Mutational analysis of upstream AUG codons of poliovirus RNA.

The 5' untranslated region of poliovirus type 2 Lansing RNA consists of 744 nucleotides containing seven AUG codons which are followed by in-frame termination codons, thus forming short open reading frames (ORFs). To determine the biological significance of these small ORFs, all of the upstream AUG codons were mutated to UUG. The point mutations were introduced into an infectious poliovirus cDNA clone, and RNA transcribed in vitro from the altered cDNA was transfected into HeLa cells to recover the virus. Mutation of AUG 7 resulted in a virus (called R2-5NC-14) with a small-plaque phenotype, whereas mutation of the other six AUG codons produced virus with a wild-type plaque morphology. To determine whether the small-plaque phenotype of R2-5NC-14 was due to altered translational efficiency of the viral mRNA, we constructed chimeric mRNAs containing the 5' noncoding region of poliovirus mRNA fused to the chloramphenicol acetyltransferase (CAT) coding sequence. mRNA containing a mutated AUG 7 codon showed decreased translational efficiency in vitro. The results indicate that the upstream ORFs of poliovirus RNA are not essential for viral replication and do not act as barriers to the translation of poliovirus mRNA. AUG 7 and flanking sequences may play a positive acting role in poliovirus RNA translation.     

A poliovirus 2A(pro) mutant unable to cleave 3CD shows inefficient viral protein synthesis and transactivation defects.

Four poliovirus mutants with modifications of tyrosine 88 in 2A(pro) were generated and introduced into the cloned poliovirus genome. Mutants Y88P and Y88L were nonviable, mutant Y88F showed a wild-type (WT) phenotype, and mutant Y88S showed a delayed cytopathic effect and formed small plaques in HeLa cells. Growth of Y88S in HeLa cells was restricted, giving rise to about 20% of the PFU production of the WT poliovirus. The 2A (Y88S) mutant synthesized significantly lower levels of viral proteins in HeLa cells than did the WT poliovirus, while the kinetics of p220 cleavage were identical for both viruses. Strikingly, the 2A (Y88S) mutant was unable to cleave 3CD, as shown by analysis of poliovirus proteins labeled with [35S]methionine or immunoblotted with a specific anti-3C serum. The ability of the Y88S mutant to form infectious virus and cleave 3CD can be complemented by the WT poliovirus. Synthesis of viral RNA was diminished in the Y88S mutant but less than the inhibition of translation of viral RNA. Experiments in which guanidine was used to inhibit poliovirus RNA synthesis suggest that the primary defect of the Y88S mutant virus is at the level of poliovirus RNA translation, while viral genome replication is much less affected. Transfection of HeLa cells infected with the WT poliovirus with a luciferase mRNA containing the poliovirus 5' untranslated sequence gives rise to a severalfold increase in luciferase activity. This enhanced translation of leader-luc mRNA was not observed when the transfected cells were infected with the 2A (Y88S) mutant. Moreover, cotransfection with mRNA encoding WT poliovirus 2A(pro) enhanced translation of leader-luc mRNA. This enhancement was much lower upon transfection with mRNA encoding 2A(Y88S), 2A(Y88L), or 2A(Y88P). These findings support the view that 2A(pro) itself, rather than the 3C' and/or 3D' products, is necessary for efficient translation of poliovirus RNA in HeLa cells.     

Sequences within a small yeast RNA required for inhibition of internal initiation of translation: interaction with La and other cellular proteins influences its inhibitory activity.

We recently reported purification, determination of the nucleotide sequence, and cloning of a 60-nucleotide RNA (I-RNA) from the yeast Saccharomyces cerevisiae which preferentially blocked cap-independent, internal ribosome entry site (IRES)-mediated translation programmed by the poliovirus (PV) 5' untranslated region (UTR). The I-RNA appeared to inhibit IRES-mediated translation by virtue of its ability to bind a 52-kDa polypeptide which interacts with the 5' UTR of viral RNA. We demonstrate here that the HeLa 52-kDa I-RNA-binding protein is immunologically identical to human La autoantigen. Moreover, I-RNA-mediated purified La protein. By using I-RNAs with defined deletions, we have identified sequences of I-RNA required for inhibition of internal initiation of translation. Two smaller fragments of I-RNA (16 and 25 nucleotides) inhibited PV UTR-mediated translation from both monocistronic and bicistronic RNAs. When transfected into HeLa cells, these derivatives of I-RNA inhibited translation of PV RNA. A comparison of protein binding by active and inactive I-RNA mutants demonstrates that in addition to the La protein, three other polypeptides with apparent molecular masses of 80, 70, and 37 kDa may influence the translation-inhibitory activity of I-RNA.     

Internal translation initiation on poliovirus RNA: further characterization of La function in poliovirus translation in vitro.

Initiation of poliovirus RNA translation by internal entry of ribosomes is believed to require the participation of trans-acting factors. The mechanism of action of these factors is poorly defined. The limiting amount of one of these factors, La protein, in rabbit reticulocyte lysates (RRL) has been postulated to partially explain the inefficient translation of poliovirus RNA in this system. To further characterize La activity in translation and to identify other potential limiting factors, we assayed the ability of La protein as well as purified initiation factors, eIF-2, guanine nucleotide exchange factor (GEF), eIF-4A, eIF-4B, eIF-4F, and eIF-3, to stimulate the synthesis of P1, the capsid precursor protein, in poliovirus type 1 (Mahoney) RNA-programmed RRL. Of the proteins tested, only La, GEF, and to some extent eIF-2 stimulated the synthesis of P1. The enhanced translation of P1 in response to La occurred concomitantly with the inhibition of synthesis of most aberrant polypeptides, resulting from initiation in the middle of the genome. Deletion of the carboxy-terminal half (214 amino acids) of La did not decrease its binding to the poliovirus 5' untranslated region but abrogated the stimulatory and correcting activity in translation. In contrast to La, GEF and eIF-2 stimulated the overall translation and increased the synthesis of aberrant products as well as P1. Neither La, GEF, nor any other factor stimulated translation of encephalomyocarditis virus RNA in RRL. The implications of these findings for the mechanism of internal translation initiation on picornavirus RNAs are discussed.     

Minimum internal ribosome entry site required for poliovirus infectivity.

Translation initiation by internal ribosome binding is a recently discovered mechanism of eukaryotic viral and cellular protein synthesis in which ribosome subunits interact with the mRNAs at internal sites in the 5' untranslated RNA sequences and not with the 5' methylguanosine cap structure present at the extreme 5' ends of mRNA molecules. Uncapped poliovirus mRNAs harbor internal ribosome entry sites (IRES) in their long and highly structured 5' noncoding regions. Such IRES sequences are required for viral protein synthesis. In this study, a novel poliovirus was isolated whose genomic RNA contains two gross deletions removing approximately 100 nucleotides from the predicted IRES sequences within the 5' noncoding region. The deletions originated from previously in vivo-selected viral revertants displaying non-temperature-sensitive phenotypes. Each revertant had a different predicted stem-loop structure within the 5' noncoding region of their genomic RNAs deleted. The mutant poliovirus (Se1-5NC-delta DG) described in this study contains both stem-loop deletions in a single RNA genome, thereby creating a minimum IRES. Se1-5NC-delta DG exhibited slow growth and a pinpoint plaque phenotype following infection of HeLa cells, delayed onset of protein synthesis in vivo, and defective initiation during in vitro translation of the mutated poliovirus mRNAs. Interestingly, the peak levels of viral RNA synthesis in cells infected with Se1-5NC-delta DG occurred at slightly later times in infection than those achieved by wild-type poliovirus, but these mutant virus RNAs accumulated in the host cells during the late phases of virus infection. UV cross-linking assays with the 5' noncoding regions of wild-type and mutated RNAs were carried out in cytoplasmic extracts from HeLa cells and neuronal cells and in reticulocyte lysates to identify the cellular factors that interact with the putative IRES elements. The cellular proteins that were cross-linked to the minimum IRES may represent factors playing an essential role in internal translation initiation of poliovirus mRNAs.     

La autoantigen enhances and corrects aberrant translation of poliovirus RNA in reticulocyte lysate.

Translation initiation on poliovirus RNA occurs by internal binding of ribosomes to a sequence within the 5' untranslated region. We have previously characterized a HeLa cell protein, p52, that binds to a fragment of the poliovirus 5' untranslated region (K. Meerovitch, J. Pelletier, and N. Sonenberg, Genes Dev. 3:1026-1034, 1989). Here we report the purification of the HeLa p52. Protein microsequencing identified p52 as La autoantigen. The La protein is a human antigen that is recognized by antibodies from patients with autoimmune disorders such as systemic lupus erythematosus and Sjögren's syndrome. We show that the La protein stimulates translation of poliovirus RNA, but not brome mosaic virus, tobacco mosaic virus, and alfalfa mosaic virus 4 RNA, translation in a reticulocyte lysate. In addition, La corrects aberrant translation of poliovirus RNA in a reticulocyte lysate. Subcellular immunolocalization showed that La protein is mainly nuclear, but after poliovirus infection, La is redistributed to the cytoplasm. Our results suggest that La protein is involved in poliovirus internal initiation of translation and might function through a similar mechanism in the translation of cellular mRNAs.     

Specific interactions of HeLa cell proteins with proposed translation domains of the poliovirus 5'' noncoding region.

To determine which sequences or structures in the poliovirus 5' noncoding region (5'NCR) are involved in binding proteins used for internal ribosome binding and protein synthesis initiation, translation competition assays were performed in rabbit reticulocyte lysates in the presence and absence of HeLa cell extract. The results revealed two functional domains in the poliovirus 5'NCR. One, requiring nucleotides (nts) 457 to 626, binds proteins that are required for translation of all mRNAs and that are present in both reticulocyte lysates and HeLa cell extracts. Another, contained within nts 286 to 456, interacts with proteins that are specific for poliovirus translation and are present in HeLa cells but not in significant amounts in rabbit reticulocyte lysates. In order to detect HeLa cell proteins that interact stably with the 5'NCR of poliovirus, UV cross-linking was used. At least four major protein-RNA complexes were identified, three of which were shown by RNA competition analysis to bind specifically to defined domains within the 5'NCR. Protein A (54 kDa) cross-linked to RNA sequences and/or structures located between nts 457 and 626; proteins B (48 kDa) and C (38 kDa) bound to nts 286 to 456.     

Restriction of translation of capped mRNA in vitro as a model for poliovirus-induced inhibition of host cell protein synthesis: relationship to p220 cleavage.

Poliovirus infection of HeLa cells results in a rapid inhibition of host protein synthesis by a mechanism that does not affect the translation of poliovirus RNA. It has been suggested that this virus-induced translational control results from inactivation of the cap-binding protein complex, and it has been shown that the 220-kilodalton component(s) (p220) of the cap-binding protein complex is cleaved in infected HeLa cells to form antigenically related polypeptides of 100 to 130 kilodaltons. We have previously described an activity in infected cells that specifically restricts translation of capped mRNA in rabbit reticulocyte lysates. Here, we describe further refinements and characterization of restriction assay. We determined that the assay is a good in vitro model for study of host cell shutoff by several criteria: (i) translation was inhibited in both instances at the step involving mRNA binding to ribosomes; (ii) translation of capped mRNA was specifically inhibited, whereas translation of poliovirus RNA was not; (iii) restriction activity appeared in infected cells with kinetics which parallel host cell shutoff; and (iv) restriction activity, like the specific inhibition of host translation, appeared in cells infected in the presence of guanidine-HCl. The restricting activity was partially purified from poliovirus-infected cells and was compared with the virus-induced p220 cleavage activity. Both activities copurified through numerous cell fractionation and biochemical fractionation procedures. However, specific restriction of capped mRNA translation in reticulocyte lysates occurred without complete cleavage of the endogenous p220.     

Sequences within the poliovirus internal ribosome entry segment control viral RNA synthesis.

The 5' untranslated region of poliovirus RNA has been reported to possess two functional elements: (i) the 5' proximal 88 nucleotides form a cloverleaf structure implicated in positive-strand RNA synthesis during viral replication, and (ii) nucleotides 134 to at least 556 function as a highly structured internal ribosome entry segment (IRES) during cap-independent, internal initiation of translation. We show here that the IRES itself is bifunctional and contains sequences necessary for viral RNA synthesis per se. For this purpose, we used a dicistronic poliovirus RNA in which the translation of the viral non-structural (replication) proteins is uncoupled from the poliovirus IRES. In this system, RNA synthesis is readily detectable in transfected cells, even when the poliovirus IRES is inactivated by point mutation. However, deletion of the major part of the poliovirus IRES renders viral-specific RNA synthesis undetectable. Using the same system, we show that a three nucleotide deletion at position 500 in the 5' untranslated region drastically affects both translation efficiency and RNA synthesis. Furthermore, disruption of the secondary structure of the IRES around nucleotide 343 has minimal effects on IRES function, but dramatically reduces viral RNA replication. Taken together, these results provide direct evidence that sequences essential for viral RNA synthesis are located in the 3' region of the poliovirus IRES.     

Dipyridamole reversibly inhibits mengovirus RNA replication

Dipyridamole is an effective inhibitor of cardiovirus growth in cell culture. The effects of dipyridamole on mengovirus replication in vivo and in vitro were examined in the hope the drug could be used as an experimental analog of the poliovirus inhibitor guanidine. Guanidine selectively inhibits poliovirus RNA synthesis but not RNA translation, and as such, has been a valuable research tool. Although guanidine does not inhibit cardiovirus infection, a compound with similar discriminatory characteristics would be experimentally useful for parallel work with these viruses. We found that mengovirus plaque formation in HeLa or L cells was inhibited nearly 100% by the presence of 80 muM dipyridamole. The inhibitory effect was reversible and targeted an early step in the replication cycle. Studies with luciferase-expressing mengovirus replicons showed that viral protein synthesis was unaffected by dipyridamole, and rather, RNA synthesis was the step targeted by the drug. This assessment was confirmed by direct analyses of viral translation and RNA synthesis activities in a Krebs-2-derived in vitro system that supported complete, infectious cardiovirus replication. In Krebs extracts, dipyridamole specifically inhibited viral RNA synthesis to more than 95%, with no concomitant effect on viral protein translation or polyprotein processing. The observed inhibition reversibly affected an early step in both minus-strand and plus-strand RNA synthesis, although inhibition of plus-strand synthesis was more profound than that of minus-strand synthesis. We conclude that dipyridamole is a potent experimental tool that readily distinguishes between cardiovirus translation and RNA replication functions.     

Effects of temperature and lipophilic agents on poliovirus formation and RNA synthesis in a cell-free system.

The translation and primary processing events of poliovirus polyproteins in HeLa cell extracts were more efficient at 34 degrees C than at 30 or 36 degrees C. The cleavage products of P2 such as 2Apro, 2BC, and 2C appeared early in the reaction before the appearance of the cleavage products of P1 and of 3CDpro, an observation suggesting that P2 was cleaved in cis by 3CDpro. Proteolytic processing of the capsid precursor P1 into VP0, VP1, and VP3 was also more efficient at 34 degrees C than at either 30 or 32 degrees C. Surprisingly, processing of 3CDpro to 3Cpro and 3Dpol was almost completely inhibited at 36 degrees C. The synthesis of virus in the cell extract was greatly enhanced at 34 degrees C over that at 30 or 32 degrees C, whereas incubation at 36 degrees C yielded very little virus. Cerulenin, an inhibitor of lipid synthesis, did not appear to affect virus-specific translation or protein processing, but it almost completely inhibited viral synthesis in vitro. Oleic acid drastically inhibited in vitro translation at 100 microM and in vitro poliovirus synthesis at 25 microM. Addition of HeLa cell smooth membranes partially restored translation but not virus formation. Our observations suggest that in vitro translation, proteolytic processing, and virus formation require intact membranes. Analysis of the in vitro translation products revealed that viral RNA polymerase activity increased linearly during incubation of the translation mixture. RNA polymerase in the crude mixture was inhibited by oleic acid but not by cerulenin. Surprisingly, oleic acid had no direct effect on oligo(U)-primed, poly(A)-dependent poly(U) synthesis catalyzed by purified 3Dpol.     

Cell-dependent role for the poliovirus 3' noncoding region in positive-strand RNA synthesis

We previously reported the isolation of a mutant poliovirus lacking the entire genomic RNA 3' noncoding region. Infection of HeLa cell monolayers with this deletion mutant revealed only a minor defect in the levels of viral RNA replication. To further analyze the consequences of the genomic 3' noncoding region deletion, we examined viral RNA replication in a neuroblastoma cell line, SK-N-SH cells. The minor genomic RNA replication defect in HeLa cells was significantly exacerbated in the SK-N-SH cells, resulting in a decreased capacity for mutant virus growth. Analysis of the nature of the RNA replication deficiency revealed that deleting the poliovirus genomic 3' noncoding region resulted in a positive-strand RNA synthesis defect. The RNA replication deficiency in SK-N-SH cells was not due to a major defect in viral translation or viral protein processing. Neurovirulence of the mutant virus was determined in a transgenic mouse line expressing the human poliovirus receptor. Greater than 1,000 times more mutant virus was required to paralyze 50% of inoculated mice, compared to that with wild-type virus. These data suggest that, together with a cellular factor(s) that is limiting in neuronal cells, the poliovirus 3' noncoding region is involved in positive-strand synthesis during genome replication.     

Host cell proteins binding to domain IV of the 5' noncoding region of poliovirus RNA.

Translation of poliovirus RNA occurs by the binding of ribosomes to an internal segment of RNA sequence within the 5' untranslated region of the viral RNA. This region is predicted to consist of six domains (I to VI) that possess complex secondary and tertiary structures. Domain IV is a large region in which alterations in the sequence or structure markedly reduce translational efficiency. In this study, we employed RNA mobility shift assays to demonstrate that a protein(s) from uninfected HeLa cell extracts, as well as from neuroblastoma extracts, interacts with the domain IV structure. A mutation in domain IV caused reduced binding of HeLa cell proteins and reduced translation both in vitro and in vivo, suggesting that the binding of at least one of these proteins plays a role in the mechanism of viral translation. UV cross-linking indicated that a protein(s) with a size of approximately 40 kDa interacted directly with the RNA. Using streptavidin beads to capture biotinylated RNA bound to proteins, we were able to visualize a number of HeLa and neuroblastoma cell proteins that interact with domain IV. These proteins have molecular masses of approximately 39, approximately 40, and approximately 42 kDa.     

Targeting internal ribosome entry site (IRES)-mediated translation to block hepatitis C and other RNA viruses

A number of RNA-containing viruses such as hepatitis C (HCV) and poliovirus (PV) that infect human beings and cause serious diseases use a common mechanism for synthesis of viral proteins, termed internal ribosome entry site (IRES)-mediated translation. This mode of translation initiation involves entry of 40S ribosome internally to the 5' untranslated region (UTR) of viral RNA. Cap-dependent translation of cellular mRNAs, on the other hand, requires recognition of mRNA 5' cap by the translation machinery. In this review, we discuss two inhibitors that specifically inhibit viral IRES-mediated translation without interfering with cellular cap-dependent translation. We present evidence, which suggest that one of these inhibitors, a small RNA (called IRNA) originally isolated from the yeast Saccharomyces cerevisiae, inhibits viral IRES-mediated translation by sequestering both noncanonical transacting factors and canonical initiation factors required for IRES-mediated translation. The other inhibitor, a small peptide from the lupus autoantigen La (called LAP), appears to block binding of cellular transacting factors to viral IRES elements. These results suggest that it might be possible to target viral IRES-mediated translation for future development of therapeutic agents effective against a number of RNA viruses including HCV that exclusively use cap-independent translation for synthesis of viral proteins.     

mRNAs containing the unstructured 5' leader sequence of alfalfa mosaic virus RNA 4 translate inefficiently in lysates from poliovirus-infected HeLa cells.

Poliovirus infection is accompanied by translational control that precludes translation of 5'-capped mRNAs and facilitates translation of the uncapped poliovirus RNA by an internal initiation mechanism. Previous reports have suggested that the capped alfalfa mosaic virus coat protein mRNA (AIMV CP RNA), which contains an unstructured 5' leader sequence, is unusual in being functionally active in extracts prepared from poliovirus-infected HeLa cells (PI-extracts). To identify the cis-acting nucleotide elements permitting selective AIMV CP expression, we tested capped mRNAs containing structured or unstructured 5' leader sequences in addition to an mRNA containing the poliovirus internal ribosome entry site (IRES). Translations were performed with PI-extracts and extracts prepared from mock-infected HeLa cells (MI-extracts). A number of control criteria demonstrated that the HeLa cells were infected by poliovirus and that the extracts were translationally active. The data strongly indicate that translation of RNAs lacking an internal ribosome entry site, including AIMV CP RNA, was severely compromised in PI-extracts, and we find no evidence that the unstructured AIMV CP RNA 5' leader sequence acts in cis to bypass the poliovirus translational control. Nevertheless, cotranslation assays in the MI-extracts demonstrate that mRNAs containing the unstructured AIMV CP RNA 5' untranslated region have a competitive advantage over those containing the rabbit alpha-globin 5' leader. Previous reports of AIMV CP RNA translation in PI-extracts likely describe inefficient expression that can be explained by residual cap-dependent initiation events, where AIMV CP RNA translation is competitive because of a diminished quantitative requirement for initiation factors.     

Attenuation stem-loop lesions in the 5' noncoding region of poliovirus RNA: neuronal cell-specific translation defects.

The nucleotide at position 480 in the 5' noncoding region of the viral RNA genome plays an important role in directing the attenuation phenotype of the Sabin vaccine strain of poliovirus type 1. In vitro translation studies have shown that the attenuated viral genomes of the Sabin strains direct levels of viral protein synthesis lower than those of their neurovirulent counterparts. We previously described the isolation of pseudorevertant polioviruses derived from transfections of HeLa cells with genome-length RNA harboring an eight-nucleotide lesion in a stem-loop structure (stem-loop V) that contains the attenuation determinant at position 480 (A. A. Haller and B. L. Semler, J. Virol. 66:5075-5086, 1992). This stem-loop structure is a major component of the poliovirus internal ribosome entry site required for initiation of viral protein synthesis. The eight-nucleotide lesion (X472) was lethal for virus growth and gave rise only to viruses which had partially reverted nucleotides within the original substituted sequences. In this study, we analyzed two of the poliovirus revertants (X472RI and X472R2) for cell-type-specific growth properties. The X472RI and X472R2 RNA templates directed protein synthesis to wild-type levels in in vitro translation reaction mixtures supplemented with crude cytoplasmic HeLa cell extracts. In contrast, the same X472 revertant RNAs displayed a decreased translation initiation efficiency when translated in a cell-free system supplemented with extracts from neuronal cells. This translation initiation defect of the X472R templates correlated with reduced yields of infectious virus particles in neuronal cells compared with those obtained from HeLa cells infected with the X472 poliovirus revertants. Our results underscore the important of RNA secondary structures within the poliovirus internal ribosome entry site in directing translation initiation and suggest that such structures interact with neuronal cell factors in a specific manner.     

5' cloverleaf in poliovirus RNA is a cis-acting replication element required for negative-strand synthesis

A cloverleaf structure at the 5' terminus of poliovirus RNA binds viral and cellular proteins. To examine the role of the cloverleaf in poliovirus replication, we determined how cloverleaf mutations affected the stability, translation and replication of poliovirus RNA in HeLa S10 translation-replication reactions. Mutations within the cloverleaf destabilized viral RNA in these reactions. Adding a 5' 7-methyl guanosine cap fully restored the stability of the mutant RNAs and had no effect on their translation. These results indicate that the 5' cloverleaf normally protects uncapped poliovirus RNA from rapid degradation by cellular nucleases. Preinitiation RNA replication complexes formed with the capped mutant RNAs were used to measure negative-strand synthesis. Although the mutant RNAs were stable and functional mRNAs, they were not active templates for negative-strand RNA synthesis. Therefore, the 5' cloverleaf is a multifunctional cis-acting replication element required for the initiation of negative-strand RNA synthesis. We propose a replication model in which the 5' and 3' ends of viral RNA interact to form a circular ribonucleoprotein complex that regulates the stability, translation and replication of poliovirus RNA.     

Interaction of cellular proteins with the 5' end of Norwalk virus genomic RNA

The lack of a susceptible cell line and an animal model for Norwalk virus (NV) infection has prompted the development of alternative strategies to generate in vitro RNAs that approximate the authentic viral genome. This approach has allowed the study of viral RNA replication and gene expression. In this study, using mobility shift and cross-linking assays, we detected several cellular proteins from HeLa and CaCo-2 cell extracts that bind to, and form stable complexes with, the first 110 nucleotides of the 5' end of NV genomic RNA, a region previously predicted to form a double stem-loop structure. These proteins had molecular weights similar to those of the HeLa cellular proteins that bind to the internal ribosomal entry site of poliovirus RNA. HeLa proteins La, PCBP-2, and PTB, which are important for poliovirus translation, and hnRNP L, which is possibly implicated in hepatitis C virus translation, interact with NV RNA. These protein-RNA interactions are likely to play a role in NV translation and/or replication.