RNA-binding activity of hepatitis delta antigen involves two arginine-rich motifs and is required for hepatitis delta virus RNA replication.

Hepatitis delta antigen (HDAg) is an RNA-binding protein with binding specificity for hepatitis delta virus (HDV) RNA (J. H. Lin, M. F. Chang, S. C. Baker, S. Govindarajan, and M. M. C. Lai, J. Virol. 64:4051-4058, 1990). By amino acid sequence homology search, we have identified within its RNA-binding domain two stretches of an arginine-rich motif (ARM), which is present in many prokaryotic and eukaryotic RNA-binding proteins. The first one is KERQDHRRRKA and the second is EDEKRERRIAG, and they are separated by 29 amino acids. Deletion of either one of these ARM sequences resulted in the total loss of the in vitro RNA-binding activity of HDAg. Thus, HDAg is different from other RNA-binding proteins in that it requires two ARM-like sequences for its RNA-binding activity. Replacement of the spacer sequence between the two ARMs with a shorter stretch of sequence also reduced RNA binding in vitro. Furthermore, site-specific mutations of the basic amino acid residues in both ARMs resulted in the total loss or reduction of RNA-binding activity. The biological significance of the RNA-binding activity was studied by examining the trans-activating activity of the RNA-binding mutants. The plasmids expressing HDAgs with various mutations in the RNA-binding motifs were cotransfected with a replication-defective HDV dimer cDNA construct into COS cells. It was found that all the HDAg mutants which had lost the in vitro RNA-binding activity also lost the ability to complement the defect of HDV RNA replication. We conclude that the trans-activating function of HDAg requires its binding to HDV RNA.     

Multimerization of Hepatitis Delta Antigen Is a Critical Determinant of RNA Binding Specificity

Hepatitis delta virus (HDV) RNA forms an unbranched rod structure that is associated with hepatitis delta antigen (HDAg) in cells replicating HDV. Previous in vitro binding experiments using bacterially expressed HDAg showed that the formation of a minimal ribonucleoprotein complex requires an HDV unbranched rod RNA of at least about 300 nucleotides (nt) and suggested that HDAg binds the RNA as a multimer of fixed size. The present study specifically examines the role of HDAg multimerization in the formation of the HDV ribonucleoprotein complex (RNP). Disruption of HDAg multimerization by site-directed mutagenesis was found to profoundly alter the nature of RNP formation. Mutant HDAg proteins defective for multimerization exhibited neither the 300-nt RNA size requirement for binding nor specificity for the unbranched rod structure. The results unambiguously demonstrate that HDAg binds HDV RNA as a multimer and that the HDAg multimer is formed prior to binding the RNA. RNP formation was found to be temperature dependent, which is consistent with conformational changes occurring on binding. Finally, analysis of RNPs constructed with unbranched rod RNAs successively longer than the minimum length indicated that multimeric binding is not limited to the first HDAg bound and that a minimum RNA length of between 604 and 714 nt is required for binding of a second multimer. The results confirm the previous proposal that HDAg binds as a large multimer and demonstrate that the multimer is a critical determinant of the structure of the HDV RNP.Human hepatitis delta virus (HDV) is an unusual subviral agent that increases the severity of acute and chronic liver disease in those infected with its helper, hepatitis B virus (23). The HDV genome is a 1,680-nucleotide (nt) single-stranded circular RNA that is replicated by a double-rolling-circle mechanism (reviewed in references 15 and 28). Both the genome and antigenome RNAs form a characteristic unbranched rod structure due to 70% sequence complementarity between the noncoding and coding regions of the RNA (10, 11, 31). HDV encodes just one protein, hepatitis delta antigen (HDAg), which forms ribonucleoprotein (RNP) complexes with both the genome and the antigenome in cells replicating HDV (3, 5, 30). These complexes play fundamental roles in viral RNA replication and packaging and their characterization is essential for understanding these processes, which are not well characterized.HDAg has been shown to form dimers and higher order multimers, even in the absence of HDV RNA (25, 30, 32). The multimerization activity has been localized to the amino-terminal third of the 195-amino-acid (aa) protein (12, 24, 30, 32). X-ray crystallographic analysis of a peptide comprised of aa 12 to 60 indicated that antiparallel dimers are stabilized by a coiled coil (aa 16 to 48), as well as a hydrophobic core region (aa 50 to 60) that also stabilizes interactions between dimers such that an octameric structure may form (35). Zuccola et al. found that bacterially expressed HDAg could be cross-linked in an octameric structure, and Cornillez-Ty et al. obtained evidence supporting such a structure in cells replicating HDV (7, 35). Site-directed mutations of HDAg amino acids critical for dimerization and/or multimerization abolish the ability of HDAg to support RNA replication (18, 32), indicating that the formation of HDAg multimers is essential for this process.We recently showed that bacterially expressed, C-terminally truncated HDAg forms stable RNP complexes in vitro with segments of HDV RNA that form unbranched rod structures (8). No particular sequences or structures in the RNA, other than the HDV unbranched rod, were essential for complex formation, but, remarkably, binding required that the RNA have a minimum length of at least about 300 nt. Overall, the results were consistent with the formation of a large RNP containing multiple copies of the 19-kDa protein that bound to the RNA either in a highly cooperative manner or as a preformed multimer. On the other hand, based on indirect measures of the RNA-binding activity of site-directed HDAg mutations in cells, others have found that HDAg multimerization might not be required for RNA-binding activity (18).Here, we directly analyze the role of HDAg multimerization in the formation of the HDV RNP complex. We find that HDAg binds to HDV unbranched rod RNA as a preformed multimer. Site-directed mutations that disrupted protein multimerization did not abolish binding but profoundly altered the nature of the RNA-protein complex. In particular, we found that multimerization is associated with RNA-binding specificity, including the RNA length requirement for binding. For the wild-type protein, RNP formation was found to be strongly temperature dependent, suggesting that conformational changes occur on binding, and providing a plausible explanation of the RNA length requirement for binding. Furthermore, we show that the protein binds as multiple multimeric units on longer RNAs, provided the length of the RNA is sufficient. We conclude that the HDAg multimer plays a critical role in the formation of properly structured HDV RNPs.     

Hepatitis Delta Antigen Mediates the Nuclear Import of Hepatitis Delta Virus RNA

Hepatitis delta virus (HDV) RNA replicates in the nuclei of virus-infected cells. The mechanism of nuclear import of HDV RNA is so far unknown. Using a fluorescein-labeled HDV RNA introduced into partially permeabilized HeLa cells, we found that HDV RNA accumulated only in the cytoplasm. However, in the presence of hepatitis delta antigen (HDAg), which is the only protein encoded by HDV RNA, the HDV RNA was translocated into the nucleus, suggesting that nuclear import of HDV RNA is mediated by HDAg. Deletion of the nuclear localization signal (NLS) or RNA-binding motifs of HDAg resulted in the failure of nuclear import of HDV RNA, indicating that both the NLS and an RNA-binding motif of HDAg are required for the RNA-transporting activity of HDAg. Surprisingly, any one of the three previously identified RNA-binding motifs was sufficient to confer the RNA-transporting activity. We have further shown that HDAg, via its NLS, interacts with karyopherin α2 in vitro, suggesting that nuclear import of the HDAg-HDV RNA complex is mediated by the karyopherin α2β heterodimer. The nuclear import of HDV RNA may be the first biological function of HDAg in the HDV life cycle.     

Genotype-Specific Complementation of Hepatitis Delta Virus RNA Replication by Hepatitis Delta Antigen

Characterizations of genetic variations among hepatitis delta virus (HDV) isolates have focused principally on phylogenetic analysis of sequences, which vary by 30 to 40% among three genotypes and about 10 to 15% among isolates of the same genotype. The significance of the sequence differences has been unclear but could be responsible for pathogenic variations associated with the different genotypes. Studies of the mechanisms of HDV replication have been limited to cDNA clones from HDV genotype I, which is the most common. To perform a comparative analysis of HDV RNA replication in genotypes I and III, we have obtained a full-length cDNA clone from an HDV genotype III isolate. In transfected Huh-7 cells, the functional roles of the two forms of the viral protein, hepatitis delta antigen (HDAg), in HDV RNA replication are similar for both genotypes I and III; the short form is required for RNA replication, while the long form inhibits replication. For both genotypes, HDAg was able to support replication of RNAs of the same genotype that were mutated so as to be defective for HDAg production. Surprisingly, however, neither genotype I nor genotype III HDAg was able to support replication of such mutated RNAs of the other genotype. The inability of genotype III HDAg to support replication of genotype I RNA could have been due to a weak interaction between the RNA and HDAg. The clear genotype-specific activity of HDAg in supporting HDV RNA replication confirms the original categorization of HDV sequences in three genotypes and further suggests that these should be referred to as types (i.e., HDV-I and HDV-III) rather than genotypes.     

Hepatitis Delta Virus RNA Editing Is Highly Specific for the Amber/W Site and Is Suppressed by Hepatitis Delta Antigen

RNA editing at adenosine 1012 (amber/W site) in the antigenomic RNA of hepatitis delta virus (HDV) allows two essential forms of the viral protein, hepatitis delta antigen (HDAg), to be synthesized from a single open reading frame. Editing at the amber/W site is thought to be catalyzed by one of the cellular enzymes known as adenosine deaminases that act on RNA (ADARs). In vitro, the enzymes ADAR1 and ADAR2 deaminate adenosines within many different sequences of base-paired RNA. Since promiscuous deamination could compromise the viability of HDV, we wondered if additional deamination events occurred within the highly base paired HDV RNA. By sequencing cDNAs derived from HDV RNA from transfected Huh-7 cells, we determined that the RNA was not extensively modified at other adenosines. Approximately 0.16 to 0.32 adenosines were modified per antigenome during 6 to 13 days posttransfection. Interestingly, all observed non-amber/W adenosine modifications, which occurred mostly at positions that are highly conserved among naturally occurring HDV isolates, were found in RNAs that were also modified at the amber/W site. Such coordinate modification likely limits potential deleterious effects of promiscuous editing. Neither viral replication nor HDAg was required for the highly specific editing observed in cells. However, HDAg was found to suppress editing at the amber/W site when expressed at levels similar to those found during HDV replication. These data suggest HDAg may regulate amber/W site editing during virus replication.     

The antigen of hepatitis delta virus: examination of in vitro RNA-binding specificity.

The only known protein of hepatitis delta virus (HDV), the delta antigen, is found both within virus particles and within the nucleus of the infected cell, where it has one or more roles essential for RNA genome replication. Others have demonstrated that the antigen has the ability, in vitro, to specifically bind HDV RNA species. We report a further examination of this phenomenon, using partially purified recombinant protein, expressed as a fusion with the staphylococcal protein A. From Northwestern (RNA-immunoblot) analyses with both complete and various subdomains of HDV genomic and antigenomic RNAs, we found that a necessary feature for specific binding was that the RNA be able to fold to some extent into the so-called rodlike structure; this structure is a predicted intramolecular partial base-pairing of the circular RNA, with about 70% of all bases involved, so as to produce an unbranched rodlike structure. Six different subregions of the HDV rodlike structure, three on the genomic RNA and three on its complement, the antigenomic RNA, were tested and found to be sufficient for antigen binding. However, features in addition to the rodlike structure may also be necessary for specific binding, because we found that a similar structure present in the RNA of the potato spindle tuber viroid did not allow binding.     

Polyadenylation of the mRNA of hepatitis delta virus is dependent on the structure of the nascent RNA and regulated by the small or large delta antigen.

During the hepatitis delta virus (HDV) RNA replication, synthesis of either the mRNA for the delta antigen (HDAg) or the full-length antigenomic RNA is determined by selective usage of the potent poly(A) signal on the antigenome. To elucidate the regulatory mechanism, HDV cDNA cotransfection system was used to examine the potential effect of the secondary structure of the nascent RNA and that of the HDAg on HDV polyadenylation in transfected cells. We found that when the nascent RNA species could fold itself to form the rodlike structure, the HDV polyadenylation was suppressed 3 to 5 fold by the HDAg. In addition, we observed that the small and the large HDAg exerted a similar suppressive effect on the HDV polyadenylation, though they played different roles in HDV replication. We concluded that the HDV polyadenylation could be regulated by the structure of the nascent antigenomic RNA and by either the small or large HDAg.     

Organization and Expression of the Hepatitis Delta Virus Genome

The RNA genome of human hepatitis delta virus (HDV) is an unusual small circular single-stranded species that can fold on itself to form an unbranched rod-like structure. This RNA is replicated in the nucleus by RNA-directed RNA synthesis coupled with RNA processing events. During processing events a subgenomic, polyadenylated RNA that is complementary to the genome and expressed in the cytoplasm as the small form of the delta antigen, a 195-amino-acid protein essential for genome replication is produced. The strategies of RNA virus genome organization and expression are very diverse; those used by HDV seem unique among animal viruses, although there are some distant similarities with those used by some plant pathogens.     

Hepatitis delta virus: protein composition of delta antigen and its hepatitis B virus-derived envelope.

Hepatitis delta virus (HDV)-associated particles were purified from the serum of an experimentally infected chimpanzee by size chromatography and by density centrifugation. Hepatitis delta antigen (HDAg) was detected after mild detergent treatment at a column elution volume corresponding to 36-nm particles and banded at a density of 1.25 g/ml. The serum had an estimated titer of 10(9) to 10(10) HDV-associated particles and had only a 10-fold excess of hepatitis B surface antigen (HBsAg) not associated with HDAg. Therefore, HDV appears to be much more efficiently packed and secreted than is its helper virus, hepatitis B virus (HBV), which is usually accompanied by a 1,000-fold excess of HBsAg. The protein compositions of the HDAg-containing particles were analyzed by immunoblotting with HDAg-, HBsAg-, and hepatitis B core antigen-specific antisera and monoclonal antibodies to HBV surface gene products. The HBsAg envelope of HDAg contained approximately 95% P24/GP27s, 5% GP33/36s, and 1% P39/GP42s proteins. This protein composition was more similar to that of the 22-nm particles of HBsAg than to that of complete HBV. The significant amount of GP33/36s suggests that the HBsAg component of the HDV-associated particle carries the albumin receptor. Two proteins of 27 and 29 kilodaltons which specifically bound antibody to HDAg but not HBV-specific antibodies were detected in the interior of the 36-nm particle. Since these proteins were structural components of HDAg and were most likely coded for by HDV, they were designated P27d and P29d.     

Hepatitis delta virus antigen is methylated at arginine residues, and methylation regulates subcellular localization and RNA replication

Hepatitis delta virus (HDV) contains a circular RNA which encodes a single protein, hepatitis delta antigen (HDAg). HDAg exists in two forms, a small form (S-HDAg) and a large form (L-HDAg). S-HDAg can transactivate HDV RNA replication. Recent studies have shown that posttranslational modifications, such as phosphorylation and acetylation, of S-HDAg can modulate HDV RNA replication. Here we show that S-HDAg can be methylated by protein arginine methyltransferase (PRMT1) in vitro and in vivo. The major methylation site is at arginine-13 (R13), which is in the RGGR motif of an RNA-binding domain. The methylation of S-HDAg is essential for HDV RNA replication, especially for replication of the antigenomic RNA strand to form the genomic RNA strand. An R13A mutation in S-HDAg inhibited HDV RNA replication. The presence of a methylation inhibitor, S-adenosyl-homocysteine, also inhibited HDV RNA replication. We further found that the methylation of S-HDAg affected its subcellular localization. Methylation-defective HDAg lost the ability to form a speckled structure in the nucleus and also permeated into the cytoplasm. These results thus revealed a novel posttranslational modification of HDAg and indicated its importance for HDV RNA replication. This and other results further showed that, unlike replication of the HDV genomic RNA strand, replication of the antigenomic RNA strand requires multiple types of posttranslational modification, including the phosphorylation and methylation of HDAg.     

RNA editing in hepatitis delta virus genotype III requires a branched double-hairpin RNA structure

RNA editing at the amber/W site plays a central role in the replication scheme of hepatitis delta virus (HDV), allowing the virus to produce two functionally distinct forms of the sole viral protein, hepatitis delta antigen (HDAg), from the same open reading frame. Editing is carried out by a cellular activity known as ADAR (adenosine deaminase), which acts on RNA substrates that are at least partially double stranded. In HDV genotype I, editing requires a highly conserved base-paired structure that occurs within the context of the unbranched rod structure characteristic of HDV RNA. This base-paired structure is disrupted in the unbranched rod of HDV genotype III, which is the most distantly related of the three known HDV genotypes and is associated with the most severe disease. Here I show that RNA editing in HDV genotype III requires a branched double-hairpin structure that deviates substantially from the unbranched rod structure, involving the rearrangement of nearly 80 bp. The structure includes a UNCG RNA tetraloop, a highly stable structural motif frequently involved in the folding of large RNAs such as rRNA. The double-hairpin structure is required for editing, and hence for virion formation, but not for HDV RNA replication, which requires the unbranched rod structure. HDV genotype III thus relies on a dynamic conformational switch between the two different RNA structures: the unbranched rod characteristic of HDV RNA and a branched double-hairpin structure that is required for RNA editing. The different mechanisms of editing in genotypes I and III underscore their functional differences and may be related to pathogenic differences as well.     

The nucleolar phosphoprotein B23 interacts with hepatitis delta antigens and modulates the hepatitis delta virus RNA replication

Hepatitis delta virus (HDV) encodes two isoforms of delta antigens (HDAgs). The small form of HDAg is required for HDV RNA replication, while the large form of HDAg inhibits the viral replication and is required for virion assembly. In this study, we found that the expression of B23, a nucleolar phosphoprotein involved in disparate functions including nuclear transport, cellular proliferation, and ribosome biogenesis, is up-regulated by these two HDAgs. Using in vivo and in vitro experimental approaches, we have demonstrated that both isoforms of HDAg can interact with B23 and their interaction domains were identified as the NH(2)-terminal fragment of each molecule encompassing the nuclear localization signal but not the coiled-coil region of HDAg. Sucrose gradient centrifugation analysis indicated that the majority of small HDAg, but a lesser amount of the large HDAg, co-sedimented with B23 and nucleolin in the large nuclear complex. Transient transfection experiments also indicated that introducing exogenous full-length B23, but not a mutated B23 defective in HDAg binding, enhanced HDV RNA replication. All together, our results reveal that HDAg has two distinct effects on nucleolar B23, up-regulation of its gene expression and the complex formation, which in turn regulates HDV RNA replication. Therefore, this work demonstrates the important role of nucleolar protein in regulating the HDV RNA replication through the complex formation with the key positive regulator being small HDAg.     

Isoprenylation mediates direct protein-protein interactions between hepatitis large delta antigen and hepatitis B virus surface antigen.

Hepatitis delta antigen (HDAg) consists of two protein species of 195 and 214 amino acids, respectively, which are identical in sequence except that the large HDAg has additional 19 amino acids at its C terminus and is prenylated. Previous studies have shown that the large HDAg and the surface antigen of hepatitis B virus (HBsAg) together can form empty hepatitis delta virus (HDV) particles. To understand the molecular mechanism of HDV virion morphogenesis, we investigated the possible direct protein-protein interaction between HDAg and HBsAg. We constructed recombinant baculoviruses expressing the major form of HBsAg and various mutant HDAgs and used these proteins for far-Western protein binding assays. We demonstrated that HBsAg interacted specifically with the large HDAg but not with the small HDAg. Using mutant HDAgs which have defective or aberrant prenylation, we showed that this interaction required isoprenylates on the cysteine residue of the C terminus of the large HDAg. Isoprenylation alone, without the remainder of the C-terminal amino acids of the large HDAg, was insufficient to mediate interaction with HBsAg. This study demonstrates a novel role of prenylates in HDV virion assembly.     

Packaging of hepatitis delta virus RNA via the RNA-binding domain of hepatitis delta antigens: different roles for the small and large delta antigens.

Hepatitis delta virus (HDV) is composed of four specific components. The first component is envelope protein which contains hepatitis B surface antigens. The second and third components are nucleocapsid proteins, referred to as small and large hepatitis delta antigens (HDAgs). The final component is a single-stranded circular RNA molecule known as the viral genome. In order to study the mechanism of HDV RNA packaging, a four-plasmid cotransfection system in which each viral component was provided by a separate plasmid was employed. Virus-like particles released from Huh-7 cells receiving such a cotransfection were found to contain HDV RNA along with three proteins. Therefore, the four-plasmid cotransfection system could lead to successful HDV RNA packaging in vitro. The system was then used to show that the large HDAg alone was able to achieve a low level of HDV RNA packaging. Analysis of a variety of large HDAg mutants revealed that the RNA-binding domain was essential for viral RNA packaging. By increasing the incorporation of small HDAg into virus-like particles, we found a three- to fourfold enhancement of HDV RNA packaging. This effect was probably through a direct binding of HDV RNA, independent from that of large HDAg, with the small HDAg. The subsequent RNA-protein complex was packaged into particles. The results provided insight into the roles and functional domains of small and large HDAgs in HDV RNA packaging.     

Human hepatitis delta antigen is a nuclear phosphoprotein with RNA-binding activity.

The genetic origin, structure, and biochemical properties of the delta antigen (HDAg) of a human hepatitis delta virus (HDV) were investigated. A cDNA fragment containing the open reading frame encoding the HDAg was transcribed into RNA and used for in vitro translation in rabbit reticulocyte lysates. The HDAg open reading frame was also inserted into an expression vector containing a simian virus 40 T-antigen promoter and expressed into COS 7 cells. In both systems, a protein species of 26 kilodaltons was synthesized from this open reading frame and could be specifically immunoprecipitated with antisera obtained from patients with delta hepatitis. A similar protein was also synthesized from antigenomic-sense monomeric HDV RNA in both systems, although the efficiency of translation was lower than that of the isolated open reading frame. This protein was found to be phosphorylated at the serine residues. Immunoperoxidase studies with anti-HDV sera demonstrated that the HDAg was expressed mainly in the nuclei of the transfected COS 7 cells. Moreover, the HDAg was shown to bind the genomic RNA of HDV. These studies indicate that HDAg is encoded by the antigenomic-sense RNA of HDV and is a nuclear phosphoprotein associated with an RNA-binding activity.     

Functional study of hepatitis delta virus large antigen in packaging and replication inhibition: role of the amino-terminal leucine zipper.

The large hepatitis delta antigen (HDAg) has been found to be essential for the assembly of the hepatitis delta virion. Furthermore, in a cotransfection experiment, the large HDAg itself, without the hepatitis delta virus (HDV) genome and small HDAg, could be packaged into hepatitis B surface antigen (HBsAg) particles. By deletion analysis, it was shown that the amino-terminal leucine zipper domain was dispensable for packaging. The large HDAg could also help in copackaging of the small HDAg into HBsAg particles without the need for HDV RNA. This process was probably mediated through direct interaction of the two HDAgs as a mutated large HDAg whose leucine zipper domain was deleted such that it could not help in copackaging of the small HDAg. This mutated large HDAg did not suppress HDV replication, suggesting that this effect is probably also via protein interaction. These results indicated that functional domains of the large HDAg responsible for packaging with HBsAg particles and for the trans-negative effect on HDV replication can be separated.