Interactions of viral protein 3CD and poly(rC) binding protein with the 5' untranslated region of the poliovirus genome

The poly(rC) binding protein (PCBP) is a cellular protein required for poliovirus replication. PCBP specifically interacts with two domains of the poliovirus 5' untranslated region (5'UTR), the 5' cloverleaf structure, and the stem-loop IV of the internal ribosome entry site (IRES). Using footprinting analysis and site-directed mutagenesis, we have mapped the RNA binding site for this cellular protein within the stem-loop IV domain. A C-rich sequence in a loop at the top of this large domain is required for PCBP binding and is crucial for viral translation. PCBP binds to stem-loop IV RNA with six-times-higher affinity than to the 5' cloverleaf structure. However, the binding of the viral protein 3CD (precursor of the viral protease 3C and the viral polymerase 3D) to the cloverleaf RNA dramatically increases the affinity of PCBP for this RNA element. The viral protein 3CD binds to the cloverleaf RNA but does not interact directly with stem-loop IV nor with other RNA elements of the viral IRES. Our results indicate that the interactions of PCBP with the poliovirus 5'UTR are modulated by the viral protein 3CD.     

Distinct poly(rC) binding protein KH domain determinants for poliovirus translation initiation and viral RNA replication

The limited coding capacity of picornavirus genomic RNAs necessitates utilization of host cell factors in the completion of an infectious cycle. One host protein that plays a role in both translation initiation and viral RNA synthesis is poly(rC) binding protein 2 (PCBP2). For picornavirus RNAs containing type I internal ribosome entry site (IRES) elements, PCBP2 binds the major stem-loop structure (stem-loop IV) in the IRES and is essential for translation initiation. Additionally, the binding of PCBP2 to the 5'-terminal stem-loop structure (stem-loop I or cloverleaf) in concert with viral protein 3CD is required for initiation of RNA synthesis directed by poliovirus replication complexes. PCBP1, a highly homologous isoform of PCBP2, binds to poliovirus stem-loop I with an affinity similar to that of PCBP2; however, PCBP1 has reduced affinity for stem-loop IV. Using a dicistronic poliovirus RNA, we were able to functionally uncouple translation and RNA replication in PCBP-depleted extracts. Our results demonstrate that PCBP1 rescues RNA replication but is not able to rescue translation initiation. We have also generated mutated versions of PCBP2 containing site-directed lesions in each of the three RNA-binding domains. Specific defects in RNA binding to either stem-loop I and/or stem-loop IV suggest that these domains may have differential functions in translation and RNA replication. These predictions were confirmed in functional assays that allow separation of RNA replication activities from translation. Our data have implications for differential picornavirus template utilization during viral translation and RNA replication and suggest that specific PCBP2 domains may have distinct roles in these activities.     

Interaction of Poly(rC) Binding Protein 2 with the 5′ Noncoding Region of Hepatitis A Virus RNA and Its Effects on Translation

Utilization of internal ribosome entry segment (IRES) structures in the 5′ noncoding region (5′NCR) of picornavirus RNAs for initiation of translation requires a number of host cell factors whose distribution may vary in different cells and whose requirement may vary for different picornaviruses. We have examined the requirement of the cellular protein poly(rC) binding protein 2 (PCBP2) for hepatitis A virus (HAV) RNA translation. PCBP2 has recently been identified as a factor required for translation and replication of poliovirus (PV) RNA. PCBP2 was shown to be present in FRhK-4 cells, which are permissive for growth of HAV, as it is in HeLa cells, which support translation of HAV RNA but which have not been reported to host replication of the virus. Competition RNA mobility shift assays showed that the 5′NCR of HAV RNA competed for binding of PCBP2 with a probe representing stem-loop IV of the PV 5′NCR. The binding site on HAV RNA was mapped to nucleotides 1 to 157, which includes a pyrimidine-rich sequence. HeLa cell extracts that had been depleted of PCBP2 by passage over a PV stem-loop IV RNA affinity column supported only low levels of HAV RNA translation. Translation activity was restored upon addition of recombinant PCBP2 to the depleted extract. Removal of the 5′-terminal 138 nucleotides of the HAV RNA, or removal of the entire IRES, eliminated the dependence of HAV RNA translation on PCBP2.     

NRF IRES activity is mediated by RNA binding protein JKTBP1 and a 14-nt RNA element

The mRNA of human NF-kappaB repressing factor (NRF) contains a long 5'-untranslated region (UTR) that directs ribosomes to the downstream start codon by a cap-independent mechanism. Comparison of the nucleotide (nt) sequences of human and mouse NRF mRNAs reveals a high degree of identity throughout a fragment of 150 nt proximal to the start codon. Here, we show that this region constitutes a minimal internal ribosome entry segment (IRES) module. Enzymatic RNA structure analysis reveals a secondary structure model of the NRF IRES module. Point mutation analysis of the module determines a short, 14-nt RNA element (nt 640-653) as a mediator of IRES function. Purification of IRES binding cellular proteins and subsequent ESI/MS/MS sequence analysis led to identification of the RNA-binding protein, JKTBP1. EMSA experiments show that JKTBP1 binds upstream to the 14-nt RNA element in the NRF IRES module (nt 579-639). Over-expression of JKTBP1 significantly enhances activity of the NRF IRES module in dicistronic constructs. Moreover, siRNA experiments demonstrate that down-regulation of endogenous JKTBP1 decreases NRF IRES activity and the level of endogenous NRF protein. The data of this study show that JKTBP1 and the 14-nt element act independently to mediate NRF IRES activity.     

Bag-1 internal ribosome entry segment activity is promoted by structural changes mediated by poly(rC) binding protein 1 and recruitment of polypyrimidine tract binding protein 1

We have shown previously that an internal ribosome entry segment (IRES) directs the synthesis of the p36 isoform of Bag-1 and that polypyrimidine tract binding protein 1 (PTB-1) and poly(rC) binding protein 1 (PCBP1) stimulate IRES-mediated translation initiation in vitro and in vivo. Here, a secondary structural model of the Bag-1 IRES has been derived by using chemical and enzymatic probing data as constraints on the RNA folding algorithm Mfold. The ribosome entry window has been identified within this structural model and is located in a region in which many residues are involved in base-pairing interactions. The interactions of PTB-1 and PCBP1 with their cognate binding sites on the IRES disrupt many of the RNA-RNA interactions, and this creates a largely unstructured region of approximately 40 nucleotides that could permit ribosome binding. Mutational analysis of the PTB-1 and PCBP1 binding sites suggests that PCBP1 acts as an RNA chaperone to open the RNA in the vicinity of the ribosome entry window while PTB-1 is probably an essential part of the preinitiation complex.     

Genetic analysis of a poliovirus/hepatitis C virus (HCV) chimera: interaction between the poliovirus cloverleaf and a sequence in the HCV 5' nontranslated region results in a replication phenotype

Internal ribosomal entry sites (IRESs) can function in foreign viral genomes or in artificial dicistronic mRNAs. We describe an interaction between the wild-type hepatitis C virus (HCV)-specific sequence and the poliovirus (PV) 5'-terminal cloverleaf in a PV/HCV chimeric virus (containing the HCV IRES), resulting in a replication phenotype. Either a point mutation at nucleotide (nt) 29 or a deletion up to nt 40 in the HCV 5' nontranslated region relieved the replication block, yielding PV/HCV variants replicating to high titers. Fortuitous yet crippling interactions between an IRES and surrounding heterologous RNA must be considered when IRES-based dicistronic expression vectors are being constructed.     

Poly(C)-binding protein 2 interacts with sequences required for viral replication in the hepatitis C virus (HCV) 5' untranslated region and directs HCV RNA replication through circularizing the viral genome

Sequences in the 5' untranslated region (5'UTR) of hepatitis C virus (HCV) RNA is important for modulating both translation and RNA replication. The translation of the HCV genome depends on an internal ribosome entry site (IRES) located within the 341-nucleotide 5'UTR, while RNA replication requires a smaller region. A question arises whether the replication and translation functions require different regions of the 5'UTR and different sets of RNA-binding proteins. Here, we showed that the 5'-most 157 nucleotides of HCV RNA is the minimum 5'UTR for RNA replication, and it partially overlaps with the IRES. Stem-loops 1 and 2 of the 5'UTR are essential for RNA replication, whereas stem-loop 1 is not required for translation. We also found that poly(C)-binding protein 2 (PCBP2) bound to the replication region of the 5'UTR and associated with detergent-resistant membrane fractions, which are the sites of the HCV replication complex. The knockdown of PCBP2 by short hairpin RNA decreased the amounts of HCV RNA and nonstructural proteins. Antibody-mediated blocking of PCBP2 reduced HCV RNA replication in vitro, indicating that PCBP2 is directly involved in HCV RNA replication. Furthermore, PCBP2 knockdown reduced IRES-dependent translation preferentially from a dual reporter plasmid, suggesting that PCBP2 also regulated IRES activity. These findings indicate that PCBP2 participates in both HCV RNA replication and translation. Moreover, PCBP2 interacts with HCV 5'- and 3'UTR RNA fragments to form an RNA-protein complex and induces the circularization of HCV RNA, as revealed by electron microscopy. This study thus demonstrates the mechanism of the participation of PCBP2 in HCV translation and replication and provides physical evidence for HCV RNA circularization through 5'- and 3'UTR interaction.     

Polypyrimidine tract binding protein and poly r(C) binding protein 1 interact with the BAG-1 IRES and stimulate its activity in vitro and in vivo

The 5′-untranslated region of Bag-1 mRNA contains an internal ribosome entry segment (IRES) and the translation of Bag-1 protein can be initiated by both cap-dependent and cap-independent mechanisms. In general, cellular IRESs require non-canonical trans-acting factors for their activity, however, very few of the proteins that act on cellular IRESs have been identified. Proteins that interact with viral IRESs have also been shown to stimulate the activity of cellular IRESs and therefore the ability of a range of known viral trans-acting factors to stimulate the Bag-1 IRES was tested. Two proteins, poly r(C) binding protein 1 (PCBP1) and polypyrimidine tract binding protein (PTB), were found to increase the activity of the Bag-1 IRES in vitro and in vivo. The regions of the Bag-1 IRES RNA to which they bind have been determined, and it was shown that PCBP1 binds to a short 66 nt section of RNA, whilst PTB interacts with a number of sites over a larger area. The minimum section of the RNA that still retained activity was determined and both PCBP1 and PTB interacted with this region suggesting that these proteins are essential for Bag-1 IRES function.     

Poly(rC) binding proteins mediate poliovirus mRNA stability

The 5'-terminal 88 nt of poliovirus RNA fold into a cloverleaf RNA structure and form ribonucleoprotein complexes with poly(rC) binding proteins (PCBPs; AV Gamarnik, R Andino, RNA, 1997, 3:882-892; TB Parsley, JS Towner, LB Blyn, E Ehrenfeld, BL Semler, RNA, 1997, 3:1124-1134). To determine the functional role of these ribonucleoprotein complexes in poliovirus replication, HeLa S10 translation-replication reactions were used to quantitatively assay poliovirus mRNA stability, poliovirus mRNA translation, and poliovirus negative-strand RNA synthesis. Ribohomopoly(C) RNA competitor rendered wild-type poliovirus mRNA unstable in these reactions. A 5'-terminal 7-methylguanosine cap prevented the degradation of wild-type poliovirus mRNA in the presence of ribohomopoly(C) competitor. Ribohomopoly(A), -(G), and -(U) did not adversely affect poliovirus mRNA stability. Ribohomopoly(C) competitor RNA inhibited the translation of poliovirus mRNA but did not inhibit poliovirus negative-strand RNA synthesis when poliovirus replication proteins were provided in trans using a chimeric helper mRNA possessing the hepatitis C virus IRES. A C24A mutation prevented UV crosslinking of PCBPs to 5' cloverleaf RNA and rendered poliovirus mRNA unstable. A 5'-terminal 7-methylguanosine cap blocked the degradation of C24A mutant poliovirus mRNA. The C24A mutation did not inhibit the translation of poliovirus mRNA nor diminish viral negative-strand RNA synthesis relative to wild-type RNA. These data support the conclusion that poly(rC) binding protein(s) mediate the stability of poliovirus mRNA by binding to the 5'-terminal cloverleaf structure of poliovirus mRNA. Because of the general conservation of 5' cloverleaf RNA sequences among picornaviruses, including C24 in loop b of the cloverleaf, we suggest that viral mRNA stability of polioviruses, coxsackieviruses, echoviruses, and rhinoviruses is mediated by interactions between PCBPs and 5' cloverleaf RNA.     

Poly (rC) binding protein 2 forms a ternary complex with the 5'-terminal sequences of poliovirus RNA and the viral 3CD proteinase.

Poly(rC) binding protein 2 (PCBP2) forms a specific ribonucleoprotein (RNP) complex with the 5'-terminal sequences of poliovirus genomic RNA, as determined by electrophoretic mobility shift assay. Mutational analysis showed that binding requires the wild-type nucleotide sequence at positions 20-25. This sequence is predicted to localize to a specific stem-loop within a cloverleaf-like secondary structure element at the 5'-terminus of the viral RNA. Addition of purified poliovirus 3CD to the PCBP2/RNA binding reaction results in the formation of a ternary complex, whose electrophoretic mobility is further retarded. These properties are consistent with those described for the unidentified cellular protein in the RNP complex described by Andino et al. (Andino R, Rieckhof GE, Achacoso PL, Baltimore D, 1993, EMBO J 12:3587-3598). Dicistronic RNAs containing mutations in the 5' cloverleaf-like structure of poliovirus that abate PCBP2 binding show a decrease in RNA replication and translation of gene products directed by the poliovirus 5' noncoding region in vitro, suggesting that the interaction of PCBP2 with these sequences performs a dual role in the virus life cycle by facilitating both viral protein synthesis and initiation of viral RNA synthesis.     

Effect of mutations downstream of the internal ribosome entry site on initiation of poliovirus protein synthesis.

Initiation of poliovirus translation is mediated by a large, structured segment of the 5' nontranslated region known as the internal ribosome entry site (IRES) and normally occurs 155 nucleotides (nt) downstream of the IRES at AUG743 (the AUG at nucleotide 743). Functional AUG codons introduced at nt 611 or 614 reduced initiation at AUG743 by 10 to 40% in vitro but had no effect on virus phenotype. To investigate the role of the nt 586-743 spacer in greater detail, four intervening termination codons were removed, and an additional AUG triplet at nt 683 was introduced by nucleotide substitution. Initiation at AUG743 was reduced by only 50 to 80%, depending on the number of upstream initiation codons. Initiation at AUG743 was also reduced following insertion of a stable hairpin at nt 630, but the reduction was modest in an ascites carcinoma cell extract. Initiation was more frequent at AUG743 than at AUG683 if mRNAs contained either an upstream initiation codon or the stable hairpin. These results suggested that not all initiation events at AUG743 can be accounted for by a scanning-dependent mechanism. Translation of bicistronic mRNAs in which the intercistronic spacer contained nt 630 to 742 of the poliovirus 5' nontranslated region indicated that these residues are not able to act as an entry point for ribosomes independently of the IRES. Insertion of increasingly longer sequences immediately downstream of the stable hairpin progressively reduced initiation at AUG743 without affecting initiation at AUG683. These results are discussed in terms of a model for initiation of poliovirus translation in which a complex RNA superstructure upstream of nt 586 promotes ribosome binding at an entry point determined by specific downstream cis-acting elements.     

Replication of poliovirus RNA with complete internal ribosome entry site deletions

cis-acting RNA sequences and structures in the 5' and 3' nontranslated regions of poliovirus RNA interact with host translation machinery and viral replication proteins to coordinately regulate the sequential translation and replication of poliovirus RNA. The poliovirus internal ribosome entry site (IRES) in the 5' nontranslated region (NTR) has been implicated as a cis-active RNA required for both viral mRNA translation and viral RNA replication. To evaluate the role of the IRES in poliovirus RNA replication, we exploited the advantages of cell-free translation-replication reactions and preinitiation RNA replication complexes. Genetic complementation with helper mRNAs allowed us to create preinitiation RNA replication complexes containing RNA templates with defined deletions in the viral open reading frame and the IRES. A series of deletions revealed that no RNA elements of either the viral open reading frame or the IRES were required in cis for negative-strand RNA synthesis. The IRES was dispensable for both negative- and positive-strand RNA syntheses. Intriguingly, although small viral RNAs lacking the IRES replicated efficiently, the replication of genome length viral RNAs was stimulated by the presence of the IRES. These results suggest that RNA replication is not directly dependent on a template RNA first functioning as an mRNA. These results further suggest that poliovirus RNA replication is not absolutely dependent on any protein-RNA interactions involving the IRES.     

Differential utilization of poly(rC) binding protein 2 in translation directed by picornavirus IRES elements

The translation of picornavirus genomic RNAs occurs by a cap-independent mechanism that requires the formation of specific ribonucleoprotein complexes involving host cell factors and highly structured regions of picornavirus 5' noncoding regions known as internal ribosome entry sites (IRES). Although a number of cellular proteins have been shown to be involved in picornavirus RNA translation, the precise role of these factors in picornavirus internal ribosome entry is not understood. In this report, we provide evidence for the existence of distinct mechanisms for the internal initiation of translation between type I and type II picornavirus IRES elements. In vitro translation reactions were conducted in HeLa cell cytoplasmic translation extracts that were depleted of the cellular protein, poly(rC) binding protein 2 (PCBP2). Upon depletion of PCBP2, these extracts possessed a significantly diminished capacity to translate reporter RNAs containing the type I IRES elements of poliovirus, coxsackievirus, or human rhinovirus linked to luciferase; however, the addition of recombinant PCBP2 could reconstitute translation. Furthermore, RNA electrophoretic mobility-shift analysis demonstrated specific interactions between PCBP2 and both type I and type II picornavirus IRES elements; however, the translation of reporter RNAs containing the type II IRES elements of encephalomyocarditis virus and foot-and-mouth disease virus was not PCBP2 dependent. These data demonstrate that PCBP2 is essential for the internal initiation of translation on picornavirus type I IRES elements but is dispensable for translation directed by the structurally distinct type II elements.     

Two functional complexes formed by KH domain containing proteins with the 5' noncoding region of poliovirus RNA.

The 5' noncoding region of the poliovirus genome contains RNA structures important for replication and translation. Here we show that two closely related cellular poly(rC) binding proteins (PCBP1 and PCBP2) bind to the terminal cloverleaf structure and facilitate the interaction of the viral protein 3CD (the uncleaved precursor of the protease-polymerase). In addition, these cellular proteins bind to stem-loop IV of the internal ribosomal entry site. The proteins are cytoplasmic and largely associated with ribosomes; they appear to dimerize in solution and to form heterodimers when binding to stem-loop IV. Initiation of viral translation in Xenopus oocytes is strongly inhibited by co-injection of specific antibodies directed against PCBP1 or PCBP2, indicating that the poly(rC) binding proteins may facilitate this process. Furthermore, PCPB-depleted HeLa extracts translate poliovirus RNA inefficiently and the activity is partially restored by addition of recombinant PCBP proteins.     

Poly(rC)-binding protein 2 interacts with the oligo(rC) tract of coxsackievirus B3

The human poly(rC)-binding protein (PCBP) 2 is known to interact with enteroviral RNA. Here, the interaction of PCBP2 with RNA target sequences at the 5′ end of the coxsackievirus B3 genome was investigated. Using the electrophoretic mobility shift assay and the yeast three-hybrid system, a short oligo(rC) tract connecting cloverleaf and IRES is demonstrated to contribute to PCBP2 binding. This oligo(rC) tract is conserved among entero- and rhinoviruses. In absence of the viral 3C proteinase, an extended cloverleaf RNA (nt 1-105) containing the oligo(rC) tract interacts with PCBP2 whereas the cloverleaf (nt 1-87) lacking the oligo(rC) tract does not. In the presence of 3C proteinase, cloverleaf RNA (1-87) interacts with PCBP2.     

Mutation of a single conserved nucleotide between the cloverleaf and internal ribosome entry site attenuates poliovirus neurovirulence

The chemical synthesis of poliovirus (PV) cDNA combined with the cell-free synthesis of infectious particles yielded virus whose mouse neurovirulence was highly attenuated (J. Cello, A. V. Paul, and E. Wimmer, Science 297:1016-1018, 2002). Compared to the wild-type PV1 (Mahoney) [PV1(M)] sequence, the synthetic virus genome harbored 27 nucleotide (nt) changes deliberately introduced as genetic markers. Of the 27 nucleotide substitutions, the UA-to-GG exchanges at nucleotides 102/103, mapping to a region between the cloverleaf and the internal ribosome entry site (IRES) in the 5'-nontranslated region, were found to be involved in the observed attenuation phenotype in mice. The UA/GG mutation at nt 102/103 in the synthetic PV1(M) [sPV1(M)] background conferred also a ts phenotype of replication to the virus in human neuroblastoma cells. Conversely, the exchange of GG to wild-type (wt) UA at 102/103 in an sPV1(M) background restored wt neurovirulence in CD155 transgenic (tg) mice and suppressed the ts phenotype in SK-N-MC cells. All poliovirus variants replicated well in HeLa cells at the two temperatures, regardless of the sequence at the 102/103 locus. Analyses of variants isolated from sPV(M)-infected CD155 tg mice revealed that the G(102)G(103)-to-G(102)A(103) reversion alone reestablished the neurovirulent phenotype. This suggests that a single mutation is responsible for the observed change of the neurovirulence phenotype. sPV1(M) RNA is translated in cell extracts of SK-N-MC cells with significantly lower efficiency than PV1(M) RNA or sPV1(M) RNA with a G(102)-to-A(102) reversion. These studies suggest a function for the conserved nucleotide (A(103)) located between the cloverleaf and the IRES which is important for replication of PV in the central nervous system of CD155 tg mice and in human cells of neuronal origin.     

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.     

Multimerization of poly(rC) binding protein 2 is required for translation initiation mediated by a viral IRES

The cellular protein, poly(rC) binding protein 2 (PCBP2), is known to function in picornavirus cap-independent translation. We have further examined the RNA binding properties and protein-protein interactions of PCBP2 necessary for translation. We have studied its putative multimerization properties utilizing the yeast two-hybrid assay and in vitro biochemical methods, including glutathione S-transferase (GST) pull-down assays and gel filtration. Through genetic analysis, the multimerization domain has been localized to the second K-homologous (KH) RNA binding domain of the protein between amino acids 125 and 158. To examine the function of multimerization in poliovirus translation, we utilized the truncated protein, DeltaKH1-PCBP2, which is capable of multimer formation, but does not bind poliovirus stem-loop IV RNA (an interaction required for translation). Utilizing RNA binding and in vitro translation assays, this protein was shown to act as a dominant negative, suggesting that PCBP2 multimerization functions in poliovirus translation and RNA binding. Additionally, PCBP2 containing a deletion in the multimerization domain (DeltaKH2-PCBP2) was not able to bind poliovirus stem-loop IV RNA and could not rescue translation in extracts that were depleted of endogenous PCBP2. Results from these experiments suggest that the multimerization of PCBP2 is required for efficient RNA binding and cap-independent translation of poliovirus RNA. By examining the functional interactions of the cellular protein PCBP2, we have discovered a novel determinant in the mechanism of picornavirus cap-independent translation.     

The N-terminal K homology domain of the poly(rC)-binding protein is a major determinant for binding to the poliovirus 5'-untranslated region and acts as an inhibitor of viral translation

The poly(rC)-binding proteins (PCBP1 and PCBP2) are RNA-binding proteins whose RNA recognition motifs are composed of three K homology (KH) domains. These proteins are involved in both the stabilization and translational regulation of several cellular and viral RNAs. PCBP1 and PCBP2 specifically interact with both the 5'-element known as the cloverleaf structure and the large stem-loop IV RNA of the poliovirus 5'-untranslated region. We have found that the first KH domain of PCBP2 (KH1) specifically interacts with the viral RNAs, and together with viral protein 3CD, KH1 forms a high affinity ternary ribonucleoprotein complex with the cloverleaf RNA, resembling the full-length PCBP protein. Furthermore, KH1 acts as a dominant-negative mutant to inhibit translation from a poliovirus reporter gene in both Xenopus laevis oocytes and HeLa cell in vitro translation extracts.     

Functional analysis of RNA binding by the hepatitis C virus RNA-dependent RNA polymerase

Protein-RNA interaction plays a critical role in regulating RNA synthesis by the hepatitis C virus (HCV) RNA-dependent RNA polymerase (RdRp). RNAs of 7 nucleotides (nt) or longer had affinities 5-fold better than an RNA of 5 nt, suggesting a minimal length required for binding. To identify RNA contact sites on the HCV RdRp, a biotinylated 7-nt RNA capable of directing de novo initiation was used in a process that coupled reversible formaldehyde cross-linking, RNA affinity chromatography, and mass spectrometry. By this process, we identified 18 peptides cross-linked to the 7-nt RNA. When these identified peptides were overlaid on the three-dimensional structures of NS5B, most mapped to the fingers subdomain, connecting loops between fingers and thumb subdomains and in the putative RNA binding channel. Two of the identified peptides resided in the active site cavity of the RdRp. Recombinant HCV RdRp with single residue changes in likely RNA contact sites were generated and characterized for effects on HCV RdRp activity. Mutant proteins had significant effects on cross-linking to 7-nt RNA and reduced RNA synthesis in vitro by 2- to 20-fold compared with wild type protein. When the mutations were tested for the replication of HCV RNA in the context of the cells transfected with the HCV subgenomic replicon, all except one prevented colony formation, indicating a defect in HCV RNA replication. These biochemical and functional analyses identified a number of residues in the HCV RdRp that are important for HCV RNA synthesis.