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.     

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 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.     

Cathepsin B & L Are Not Required for Ebola Virus Replication

Ebola virus (EBOV), family Filoviridae, emerged in 1976 on the African continent. Since then it caused several outbreaks of viral hemorrhagic fever in humans with case fatality rates up to 90% and remains a serious Public Health concern and biothreat pathogen. The most pathogenic and best-studied species is Zaire ebolavirus (ZEBOV). EBOV encodes one viral surface glycoprotein (GP), which is essential for replication, a determinant of pathogenicity and an important immunogen. GP mediates viral entry through interaction with cellular surface molecules, which results in the uptake of virus particles via macropinocytosis. Later in this pathway endosomal acidification activates the cysteine proteases Cathepsin B and L (CatB, CatL), which have been shown to cleave ZEBOV-GP leading to subsequent exposure of the putative receptor-binding and fusion domain and productive infection. We studied the effect of CatB and CatL on in vitro and in vivo replication of EBOV. Similar to previous findings, our results show an effect of CatB, but not CatL, on ZEBOV entry into cultured cells. Interestingly, cell entry by other EBOV species (Bundibugyo, Côte d''Ivoire, Reston and Sudan ebolavirus) was independent of CatB or CatL as was EBOV replication in general. To investigate whether CatB and CatL have a role in vivo during infection, we utilized the mouse model for ZEBOV. Wild-type (control), catB^−/− and catL^−/− mice were equally susceptible to lethal challenge with mouse-adapted ZEBOV with no difference in virus replication and time to death. In conclusion, our results show that CatB and CatL activity is not required for EBOV replication. Furthermore, EBOV glycoprotein cleavage seems to be mediated by an array of proteases making targeted therapeutic approaches difficult.     

The Toll and Imd Pathways Are Not Required for Wolbachia-Mediated Dengue Virus Interference

Wolbachia blocks dengue virus replication in Drosophila melanogaster as well as in Aedes aegypti. Using the Drosophila model and mutations in the Toll and Imd pathways, we showed that neither pathway is required for expression of the dengue virus-blocking phenotype in the Drosophila host. This provides additional evidence that the mechanistic basis of Wolbachia-mediated dengue virus blocking in insects is more complex than simple priming of the host insect innate immune system.     

Analysis of Binding Sites on Complement Factor I That Are Required for Its Activity

The central complement inhibitor factor I (FI) degrades activated complement factors C4b and C3b in the presence of cofactors such as C4b-binding protein, factor H, complement receptor 1, and membrane cofactor protein. FI is a serine protease composed of two chains. The light chain comprises the serine protease domain, whereas the heavy chain contains several domains; that is, the FI and membrane attack complex domain (FIMAC), CD5, low density lipoprotein receptor 1 (LDLr1) and LDLr2 domains. To understand better how FI acts as a complement inhibitor, we used homology-based models of FI domains to predict potential binding sites. Specific amino acids were then mutated to yield 16 well expressed mutants, which were then purified from media of eukaryotic cells for functional analyses. The Michaelis constant (K_m) of all FI mutants toward a small substrate was not altered, whereas some mutants showed increased maximum initial velocity (V_max). All the mutations in the FIMAC domain affected the ability of FI to degrade C4b and C3b irrespective of the cofactor used, whereas only some mutations in the CD5 and LDLr1/2 domains had a similar effect. These same mutants also showed impaired binding to C3met. In conclusion, the FIMAC domain appears to harbor the main binding sites important for the ability of FI to degrade C4b and C3b.     

Apolipoprotein E but Not B Is Required for the Formation of Infectious Hepatitis C Virus Particles

Our previous studies have found that hepatitis C virus (HCV) particles are enriched in apolipoprotein E (apoE) and that apoE is required for HCV infectivity and production. Studies by others, however, suggested that both microsomal transfer protein (MTP) and apoB are important for HCV production. To define the roles of apoB and apoE in the HCV life cycle, we developed a single-cycle HCV growth assay to determine the correlation of HCV assembly with apoB and apoE expression, as well as the influence of MTP inhibitors on the formation of HCV particles. The small interfering RNA (siRNA)-mediated knockdown of apoE expression remarkably suppressed the formation of HCV particles. However, apoE expressed ectopically could restore the defect of HCV production posed by the siRNA-mediated knockdown of endogenous apoE expression. In contrast, apoB-specific antibodies and siRNAs had no significant effect on HCV infectivity and production, respectively, suggesting that apoB does not play a significant role in the HCV life cycle. Additionally, two MTP inhibitors, CP-346086 and BMS-2101038, efficiently blocked secretion of apoB-containing lipoproteins but did not affect HCV production unless apoE expression and secretion were inhibited. At higher concentrations, however, MTP inhibitors blocked apoE expression and secretion and consequently suppressed the formation of HCV particles. Furthermore, apoE was found to be sensitive to trypsin digestion and to interact with NS5A in purified HCV particles and HCV-infected cells, as demonstrated by coimmunoprecipitation. Collectively, these findings demonstrate that apoE but not apoB is required for HCV assembly, probably via a specific interaction with NS5A.Hepatitis C virus (HCV) is the leading cause of chronic viral hepatitis, affecting approximately 170 million people worldwide (8, 40). HCV coinfection with human immunodeficiency virus (HIV) is also common, occurring overall in 25 to 30% of HIV-positive persons (1). Individuals with chronic HCV infection are at high risk for the development of cirrhosis and hepatocellular carcinoma. A pegylated interferon and ribavirin combination is the standard therapy to treat hepatitis C but suffers from limited efficacy (<50% antiviral response among patients infected with the dominant genotype 1 HCV) and severe side effects (18, 27). More efficacious and safer antiviral drugs for effective treatment of hepatitis C are urgently needed. A thorough understanding of the HCV life cycle will likely provide novel targets for antiviral drug discovery and development to control HCV infection.HCV is an enveloped RNA virus containing a single-stranded, positive-sense RNA genome and is classified as a Hepacivirus in the Flaviviridae family (11, 33). The viral RNA genome carries a single open reading frame flanked by untranslated regions (UTRs) at both the 5′ and 3′ ends. The 5′ and 3′ UTRs contain cis-acting RNA elements important for the initiation of HCV polyprotein translation and viral RNA replication (24). Upon translation, the HCV polyprotein precursor is proteolytically processed by cellular peptidases and viral proteases into at least 10 different viral proteins (C, E1, E2, p7, NS2, NS3, NS4A, NS4B, NS5A, and NS5B). Studies with subgenomic HCV RNAs demonstrated that the NS3 to NS5B proteins, in association with intracellular membranes and cellular proteins, are essential and sufficient for HCV RNA replication in the cell (5, 14, 25). The newly synthesized HCV proteins and RNA genome are assembled to form progeny HCV particles by undetermined mechanisms.Our earlier work found that infectious HCV particles are highly enriched in apolipoprotein E (apoE), which is a major determinant of HCV infectivity and production in cell culture (10). ApoE-specific monoclonal antibodies (MAbs) effectively neutralized HCV infectivity, in a dose-dependent manner. The knockdown of apoE expression by specific small interfering RNA (siRNA) remarkably suppressed HCV production, suggesting that apoE is also important for the formation of infectious particles and/or egression (10). However, studies by others suggested that HCV assembly and production are dependent on microsomal transfer protein (MTP) and apolipoprotein B (apoB), both of which are essential components required for the assembly and secretion of very-low-density lipoproteins (VLDLs) (19, 21). In those studies, both apoB-specific siRNAs and MTP inhibitors were found to suppress HCV production (19, 21). It was speculated that HCV shares the same assembly and secretion pathway with VLDLs.To define the roles of apoB and apoE in the formation of HCV particles and egression, we developed a single-cycle HCV growth assay. Using this assay system, we have demonstrated that apoE but not apoB is required for the infectivity and formation of infectious HCV particles. First of all, apoB-specific MAb and polyclonal antibodies did not affect HCV infection. Additionally, apoE-specific siRNA potently inhibited the formation of infectious HCV particles, whereas HCV production was unaffected by the siRNA-mediated knockdown of apoB expression. Furthermore, two MTP inhibitors, CP-346086 and BMS-2101038, efficiently blocked apoB secretion but did not significantly affect HCV production prior to the blockage of apoE expression/secretion. At higher concentrations, however, both MTP inhibitors blocked apoE secretion and consequently suppressed the formation of infectious HCV particles. To further understand the role of apoE in HCV assembly, we carried out coimmunoprecipitation (co-IP) experiments and found that apoE-specific MAb pulled down NS5A but not other HCV proteins from lysed HCV particles, suggesting a specific interaction between apoE and NS5A during the formation of infectious HCV particles. Collectively, our findings demonstrate that apoE but not apoB is required for HCV assembly, probably via a specific interaction with NS5A.     

Cytidine Deaminase Motifs within the DYW Domain of Two Pentatricopeptide Repeat-containing Proteins Are Required for Site-specific Chloroplast RNA Editing

In angiosperm organelles, cytidines are converted to uridines by a deamination reaction in the process termed RNA editing. The C targets of editing are recognized by members of the pentatricopeptide repeat (PPR) protein family. Although other members of the editosome have begun to be identified, the enzyme that catalyzes the C-U conversion is still unknown. The DYW motif at the C terminus of many PPR editing factors contains residues conserved with known cytidine deaminase active sites; however, some PPR editing factors lack a DYW motif. Furthermore, in many PPR-DYW editing factors, the truncation of the DYW motif does not affect editing efficiency, so the role of the DYW motif in RNA editing is unclear. Here, a chloroplast PPR-DYW editing factor, quintuple editing factor 1 (QED1), was shown to affect five different plastid editing sites, the greatest number of chloroplast C targets known to be affected by a single PPR protein. Loss of editing at the five sites resulted in stunted growth and accumulation of apparent photodamage. Adding a C-terminal protein tag to QED1 was found to severely inhibit editing function. QED1 and RARE1, another plastid PPR-DYW editing factor, were discovered to require their DYW motifs for efficient editing. To identify specific residues critical for editing, conserved deaminase residues in each PPR protein were mutagenized. The mutant PPR proteins, when expressed in qed1 or rare1 mutant protoplasts, could not complement the editing defect. Therefore, the DYW motif, and specifically, the deaminase residues, of QED1 and RARE1 are required for editing efficiency.     

RNA Polymerase Activity and Specific RNA Structure Are Required for Efficient HCV Replication in Cultured Cells

We have previously reported that the NS3 helicase (N3H) and NS5B-to-3′X (N5BX) regions are important for the efficient replication of hepatitis C virus (HCV) strain JFH-1 and viral production in HuH-7 cells. In the current study, we investigated the relationships between HCV genome replication, virus production, and the structure of N5BX. We found that the Q377R, A450S, S455N, R517K, and Y561F mutations in the NS5B region resulted in up-regulation of J6CF NS5B polymerase activity in vitro. However, the activation effects of these mutations on viral RNA replication and virus production with JFH-1 N3H appeared to differ. In the presence of the N3H region and 3′ untranslated region (UTR) of JFH-1, A450S, R517K, and Y561F together were sufficient to confer HCV genome replication activity and virus production ability to J6CF in cultured cells. Y561F was also involved in the kissing-loop interaction between SL3.2 in the NS5B region and SL2 in the 3′X region. We next analyzed the 3′ structure of HCV genome RNA. The shorter polyU/UC tracts of JFH-1 resulted in more efficient RNA replication than J6CF. Furthermore, 9458G in the JFH-1 variable region (VR) was responsible for RNA replication activity because of its RNA structures. In conclusion, N3H, high polymerase activity, enhanced kissing-loop interactions, and optimal viral RNA structure in the 3′UTR were required for J6CF replication in cultured cells.     

Formation of Potato Virus A-Induced RNA Granules and Viral Translation Are Interrelated Processes Required for Optimal Virus Accumulation

RNA granules are cellular structures, which play an important role in mRNA translation, storage, and degradation. Animal (+)RNA viruses often co-opt RNA granule proteins for viral reproduction. However, the role of RNA granules in plant viral infections is poorly understood. Here we use Potato virus A (PVA) as a model potyvirus and demonstrate that the helper component-proteinase (HCpro), the potyviral suppressor of RNA silencing, induces the formation of RNA granules. We used confocal microscopy to demonstrate the presence of host RNA binding proteins including acidic ribosomal protein P0, argonaute 1 (AGO1), oligouridylate-binding protein 1 (UBP1), varicose (VCS) and eukaryotic initiation factor iso4E (eIF(iso)4E) in these potyvirus-induced RNA granules. We show that the number of potyviral RNA granules is down-regulated by the genome-linked viral protein (VPg). We demonstrated previously that VPg is a virus-specific translational regulator that co-operates with potyviral RNA granule components P0 and eIF(iso)4E in PVA translation. In this study we show that HCpro and varicose, components of potyviral RNA granules, stimulate VPg-promoted translation of the PVA, whereas UBP1 inhibits this process. Hence, we propose that PVA translation operates via a pathway that is interrelated with potyviral RNA granules in PVA infection. The importance of these granules is evident from the strong reduction in viral RNA and coat protein amounts that follows knock down of potyviral RNA granule components. HCpro suppresses antiviral RNA silencing during infection, and our results allow us to propose that this is also the functional context of the potyviral RNA granules we describe in this study.