, Hsp90. However, additional host factors required for these reactions remained to be identified. We now report that five cellular chaperone proteins, all known cofactors of Hsp90, were sufficient to reconstitute a duck hepatitis B virus RT active in epsilon binding and protein priming in vitro. Four proteins, Hsp90, Hsp70, Hsp40, and Hop, were required for reconstitution of RT activity, and the fifth protein, p23, further enhanced the kinetics of reconstitution. RT activation by the chaperone proteins is a dynamic process dependent on ATP hydrolysis and the Hsp90 ATPase activity. Thus, our results have defined a minimal complement of host factors necessary and sufficient for RT activation. Furthermore, this defined in vitro reconstitution system has now paved the way for future biochemical and structural studies to elucidate the mechanisms of RT activation and chaperone functions.

In vitro inhibition of hepadnavirus polymerases by the triphosphates of BMS-200475 and lobucavir.

The guanosine analogs BMS-200475 and lobucavir have previously been shown to effectively suppress propagation of the human hepatitis B virus (HBV) and woodchuck hepatitis virus (WHV) in 2.2.15 liver cells and in the woodchuck animal model system, respectively. This repression was presumed to occur via inhibition of the viral polymerase (Pol) by the triphosphate (TP) forms of BMS-200475 and lobucavir which are both produced in mammalian cells. To determine the exact mode of action, BMS-200475-TP and lobucavir-TP, along with several other guanosine analog-TPs and lamivudine-TP were tested against the HBV, WHV, and duck hepatitis B virus (DHBV) polymerases in vitro. Estimates of the 50% inhibitory concentrations revealed that BMS-200475-TP and lobucavir-TP inhibited HBV, WHV, and DHBV Pol comparably and were superior to the other nucleoside-TPs tested. More importantly, both analogs blocked the three distinct phases of hepadnaviral replication: priming, reverse transcription, and DNA-dependent DNA synthesis. These data suggest that the modest potency of lobucavir in 2.2.15 cells may be the result of poor phosphorylation in vivo. Kinetic studies revealed that BMS-200475-TP and lobucavir-TP competitively inhibit HBV Pol and WHV Pol with respect to the natural dGTP substrate and that both drugs appear to bind to Pol with very high affinities. Endogenous sequencing reactions conducted in replicative HBV nucleocapsids suggested that BMS-200475-TP and lobucavir-TP are nonobligate chain terminators that stall Pol at sites that are distinct yet characteristically two to three residues downstream from dG incorporation sites.

Amino acids essential for RNase H activity of hepadnaviruses are also required for efficient elongation of minus-strand viral DNA.

The hepadnavirus P gene contains amino acid sequences which share homology with all known RNases H. In this study, we made four mutants in which single amino acids of the duck hepatitis B virus (DHBV) RNase H region were altered. In two of them, amino acids at locations comprising the putative catalytic site were changed, while the remaining mutants had alterations at amino acids conserved among hepadnaviruses. Transfection of these mutant genomes into permissive cells resulted in synthesis of several discrete viral nucleic acid species, ranging in apparent sizes from approximately 500 to 3,000 bp, numbered I, II, III, IV, and V. While the locations of the species were similar in all mutants, the proportions of the species varied among the mutants. Analysis of the nucleic acid species revealed that they were hybrid molecules of RNA and minus-strand DNA, indicating that the RNase H activity was missing or greatly reduced in these mutants. Primer extension experiments showed that the mutant viruses initiated minus-strand viral DNA synthesis normally. The 3' termini of minus-strand DNA in species II, III, and IV were mapped just downstream of nucleotides 1659, 1220, and 721, respectively. Species V contained essentially full-length minus-strand viral DNA. A parallel amino acid change in the putative catalytic site of the HBV RNase H domain resulted in accumulation of low-molecular-weight hybrid molecules consisting of RNA and minus-strand DNA and similar in size and pattern to those seen with DHBV. These studies demonstrate experimentally the involvement of the C-terminal portion of the P gene in RNase H activity in both DHBV and human hepatitis B virus and indicate that the amino acids essential for RNase H activity of hepadnavirus P protein are also important for the efficient elongation of minus-strand viral DNA.

Detection of an RNase H activity associated with hepadnaviruses.

Replication of the hepadnavirus DNA genome is accomplished via reverse transcription of an intermediate, pregenomic RNA molecule. This process is likely to be carried out by a virally encoded, multifunctional polymerase which possesses DNA- and RNA-dependent DNA polymerase and RNase H activities. However, the nature of the product(s) of the polymerase gene predicted to mediate these functions is unclear. Biochemical studies of the polymerase protein(s) have been limited by its apparent low abundance in virus particles and, until recently, the inability to express active polymerase protein(s) heterologously. We have used activity gel assays to detect DNA- and RNA-dependent DNA polymerase activities associated with highly purified duck hepatitis B virus (DHBV) core particles (S. M. Oberhaus and J. E. Newbold, J. Virol. 67:6558-6566, 1993). Now we report that the same approach identifies a 35-kDa RNase H activity in association with highly purified DHBV core particles and crude preparations of virions from DHBV-infected ducks and woodchuck hepatitis virus-infected woodchucks. This is the first report of the detection of an hepadnavirus-associated RNase H activity. Its apparent size is smaller than any of the DNA polymerase activities that we detected previously and significantly smaller than the full-length protein predicted from the polymerase open reading frame (p85 for DHBV). These data suggest that the viral polymerase and RNase H activities are separable and that these enzymes may coordinate their activities in vivo by forming a complex.

Analysis of the earliest steps of hepadnavirus replication: genome repair after infectious entry into hepatocytes does not depend on viral polymerase activity.

Hepadnaviruses contain a relaxed circular DNA genome (RC-DNA) with discontinuities in both strands. Upon infectious entry into a host cell, this genome is converted into a covalently closed superhelical form (CCC-DNA), which later serves as the template for transcription. Here we examined whether the viral polymerase activity is required for this repair reaction. Primary hepatocytes prepared from embryonated duck eggs were infected with the duck hepatitis B virus. Conversion of the RC-DNA into the CCC-DNA was then analyzed by a newly developed polymerase chain reaction technique. This method allows the efficient discrimination between the two DNA forms and is sensitive enough to monitor repair of the infecting viral DNA in the absence of replication and amplification. Thus, we were able to monitor this process in the presence of a potent inhibitor of the viral polymerase, the nucleoside analog 2',3'-dideoxyguanosine. The data show that inhibition of the viral polymerase activity has no influence on genome repair, suggesting that this enzymatic function is not required for conversion of the RC-DNA into the CCC-DNA. Consequently, antiviral drugs blocking the polymerase activity cannot prevent the infectious entry of the virus into a host cell.

How do viral reverse transcriptases recognize their RNA genome?

Reverse transcription is not solely a retroviral mechanism. Hepadnaviruses and caulimoviruses have RNA intermediates that are reverse transcribed into DNA. Moreover non-viral retroelements, retrotransposons, use reverse transcription in their transposition. All these retroelements encode reverse transcriptase but each group developed their own expression modes capable of assuring a specific and efficient replication of their genomes.

Mechanism of translation of the hepadnaviral polymerase (P) gene.

Unlike many other reverse transcriptase genes, the polymerase (P) gene of the hepatitis B viruses is expressed by translational initiation from its own AUG codon rather than by ribosomal frameshifting during translation of the overlapping core gene (C). To explore the mechanism of its translation, we have fused the P gene of duck hepatitis B virus to the bacterial lacZ gene at a point 3' to the C-P overlap; this allows detection of the products of P translation with antisera to the lacZ-encoded protein. The C and P/Z coding regions were cloned downstream of a heterologous promoter and expressed in COS-7 cells. A single, bicistronic mRNA containing both C and P sequences is detected in these cells, and translational initiation occurs efficiently at the internally situated P AUG. Mutations affecting C translation have only minimal effects on P expression, in contrast to what would be expected from a modified scanning model for translation. We conclude that P translation depends on a mechanism other than scanning to allow internal entry of ribosomes to the region of the P initiator.