cis-Acting sequences in addition to donor and acceptor sites are required for template switching during synthesis of plus-strand DNA for duck hepatitis B virus

Pregenomic RNA Launch Hepatitis B Virus Replication System Facilitates the Mechanistic Study of Antiviral Agents and Drug-Resistant Variants on Covalently Closed Circular DNA Synthesis

Hepatitis B virus (HBV) replicates its genomic DNA by reverse transcription of an RNA intermediate, termed pregenomic RNA (pgRNA), within nucleocapsid. It had been shown that transfection of in vitro-transcribed pgRNA initiated viral replication in human hepatoma cells. We demonstrated here that viral capsids, single-stranded DNA, relaxed circular DNA (rcDNA) and covalently closed circular DNA (cccDNA) became detectable sequentially at 3, 6, 12, and 24 h post-pgRNA transfection into Huh7.5 cells. The levels of viral DNA replication intermediates and cccDNA peaked at 24 and 48 h post-pgRNA transfection, respectively. HBV surface antigen (HBsAg) became detectable in culture medium at day 4 posttransfection. Interestingly, the early robust viral DNA replication and cccDNA synthesis did not depend on the expression of HBV X protein (HBx), whereas HBsAg production was strictly dependent on viral DNA replication and expression of HBx, consistent with the essential role of HBx in the transcriptional activation of cccDNA minichromosomes. While the robust and synchronized HBV replication within 48 h post-pgRNA transfection is particularly suitable for the precise mapping of the HBV replication steps, from capsid assembly to cccDNA formation, targeted by distinct antiviral agents, the treatment of cells starting at 48 h post-pgRNA transfection allows the assessment of antiviral agents on mature nucleocapsid uncoating, cccDNA synthesis, and transcription, as well as viral RNA stability. Moreover, the pgRNA launch system could be used to readily assess the impacts of drug-resistant variants on cccDNA formation and other replication steps in the viral life cycle. IMPORTANCE Hepadnaviral pgRNA not only serves as a template for reverse transcriptional replication of viral DNA but also expresses core protein and DNA polymerase to support viral genome replication and cccDNA synthesis. Not surprisingly, cytoplasmic expression of duck hepatitis B virus pgRNA initiated viral replication leading to infectious virion secretion. However, HBV replication and antiviral mechanism were studied primarily in human hepatoma cells transiently or stably transfected with plasmid-based HBV replicons. The presence of large amounts of transfected HBV DNA or transgenes in cellular chromosomes hampered the robust analyses of HBV replication and cccDNA function. As demonstrated here, the pgRNA launch HBV replication system permits the accurate mapping of antiviral target and investigation of cccDNA biosynthesis and transcription using secreted HBsAg as a convenient quantitative marker. The effect of drug-resistant variants on viral capsid assembly, genome replication, and cccDNA biosynthesis and function can also be assessed using this system.

Molecular biology of the hepatitis B virus for clinicians

Hepatitis B virus (HBV) infection is one of the major global health problems, especially in economically under-developed or developing countries. HBV infection can lead to a number of clinical outcomes including chronic infection, cirrhosis and liver cancer. It ranks among the top 10 causes of death, being responsible for around 1 million deaths every year. Despite the availability of a highly efficient vaccine and potent antiviral agents, HBV infection still remains a significant clinical problem, particularly in those high endemicity areas where vaccination of large populations has not been possible due to economic reasons. Although HBV is among the smallest viruses in terms of virion and genome size, it has numerous unique features that make it completely distinct from other DNA viruses. It has a partially double stranded DNA with highly complex genome organization, life cycle and natural history. Remarkably distinct from other DNA viruses, it uses an RNA intermediate called pregenomic RNA (pgRNA) and reverse transcriptase for its genome replication. Genome replication is accomplished by a complex mechanism of primer shifting facilitated by direct repeat sequences encoded in the genome. Further, the genome has evolved in such a manner that every single nucleotide of the genome is used for either coding viral proteins or used as regulatory regions or both. Moreover, it utilizes internal in-frame translation initiation codons, as well as different reading frames from the same RNA to generate different proteins with diverse functions. HBV also shows considerable genetic variability which has been related with clinical outcomes, replication potential, therapeutic response etc. This review aims at reviewing fundamental events of the viral life cycle including viral replication, transcription and translation, from the molecular standpoint, as well as, highlights the clinical relevance of genetic variability of HBV.

cis-Acting sequences that contribute to synthesis of minus-strand DNA are not conserved between hepadnaviruses

Hepadnaviruses are DNA viruses that are found in several mammalian and avian species. These viruses replicate their genome through reverse transcription of an RNA intermediate termed pregenomic RNA (pgRNA). pgRNA is reverse transcribed by the viral polymerase into a minus-strand DNA, followed by synthesis of the plus-strand DNA. There are multiple cis-acting sequences that contribute to the synthesis of minus-strand DNA for human hepatitis B virus (HBV). Less is known about the cis-acting sequences of avian hepadnaviruses that contribute to synthesis of minus-strand DNA. To identify cis-acting sequences of duck hepatitis B virus (DHBV) and heron hepatitis B virus (HHBV), we analyzed variants containing 200-nucleotide (nt) deletions. Most variants of DHBV synthesized minus-strand DNA to 50 to 100% of the wild-type (WT) level, while two variants synthesized less than 50%. For HHBV, most variants synthesized minus-strand DNA to less than 50% the WT level. These results differ from those for HBV, where most of the genome can be removed with little consequence. HBV contains a sequence, φ, that contributes to the synthesis of minus-strand DNA. It has been proposed that DHBV has an analogous sequence. We determined that the proposed φ sequence of DHBV does not contribute to the synthesis of minus-strand DNA. Finally, we found that the DR2 sequence present in all hepadnaviruses is important for synthesis of minus-strand DNA in both DHBV and HHBV but not in HBV. These differences in cis-acting sequences suggest that the individual hepadnaviruses have evolved differences in their mechanisms for synthesizing minus-strand DNA, more so than for other steps in replication.

Characterization of the intracellular deproteinized relaxed circular DNA of hepatitis B virus: an intermediate of covalently closed circular DNA formation

Covalently closed circular DNA (cccDNA) of hepatitis B virus (HBV) is formed by conversion of capsid-associated relaxed circular DNA (rcDNA) via unknown mechanisms and exists in the nucleus of the infected hepatocyte as a minichromosome that serves as the transcription template for viral RNAs. To study the molecular pathway of cccDNA formation and its regulation by viral and cellular factors, we have established a cell line that supports the replication of an envelope protein-deficient HBV genome in a tetracycline-inducible manner. Following induction of HBV replication, the cells accumulate higher levels of cccDNA as well as larger amounts of deproteinized rcDNA (DP-rcDNA) than cells that replicate wild-type HBV genomes. These results indicate that HBV envelope proteins negatively regulate cccDNA formation, and conversion of DP-rcDNA into cccDNA is a rate-limiting step of cccDNA formation in HepG2 cells. Detailed analyses reveal the following: (i) DP-rcDNA exists in both cytoplasm and nucleus; (ii) while nuclear DP-rcDNA is sensitive to DNase I digestion, a small fraction of cytoplasmic DP-rcDNA is DNase I resistant; (iii) both DNase I-sensitive and -resistant cytoplasmic DP-rcDNAs cosediment with capsids and can be immunoprecipitated with HBV core antibody; and (iv) a primer extension assay maps the 5' end of the minus strand of DP-rcDNA at the authentic end of virion rcDNA. Hence, our results favor a hypothesis that the removal of viral polymerase protein covalently linked to the 5' end of the minus-strand DNA occurs inside the capsid in the cytoplasm and most possibly via a reaction that cleaves the phosphodiester bond between the tyrosine of the polymerase and the 5' phosphoryl group of minus-strand DNA.

Base pairing between cis-acting sequences contributes to template switching during plus-strand DNA synthesis in human hepatitis B virus

Hepadnaviruses utilize two template switches (primer translocation and circularization) during synthesis of plus-strand DNA to generate a relaxed-circular (RC) DNA genome. In duck hepatitis B virus (DHBV) three cis-acting sequences, 3E, M, and 5E, contribute to both template switches through base pairing, 3E with the 3' portion of M and 5E with the 5' portion of M. Human hepatitis B virus (HBV) also contains multiple cis-acting sequences that contribute to the accumulation of RC DNA, but the mechanisms through which these sequences contribute were previously unknown. Three of the HBV cis-acting sequences (h3E, hM, and h5E) occupy positions equivalent to those of the DHBV 3E, M, and 5E. We present evidence that h3E and hM contribute to the synthesis of RC DNA through base pairing during both primer translocation and circularization. Mutations that disrupt predicted base pairing inhibit both template switches while mutations that restore the predicted base pairing restore function. Therefore, the h3E-hM base pairing appears to be a conserved requirement for template switching during plus-strand DNA synthesis of HBV and DHBV. Also, we show that base pairing is not sufficient to explain the mechanism of h3E and hM, as mutating sequences adjacent to the base pairing regions inhibited both template switches. Finally, we did not identify predicted base pairing between h5E and the hM region, indicating a possible difference between HBV and DHBV. The significance of these similarities and differences between HBV and DHBV will be discussed.

5'-proximal hot spot for an inducible positive-to-negative-strand template switch by coronavirus RNA-dependent RNA polymerase

Coronaviruses have a positive-strand RNA genome and replicate through the use of a 3' nested set of subgenomic mRNAs each possessing a leader (65 to 90 nucleotides [nt] in length, depending on the viral species) identical to and derived from the genomic leader. One widely supported model for leader acquisition states that a template switch takes place during the generation of negative-strand antileader-containing templates used subsequently for subgenomic mRNA synthesis. In this process, the switch is largely driven by canonical heptameric donor sequences at intergenic sites on the genome that match an acceptor sequence at the 3' end of the genomic leader. With experimentally placed 22-nt-long donor sequences within a bovine coronavirus defective interfering (DI) RNA we have shown that matching sites occurring anywhere within a 65-nt-wide 5'-proximal genomic acceptor hot spot (nt 33 through 97) can be used for production of templates for subgenomic mRNA synthesis from the DI RNA. Here we report that with the same experimental approach, template switches can be induced in trans from an internal site in the DI RNA to the negative-strand antigenome of the helper virus. For these, a 3'-proximal 89-nt acceptor hot spot on the viral antigenome (nt 35 through 123), largely complementary to that described above, was found. Molecules resulting from these switches were not templates for subgenomic mRNA synthesis but, rather, ambisense chimeras potentially exceeding the viral genome in length. The results suggest the existence of a coronavirus 5'-proximal partially double-stranded template switch-facilitating structure of discrete width that contains both the viral genome and antigenome.

Hepatitis B virus replication

Hepadnaviruses, including human hepatitis B virus (HBV), replicate through reverse transcription of an RNA intermediate, the pregenomic RNA (pgRNA). Despite this kinship to retroviruses, there are fundamental differences beyond the fact that hepadnavirions contain DNA instead of RNA. Most peculiar is the initiation of reverse transcription: it occurs by protein-priming, is strictly committed to using an RNA hairpin on the pgRNA, ε, as template, and depends on cellular chaperones; moreover, proper replication can apparently occur only in the specialized environment of intact nucleocapsids. This complexity has hampered an in-depth mechanistic understanding. The recent successful reconstitution in the test tube of active replication initiation complexes from purified components, for duck HBV (DHBV), now allows for the analysis of the biochemistry of hepadnaviral replication at the molecular level. Here we review the current state of knowledge at all steps of the hepadnaviral genome replication cycle, with emphasis on new insights that turned up by the use of such cell-free systems. At this time, they can, unfortunately, not be complemented by three-dimensional structural information on the involved components. However, at least for the ε RNA element such information is emerging, raising expectations that combining biophysics with biochemistry and genetics will soon provide a powerful integrated approach for solving the many outstanding questions. The ultimate, though most challenging goal, will be to visualize the hepadnaviral reverse transcriptase in the act of synthesizing DNA, which will also have strong implications for drug development.

Regulation of hepadnavirus reverse transcription by dynamic nucleocapsid phosphorylation

Reverse transcription, an essential step in the life cycle of all retroelements, is a complex, multistep process whose regulation is not yet clearly understood. We have recently shown that reverse transcription in the pararetrovirus duck hepatitis B virus is associated with complete dephosphorylation of the viral core protein, which forms the nucleocapsid wherein reverse transcription takes place. Here we present a genetic study of the role of this dynamic nucleocapsid phosphorylation in regulating viral reverse transcription. Detailed analyses of the reverse transcription products synthesized within nucleocapsids composed of core phosphorylation site mutants revealed that alanine substitutions, mimicking the nonphosphorylated state, completely blocked reverse transcription at a very early stage. In contrast, aspartate substitutions, mimicking the phosphorylated state, allowed complete first-strand DNA synthesis but were severely defective in accumulating mature double-stranded DNA. The latter defect was due to a combination of mutant nucleocapsid instability during maturation and a block in mature second-strand DNA synthesis. Thus, the reversible phosphorylation of the nucleocapsids regulates the ordered progression of reverse transcription.

Complementarity between epsilon and phi sequences in pregenomic RNA influences hepatitis B virus replication efficiency

Hepatitis B virus (HBV) replication requires the viral polymerase to reverse transcribe the 3.5-kb pregenomic viral RNA within the nucleocapsid. It has been proposed that a sequence element designated phi (phi), which is located 32 nucleotides upstream of the 3' DR1 pregenomic RNA sequence and is complementary to epsilon, is required for efficient minus-strand synthesis because it may mediate the translocation of the viral polymerase plus the three nucleotide primer from epsilon to DR1. A mutation in phi has been identified which can be compensated for with a complementary mutation in epsilon. This observation supports the suggestion that epsilon and phi base pair during the process of polymerase translocation from epsilon to DR1. However, additional mutations in phi were not complemented by the corresponding mutations in epsilon indicating that the functional recognition of epsilon and epsilon/phi stem-loop structures by polymerase probably requires both sequence- and structure-specific information.

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.

Sequence identity of the direct repeats, DR1 and DR2, contributes to the discrimination between primer translocation and in situ priming during replication of the duck hepatitis B virus

There are two mutually exclusive pathways for plus-strand DNA synthesis in hepadnavirus reverse transcription. The predominant pathway gives rise to relaxed circular DNA, while the other pathway yields duplex linear DNA. At the completion of minus-strand DNA synthesis, the final RNase H cleavage generates the plus-strand primer at direct repeat 1 (DR1). A small fraction of viruses make duplex linear DNA after initiating plus-strand DNA synthesis from this site, a process called in situ priming. To make relaxed circular DNA, a template switch is necessary for the RNA primer generated at DR1 to initiate plus-strand DNA synthesis from the direct repeat 2 (DR2) located near the opposite end of the minus-strand DNA, a process called primer translocation. We are interested in understanding the mechanism that discriminates between these two processes. Previously, we showed that a small DNA hairpin forms at DR1 in the avihepadnaviruses and acts as an inhibitor of in situ priming. Here, using genetic approaches, we show that sequence identity between DR1 and DR2 is necessary, but not sufficient for primer translocation in the duck hepatitis B virus. The discrimination between in situ priming and primer translocation depends upon suppression of in situ priming, a process that is dependent upon both sequence identity between DR1 and DR2, and the presence of the hairpin at DR1. Finally, our analysis indicates the entire RNA primer can contribute to primer translocation and is translocated to DR2 before initiation of plus-strand DNA synthesis from that site.

Three novel cis-acting elements required for efficient plus-strand DNA synthesis of the hepatitis B virus genome

Synthesis of the relaxed-circular (RC) DNA genomes of hepadnaviruses by reverse transcriptase involves two template switches during plus-strand DNA synthesis. These template switches require repeat sequences (so-called donor and acceptor sites) between which a complementary strand of nucleic acid is transferred. To determine cis-acting elements apart from the donor and acceptor sites that are required for plus-strand RC DNA synthesis by hepatitis B virus (HBV), a series of mutants bearing a small deletion were made and analyzed for their impact on the viral genome synthesis. We found three novel cis-acting elements in the HBV genome: one element, located in the middle of the minus strand, is indispensable, whereas the other two elements, located near either end of the minus strand, contribute modestly to the plus-strand RC DNA synthesis. The data indicated that the first element facilitates plus-strand RNA primer translocation or subsequent elongation during plus-strand RC DNA synthesis, while the last two elements, although distantly located on the minus strand, act at multiple steps to promote plus-strand RC DNA synthesis. The necessity of multiple cis-acting elements on the minus-strand template reflects the complex nature of hepadnavirus reverse transcription.

The conformation of the 3' end of the minus-strand DNA makes multiple contributions to template switches during plus-strand DNA synthesis of duck hepatitis B virus

Two template switches are necessary during plus-strand DNA synthesis of the relaxed circular (RC) form of the hepadnavirus genome. The 3' end of the minus-strand DNA makes important contributions to both of these template switches. It acts as the donor site for the first template switch, called primer translocation, and subsequently acts as the acceptor site for the second template switch, termed circularization. A small DNA hairpin has been shown to form near the 3' end of the minus-strand DNA overlapping the direct repeat 1 in avihepadnaviruses. Previously we showed that this hairpin is involved in discriminating between two mutually exclusive pathways for the initiation of plus-strand DNA synthesis. In its absence, the pathway leading to production of duplex linear DNA is favored, whereas primer translocation is favored in its presence, apparently through the inhibition of in situ priming. Circularization involves transfer of the nascent plus strand from the 5' end of the minus-strand DNA to the 3' end, where further elongation can lead to production of RC DNA. Using both genetic and biochemical approaches, we now have found that the small DNA hairpin in the duck hepatitis B virus (DHBV) makes a positive contribution to circularization. The contribution appears to be through its impact on the conformation of the acceptor site. We also identified a unique DHBV variant that can synthesize RC DNA well in the absence of the hairpin. The behavior of this variant could serve as a model for understanding the mammalian hepadnaviruses, in which an analogous hairpin does not appear to exist.

Template switches during plus-strand DNA synthesis of duck hepatitis B virus are influenced by the base composition of the minus-strand terminal redundancy

Two template switches are necessary during plus-strand DNA synthesis of the relaxed circular (RC) form of the hepadnavirus genome. The 3' end of the minus-strand DNA makes important contributions to both of these template switches. It acts as the donor site for the first template switch, called primer translocation, and subsequently acts as the acceptor site for the second template switch, termed circularization. Circularization involves transfer of the nascent 3' end of the plus strand from the 5' end of the minus-strand DNA to the 3' end, where further elongation can lead to production of RC DNA. In duck hepatitis B virus (DHBV), a small terminal redundancy (5'r and 3'r) on the ends of the minus-strand DNA has been shown to be important, but not sufficient, for circularization. We investigated what contribution, if any, the base composition of the terminal redundancy made to the circularization process. Using a genetic approach, we found a strong positive correlation between the fraction of A and T residues within the terminal redundancy and the efficiency of the circularization process in those variants. Additionally, we found that the level of in situ priming increases, at the expense of primer translocation, as the fraction of A and T residues in the 3'r decreases. Thus, a terminal redundancy rich in A and T residues is important for both plus-strand template switches in DHBV.

cis-Acting sequences that contribute to the synthesis of relaxed-circular DNA of human hepatitis B virus

Synthesis of the relaxed-circular (RC) genome of hepadnaviruses is a multistep process that requires template switching during reverse transcription. Studies of duck hepatitis B virus indicated the presence of cis-acting sequences, distinct from the donor and acceptor sequences for the template switches, which contribute to the synthesis of RC DNA. However, knowledge about cis-acting requirements distinct from the donor and acceptor sites for human hepatitis B virus (HBV) was lacking. In this study, we searched for cis-acting sequences for synthesis of HBV RC DNA by analyzing a set of deletion variants that collectively represent most of the HBV genome. Sequences of epsilon, DR1, DR2, 5'r, and 3'r were not analyzed in the study. Results from Southern blotting showed that multiple cis-acting sequences were involved in the synthesis of HBV RC DNA. Analysis of several HBV/woodchuck hepatitis virus chimeras corroborated the findings from the analysis of deletion variants. This study represents a comprehensive and quantitative analysis of cis-acting sequences that contribute to the synthesis of HBV RC DNA.

Mismatch extension during strong stop strand transfer and minimal homology requirements for replicative template switching during Moloney murine leukemia virus replication

Reverse transcription requires two replicative template switches, called minus and plus strand strong stop transfer, and can include additional, recombinogenic switches. Donor and acceptor template homology facilitates both replicative and recombinogenic transfers, but homology-independent determinants may also contribute. Here, improved murine leukemia virus-based assays were established and the effects of varying extents of mismatches and complementarity between primer and acceptor template regions were assessed. Template switch accuracy was addressed by examining provirus structures, and efficiency was measured using a competitive titer assay. The results demonstrated that limited mismatch extension occurred readily during both minus and plus strand transfer. A strong bias for correct targeting to the U3/R junction and against use of alternate regions of homology was observed during minus strand transfer. Transfer to the U3/R junction was as accurate with five bases of complementarity as it was with an intact R, and as few as 3nt targeted transfer to a limited extent. In contrast, 12 base recombinogenic acceptors were utilized poorly and no accurate switch was observed when recombination acceptors retained only five bases of complementarity. These findings confirm that murine leukemia virus replicative and recombinogenic template switches differ in homology requirements, and support the notion that factors other than primer-template complementarity may contribute to strong stop acceptor template recognition.

Base pairing among three cis-acting sequences contributes to template switching during hepadnavirus reverse transcription

Synthesis of the relaxed-circular (RC) DNA genome of hepadnaviruses requires two template switches during plus-strand DNA synthesis: primer translocation and circularization. Although primer translocation and circularization use different donor and acceptor sequences, and are distinct temporally, they share the common theme of switching from one end of the minus-strand template to the other end. Studies of duck hepatitis B virus have indicated that, in addition to the donor and acceptor sequences, three other cis-acting sequences, named 3E, M, and 5E, are required for the synthesis of RC DNA by contributing to primer translocation and circularization. The mechanism by which 3E, M, and 5E act was not known. We present evidence that these sequences function by base pairing with each other within the minus-strand template. 3E base-pairs with one portion of M (M3) and 5E base-pairs with an adjacent portion of M (M5). We found that disrupting base pairing between 3E and M3 and between 5E and M5 inhibited primer translocation and circularization. More importantly, restoring base pairing with mutant sequences restored the production of RC DNA. These results are consistent with the model that, within duck hepatitis B virus capsids, the ends of the minus-strand template are juxtaposed via base pairing to facilitate the two template switches during plus-strand DNA synthesis.

A pregenomic RNA sequence adjacent to DR1 and complementary to epsilon influences hepatitis B virus replication efficiency

Hepatitis B virus (HBV) possesses a 3.2-kb partially double-stranded DNA genome that is generated inside the nucleocapsid by the reverse transcription of the 3.5-kb pregenomic viral transcript. The initial steps in viral replication involve the recognition of an encapsidation signal termed epsilon (epsilon) at the 5'-end of the pregenomic RNA by the HBV polymerase. The polymerase-bound pregenomic RNA is subsequently incorporated into an immature nucleocapsid particle and minus-strand HBV DNA synthesis is initiated utilizing the bulge region of epsilon as a template and a tyrosine residue in the amino-terminal region of the polymerase as a primer. Three nucleotides complementary to the 3'-end of the bulge region of epsilon are synthesized and subsequently translocated with the polymerase molecule to the acceptor site located in the DR1 sequence present at the 3'-end of the pregenomic RNA. Using mutagenesis analysis, a sequence element designated phi (phi) located upstream of the 3' DR1 sequence has been identified that is complementary to epsilon and is important for efficient viral replication. This element may bring the 3' DR1 sequence into proximity with the three nucleotide primer synthesized at the bulge of epsilon and facilitate primer translocation to the 3' DR1 acceptor sequence. Sequence elements with similar proximity to the 3' DR1 sequences and complementarity to epsilon are present in the woodchuck hepatitis virus (WHV) and duck hepatitis B virus (DHBV), suggesting the phi regulatory element may be phylogenetically conserved due to its functional importance in hepadnavirus minus-strand DNA synthesis.

Characterization of the cis-acting contributions to avian hepadnavirus RNA encapsidation

Previous analysis of duck hepatitis B virus (DHBV) indicated the presence of at least two cis-acting sequences required for efficient encapsidation of its pregenomic RNA (pgRNA), epsilon and region II. epsilon, an RNA stem-loop near the 5' end of the pgRNA, has been characterized in detail, while region II, located in the middle of the pgRNA, is not as well defined. Our initial aim was to identify the sequence important for the function of region II in DHBV. We scanned region II and the surrounding sequence by using a quantitative encapsidation assay. We found that the sequence between nucleotides (nt) 438 and 720 contributed to efficient pgRNA encapsidation, while the sequence between nt 538 and 610 made the largest contribution to encapsidation. Additionally, deletions between the two encapsidation sequences, epsilon and region II, had variable effects on encapsidation, while substitutions of heterologous sequence between epsilon and region II disrupted the ability of the pgRNA to be encapsidated efficiently. Overall, these data indicate that the intervening sequences between epsilon and region II play a role in encapsidation. We also analyzed heron hepatitis B virus (HHBV) for the presence of region II and found features similar to DHBV: a broad region necessary for efficient encapsidation that contained a critical region II sequence. Furthermore, we analyzed variants of DHBV that were substituted with HHBV sequence over region II and found that the chimeras were not fully functional for RNA encapsidation. These results indicate that sequences within region II may need to be compatible with other viral components in order to function in pgRNA encapsidation.

cis-Acting sequences 5E, M, and 3E interact to contribute to primer translocation and circularization during reverse transcription of avian hepadnavirus DNA

Hepadnaviral reverse transcription requires template switches for the genesis of relaxed circular (RC) DNA, the major genomic form in virions. Two template switches, primer translocation and circularization, are required during the synthesis of the second, or plus, strand of DNA. Studies of duck hepatitis B virus (DHBV) indicate that in addition to the requirement for repeated sequences at the donor and acceptor sites, template switching requires at least three other cis-acting sequences, 5E, M, and 3E. In this study we analyzed a series of variant heron hepatitis B viruses (HHBV) in which the regions of the genome that would be expected to contain 5E, M, and 3E were replaced with DHBV sequence. We found that all single and double chimeras were partially defective in the synthesis of RC DNA. In contrast, the triple chimera was able to synthesize RC DNA at a level comparable to that of unchanged HHBV. These results indicate that the three cis-acting sequences, 5E, M, and 3E, need to be compatible to contribute to RC DNA synthesis, suggesting that these sequences interact during plus-strand synthesis. Second, we found that the defect in RC DNA synthesis for several of the single and double chimeric viruses resulted from a partial defect in primer translocation/utilization and a partial defect in circularization. These findings indicate that the processes of primer translocation and circularization share a mechanism during which 5E, M, and 3E interact.

Identification and characterization of a novel replicative intermediate of heron hepatitis B virus

We have identified and characterized a novel intracellular DNA replicative intermediate that is synthesized by heron hepatitis B virus (HHBV) and not by other avian hepadnaviruses. The new DNA form is synthesized in all host cells tested. The HHBV nucleic acid template, and not HHBV proteins, is responsible for the formation of the new form. The new form is comprised of a full-length minus-strand DNA and an incomplete plus-strand DNA whose 5' ends are mapped to DR2, predominantly. The 3' ends of its plus-strand are located between nucleotides 946 and 1046. Genetic analysis indicates that the sequences responsible for the formation of the new form lie between nucleotides 910 and 1364. The endogenous polymerase activity of capsids isolated from cells converted the new form into RC DNA. Intracellular capsids containing the new form are secreted inefficiently as virions, in comparison to RC- and DL DNA-containing capsids. Our analysis suggests that the new form is an incomplete RC DNA molecule that is due to a specific block or pause in the synthesis of plus-strand DNA. Our analysis also suggests that capsids become competent for efficient secretion sometime after the synthesis of 1500 nucleotides of plus-strand DNA.

Analysis of duck hepatitis B virus reverse transcription indicates a common mechanism for the two template switches during plus-strand DNA synthesis

The synthesis of the hepadnavirus relaxed circular DNA genome requires two template switches, primer translocation and circularization, during plus-strand DNA synthesis. Repeated sequences serve as donor and acceptor templates for these template switches, with direct repeat 1 (DR1) and DR2 for primer translocation and 5'r and 3'r for circularization. These donor and acceptor sequences are at, or near, the ends of the minus-strand DNA. Analysis of plus-strand DNA synthesis of duck hepatitis B virus (DHBV) has indicated that there are at least three other cis-acting sequences that make contributions during the synthesis of relaxed circular DNA. These sequences, 5E, M, and 3E, are located near the 5' end, the middle, and the 3' end of minus-strand DNA, respectively. The mechanism by which these sequences contribute to the synthesis of plus-strand DNA was unclear. Our aim was to better understand the mechanism by which 5E and M act. We localized the DHBV 5E element to a short sequence of approximately 30 nucleotides that is 100 nucleotides 3' of DR2 on minus-strand DNA. We found that the new 5E mutants were partially defective for primer translocation/utilization at DR2. They were also invariably defective for circularization. In addition, examination of several new DHBV M variants indicated that they too were defective for primer translocation/utilization and circularization. Thus, this analysis indicated that 5E and M play roles in both primer translocation/utilization and circularization. In conjunction with earlier findings that 3E functions in both template switches, our findings indicate that the processes of primer translocation and circularization share a common underlying mechanism.

Small DNA hairpin negatively regulates in situ priming during duck hepatitis B virus reverse transcription

There are two mutually exclusive pathways for plus-strand DNA synthesis in hepadnavirus reverse transcription. The predominant pathway gives rise to relaxed circular DNA, while the other pathway yields duplex linear DNA. Both pathways use the same RNA primer, which is capped and 18 or 19 nucleotides in length. At the completion of minus-strand DNA synthesis, the final RNase H cleavage generates the plus-strand primer. To make relaxed circular DNA, primer translocation must occur, resulting in the transfer of the primer generated at DR1 to the acceptor site (DR2) near the opposite end of the minus-strand DNA. A small fraction of viruses instead make duplex linear DNA after initiating plus-strand DNA synthesis from DR1, a process called in situ priming. We are interested in understanding the mechanism of discrimination between these two pathways. Some variants of duck hepatitis B virus exhibit high levels of in situ priming due to cis-acting mutations. The mechanism by which these mutations act has been obscure. Sequence inspection predicted formation of a small DNA hairpin in the region overlapping these mutations. We have shown that substitutions disrupting base pairing potential in this hairpin led to increased levels of in situ priming. The introduction of compensatory changes to restore base pairing potential led to reduced levels of in situ priming. Thus, formation of the small DNA hairpin overlapping the 5' end of DR1 in the minus strand contributes to the regulation of primer translocation, at least, through inhibition of in situ priming by making the 3' end of the minus-strand DNA a poor template for initiation.

Mutations that increase in situ priming also decrease circularization for duck hepatitis B virus

The process of hepadnavirus reverse transcription involves two template switches during the synthesis of plus-strand DNA. The first involves translocation of the plus-strand primer from its site of generation, the 3' end of minus-strand DNA, to the complementary sequence DR2, located near the 5' end of the minus-strand DNA. Plus strands initiated from DR2 are extended to the 5' end of the minus-strand DNA. At this point, the 3' end of the minus strand becomes the template via the second template switch, a process called circularization. Elongation of circularized plus-strand DNA generates relaxed circular DNA. Although most virions contain relaxed circular DNA, some contain duplex linear DNA. Duplex linear genomes are synthesized when the plus-strand primer is used at the site of its generation, the 3' end of the minus-strand template. This type of synthesis is called in situ priming. Although in situ priming is normally low, in some duck hepatitis B virus mutants this type of priming is elevated. For example, mutations within the 3' end of the minus-strand DNA can lead to increased levels of in situ priming. We report here that these same mutations result in a second defect, a less efficient template switch that circularizes the genome. Although it is not clear how these mutations affect both steps in DNA replication, our findings suggest a commonality in the mechanism of initiation of plus-strand synthesis and the template switch that circularizes the genome.

The binding site of transcription factor YY1 is required for intramolecular recombination between terminally repeated sequences of linear replicative hepatitis B virus DNA

In the replication cycle of hepadnavirus DNA, the double-stranded linear form of viral DNA is generated as a minor replicative intermediate, which is efficiently converted to covalently closed circular DNA (cccDNA) by intramolecular recombination (W. Yang and J. Summers, J. Virol. 69:4029-4036, 1995). We previously found a binding site of transcription factor Yin and Yang 1 (YY1) in one terminal region of the double-stranded linear replicative hepatitis B virus (HBV) DNA (M. Nakanishi-Matsui, Y. Hayashi, Y. Kitamura, and K. Koike, J. Virol. 74:5562-5568, 2000). However, it is not known whether the YY1-binding site is required for the intramolecular recombination of HBV DNA. In this study, we established an HBV-producing system in which the cccDNA appeared to be generated from the transfected linear DNA or the linear replicative DNA by nonhomologous end joining (NHEJ) or by both NHEJ and homologous recombination between terminally repeated sequences, respectively. When the YY1-binding site in the terminal region of transfected linear viral DNA was mutated, the cccDNA was generated merely by NHEJ. Results suggest that the YY1-binding site in the terminal region of linear replicative HBV DNA is required for intramolecular recombination between terminally repeated sequences.

Evidence that the first strand-transfer reaction of duck hepatitis B virus reverse transcription requires the polymerase and that strand transfer is not needed for the switch of the polymerase to the elongation mode of DNA synthesis

Deletion of amino acids 79-88 in the duck hepatitis B virus reverse transcriptase had minimal effects on polymerase activities prior to the minus-strand DNA transfer reaction, yet it greatly diminished strand transfer and subsequent DNA synthesis. This mutation also reduced reverse transcription on exogenous RNA templates. The reaction on exogenous RNAs employed the phosphonoformic acid (PFA)-sensitive elongation mode of DNA synthesis rather than the PFA-resistant priming mode, despite the independence of DNA synthesis in this assay from the priming and minus-strand transfer reactions. These data provide experimental evidence that the polymerase is involved directly in the minus-strand transfer reaction and that the switch of the polymerase from the early PFA-resistant mode of DNA synthesis to the later PFA-sensitive elongation mode does not require the strand-transfer reaction.

Hepatitis B virus biology

Hepadnaviruses (hepatitis B viruses) cause transient and chronic infections of the liver. Transient infections run a course of several months, and chronic infections are often lifelong. Chronic infections can lead to liver failure with cirrhosis and hepatocellular carcinoma. The replication strategy of these viruses has been described in great detail, but virus-host interactions leading to acute and chronic disease are still poorly understood. Studies on how the virus evades the immune response to cause prolonged transient infections with high-titer viremia and lifelong infections with an ongoing inflammation of the liver are still at an early stage, and the role of the virus in liver cancer is still elusive. The state of knowledge in this very active field is therefore reviewed with an emphasis on past accomplishments as well as goals for the future.

A new avian hepadnavirus infecting snow geese (Anser caerulescens) produces a significant fraction of virions containing single-stranded DNA

We describe the identification and functional analysis of an evolutionary distinct new avian hepadnavirus. Infection of snow geese (Anser caerulescens) with a duck hepatitis B virus (DHBV)-related virus, designated SGHBV, was demonstrated by detection of envelope proteins in sera with anti-DHBV preS and S antibodies. Comparative sequence analysis of the PCR-amplified SGHBV genomes revealed unique SGHBV sequence features compared with other avian hepadnaviruses. Unlike DHBV, SGHBV shows an open reading frame in an analogous position to orthohepadnavirus X genes. Four of five cloned genomes were competent in replication, gene expression, and virus particle secretion in chicken hepatoma cells. Primary duck hepatocytes were permissive for infection with SGHBV, suggesting a similar or identical host range. SGHBV was found to secrete a significant fraction of virion-like particles containing single-stranded viral DNA. This was observed both in cell culture medium of SGHBV DNA-transfected LMH cells and in viremic sera of several birds, suggesting that it is a stable trait of SGHBV. Taken together, SGHBV has several unique features that expand the knowledge of the functional and evolutionary diversity of hepadnaviruses and offers new experimental opportunities for studies on the life cycle of hepadnaviruses.

Duck hepatitis B virus nucleocapsids formed by N-terminally extended or C-terminally truncated core proteins disintegrate during viral DNA maturation

Hepadnaviruses are DNA viruses that replicate through reverse transcription of an RNA pregenome. Viral DNA synthesis takes place inside viral nucleocapsids, formed by core protein dimers. Previous studies have identified carboxy-terminal truncations of the core protein that affect viral DNA maturation. Here, we describe the effect of small amino-terminal insertions into the duck hepatitis B virus (DHBV) core protein on viral DNA replication. All insertion mutants formed replication-competent nucleocapsids. Elongation of viral DNA, however, appeared to be incomplete. Increasing the number of additional amino acids and introducing negatively charged residues further reduced the observed size of mature viral DNA species. Mutant core proteins did not inhibit the viral polymerase. Instead, viral DNA synthesis destabilized mutant nucleocapsids, rendering mature viral DNA selectively sensitive to nuclease action. Interestingly, the phenotype of two previously described carboxy-terminal DHBV core protein deletion mutants was found to be based on the same mechanism. These data suggest that (i) the amino- as well as the carboxy-terminal portion of the DHBV core protein plays a critical role in nucleocapsid stabilization, and (ii) the hepadnavirus polymerase can perform partial second-strand DNA synthesis in the absence of intact viral nucleocapsids.

Changing the site of initiation of plus-strand DNA synthesis inhibits the subsequent template switch during replication of a hepadnavirus

Unique to hepadnavirus reverse transcription is the process of primer translocation, in which the RNA primer for the initiation of plus-strand DNA synthesis is generated at one site on its template, DR1, and is moved to a new site, DR2. For duck hepatitis B virus (DHBV), DR2 is located within 50 nucleotides of the 5' end of the minus-strand DNA template. When the synthesis of plus-strand DNA proceeds to the 5' terminus of the minus strand, the 3' end of the minus strand becomes the template for DNA synthesis. This switch in templates circularizes the nascent genome and is required for the genesis of the relaxed circular form of the DNA and the mature capsid. Maturation of the capsid is a prerequisite for virus egress. We have analyzed a series of DHBV variants in which plus-strand DNA synthesis was initiated from a new position relative to the 5' end of the template. For these variants, the subsequent circularization was inhibited. We found that when the number of nucleotides between the site of initiation of plus-strand DNA synthesis and the 5' end of its template was restored to 54 nucleotides, circularization was substantially restored. These results mean that the process of circularization is influenced by the earlier steps in DNA replication. This sensitivity is consistent with the notion that this region of the nascent genome is in a dynamic structure that is crucial for successful DNA replication.