Picornavirus genome replication: assembly and organization of the VPg uridylylation ribonucleoprotein (initiation) complex

All picornaviruses have a protein, VPg, covalently linked to the 5'-ends of their genomes. Uridylylated VPg (VPg-pUpU) is thought to serve as the protein primer for RNA synthesis. VPg-pUpU can be produced in vitro by the viral polymerase, 3Dpol, in a reaction in which a single adenylate residue of a stem-loop structure, termed oriI, templates processive incorporation of UMP into VPg by using a "slide-back" mechanism. This reaction is greatly stimulated by viral precursor protein 3CD or its processed derivative, 3C; both contain RNA-binding and protease activities. We show that the 3C domain encodes specificity for oriI, and the 3D domain enhances the overall affinity for oriI. Thus, 3C(D) stimulation exhibits an RNA length dependence. By using a minimal system to evaluate the mechanism of VPg uridylylation, we show that the active complex contains polymerase, oriI, and 3C(D) at stoichiometry of 1:1:2. Dimerization of 3C(D) is supported by physical and structural data. Polymerase recruitment to and retention in this complex require a protein-protein interaction between the polymerase and 3C(D). Physical and functional data for this interaction are provided for three picornaviruses. VPg association with this complex is weak, suggesting that formation of a complex containing all necessary components of the reaction is rate-limiting for the reaction. We suggest that assembly of this complex in vivo would be facilitated by use of precursor proteins instead of processed proteins. These data provide a glimpse into the organization of the ribonucleoprotein complex that catalyzes this key step in picornavirus genome replication.     

Picornavirus genome replication. Identification of the surface of the poliovirus (PV) 3C dimer that interacts with PV 3Dpol during VPg uridylylation and construction of a structural model for the PV 3C2-3Dpol complex

Picornaviruses have a peptide termed VPg covalently linked to the 5'-end of the genome. Attachment of VPg to the genome occurs in at least two steps. First, Tyr-3 of VPg, or some precursor thereof, is used as a primer by the viral RNA-dependent RNA polymerase, 3Dpol, to produce VPg-pUpU. Second, VPg-pUpU is used as a primer to produce full-length genomic RNA. Production of VPg-pUpU is templated by a single adenylate residue located in the loop of an RNA stem-loop structure termed oriI by using a slide-back mechanism. Recruitment of 3Dpol to and its stability on oriI have been suggested to require an interaction between the back of the thumb subdomain of 3Dpol and an undefined region of the 3C domain of viral protein 3CD. We have performed surface acidic-to-alanine-scanning mutagenesis of 3C to identify the surface of 3C with which 3Dpol interacts. This analysis identified numerous viable poliovirus mutants with reduced growth kinetics that correlated to reduced kinetics of RNA synthesis that was attributable to a change in VPg-pUpU production. Importantly, these 3C derivatives were all capable of binding to oriI as well as wild-type 3C. Synthetic lethality was observed for these mutants when placed in the context of a poliovirus mutant containing 3Dpol-R455A, a residue on the back of the thumb required for VPg uridylylation. These data were used to guide molecular docking of the structures for a poliovirus 3C dimer and 3Dpol, leading to a structural model for the 3C(2)-3Dpol complex that extrapolates well to all picornaviruses.     

Analysis of RNA synthesis of type 1 poliovirus by using an in vitro molecular genetic approach.

Membranous crude replication complexes (CRC) were isolated from poliovirus-infected HeLa cells as recently described (N. Takeda, R.J. Kuhn, C.-F. Yang, T. Takegami, and E. Wimmer, J. Virol. 60:43-53, 1986). Viruses used to produce the CRC were poliovirus type 1 (Mahoney), [PV-1(M)], poliovirus type 1 (Sabin) [PV-1(S)], and four in vitro recombinants that were constructed from infectious cDNA clones. RNA synthesis in CRC was studied. No end-linked, full-length double-stranded poliovirus RNA was detected in CRC regardless of whether nonionic detergent (Nonidet P-40) was added prior to incubation. Synthesis of VPg-pU and VPg-pUpU, two nucleotidyl proteins presumed to be involved in the initiation of RNA synthesis, was slower at 30 degrees C in CRC induced by PV-1(S) than by PV-1(M). This observation was used to design a pulse-chase experiment whose result suggested that synthesis of VPg-pUpU occurred by uridylylation of VPg-pU. Synthesis of VPg-pU(pU) was thermosensitive in CRC induced by PV-1(S). With CRC of recombinant viruses, the thermosensitive block covaried to nucleotide substitutions in PV-1(S) that mapped to the virus-induced RNA polymerase 3Dpol. We conclude that plus-stranded RNA synthesis in CRC does not proceed via hairpin structures. The results of VPg-pU----VPg-pUpU synthesis are consistent with a model in which VPg-pU is the primer of RNA synthesis mediated by 3Dpol. The data suggest that uridylylation of VPg or a precursor thereof may be catalyzed by 3Dpol itself, a mechanism resembling events occurring in adenovirus DNA replication.     

Genetic evidence for an interaction between a picornaviral cis-acting RNA replication element and 3CD protein

Internally located, cis-acting RNA replication elements, termed cres, are essential for replication of the genomes of picornaviruses such as human rhinovirus 14 (HRV-14) and poliovirus because they template uridylylation of the protein primer, VPg, by the polymerase 3D(pol). These cres form stem-loop structures sharing a common loop motif, and the HRV-14 cre can substitute functionally for the poliovirus cre in both uridylylation in vitro and RNA replication in vivo. We show, however, that the poliovirus cre is unable to support HRV-14 RNA replication. This lack of complementation maps to the stem of the poliovirus cre and was reversed by single nucleotide substitutions in the stem as well as the base of the loop. Replication-competent, revertant viruses rescued from dicistronic HRV-14 RNAs containing the poliovirus cre, or a chimeric cre containing the poliovirus stem, contained adaptive amino acid substitutions. These mapped to the surface of both the polymerase 3D(pol), at the tip of the "thumb" domain, and the protease 3C(pro), on the side opposing the active site and near the end of an extended strand segment implicated previously in RNA binding. These mutations substantially enhanced replication competence when introduced into HRV-14 RNAs containing the poliovirus cre, and they were additive in their effects. The data support a model in which 3CD or its derivatives 3C(pro) and 3D(pol) interact directly with the stem of the cre during uridylylation of VPg.     

Role of RNA structure and RNA binding activity of foot-and-mouth disease virus 3C protein in VPg uridylylation and virus replication

The uridylylation of the VPg peptide primer is the first stage in the replication of picornavirus RNA. This process can be achieved in vitro using purified components, including 3B (VPg) with the RNA dependent RNA polymerase (3Dpol), the precursor 3CD, and an RNA template containing the cre/bus. We show that certain RNA sequences within the foot-and-mouth disease virus (FMDV) 5' untranslated region but outside of the cre/bus can enhance VPg uridylylation activity. Furthermore, we have shown that the FMDV 3C protein alone can substitute for 3CD, albeit less efficiently. In addition, the VPg precursors, 3B(3)3C and 3B(123)3C, can function as substrates for uridylylation in the absence of added 3C or 3CD. Residues within the FMDV 3C protein involved in interaction with the cre/bus RNA have been identified and are located on the face of the protein opposite from the catalytic site. These residues within 3C are also essential for VPg uridylylation activity and efficient virus replication.     

Picornavirus genome replication: roles of precursor proteins and rate-limiting steps in oriI-dependent VPg uridylylation

The 5' ends of all picornaviral RNAs are linked covalently to the genome-encoded peptide, VPg (or 3B). VPg linkage is thought to occur in two steps. First, VPg serves as a primer for production of diuridylylated VPg (VPg-pUpU) in a reaction catalyzed by the viral polymerase that is templated by an RNA element (oriI). It is currently thought that the viral 3AB protein is the source of VPg in vivo. Second, VPg-pUpU is transferred to the 3' end of plus- and/or minus-strand RNA and serves as primer for production of full-length RNA. Nothing is known about the mechanism of transfer. We present biochemical and biological evidence refuting the use of 3AB as the donor for VPg uridylylation. Our data are consistent with precursors 3BC and/or 3BCD being employed for uridylylation. This conclusion is supported by in vitro uridylylation of these proteins, the ability of a mutant replicon incapable of producing processed VPg to replicate in HeLa cells and cell-free extracts and corresponding precursor processing profiles, and the demonstration of 3BC-linked RNA in mutant replicon-transfected cells. These data permit elaboration of our model for VPg uridylylation to include the use of precursor proteins and invoke a possible mechanism for location of the diuridylylated, VPg-containing precursor at the 3' end of plus- or minus-strand RNA for production of full-length RNA. Finally, determinants of VPg uridylylation efficiency suggest formation and/or collapse or release of the uridylylated product as the rate-limiting step in vitro depending upon the VPg donor employed.     

Identification of the oriI-binding site of poliovirus 3C protein by nuclear magnetic resonance spectroscopy

Replication of picornaviral genomes requires recognition of at least three cis-acting replication elements: oriL, oriI, and oriR. Although these elements lack an obvious consensus sequence or structure, they are all recognized by the virus-encoded 3C protein. We have studied the poliovirus 3C-oriI interaction in order to begin to decipher the code of RNA recognition by picornaviral 3C proteins. oriI is a stem-loop structure that serves as the template for uridylylation of the peptide primer VPg by the viral RNA-dependent RNA polymerase. In this report, we have used nuclear magnetic resonance (NMR) techniques to study 3C alone and in complex with two single-stranded RNA oligonucleotides derived from the oriI stem. The (1)H-(15)N spectra of 3C recorded in the presence of these RNAs revealed site-specific chemical shift perturbations. Residues that exhibit significant perturbations are primarily localized in the amino terminus and in a highly conserved loop between residues 81 and 89. In general, the RNA-binding site defined in this study is consistent with predictions based on biochemical and mutagenesis studies. Although some residues implicated in RNA binding by previous studies are perturbed in the 3C-RNA complex reported here, many are unique. These studies provide unique site-specific insight into residues of 3C that interact with RNA and set the stage for detailed structural investigation of the 3C-RNA complex by NMR. Interpretation of our results in the context of an intact oriI provides insight into the architecture of the picornavirus VPg uridylylation complex.     

Structure-function relationships of the viral RNA-dependent RNA polymerase: fidelity, replication speed, and initiation mechanism determined by a residue in the ribose-binding pocket

Studies of the RNA-dependent RNA polymerase (RdRp) from poliovirus (PV), 3Dpol, have shown that Asn-297 permits this enzyme to distinguish ribose from 2'-deoxyribose. All animal RNA viruses have Asn at the structurally homologous position of their polymerases, suggesting a conserved function for this residue. However, all prokaryotic RNA viruses have Glu at this position. In the presence of Mg2+, the apparent affinity of Glu-297 3Dpol for 2'-deoxyribonucleotides was decreased by 6-fold relative to wild type without a substantial difference in the fidelity of 2'-dNMP incorporation. The fidelity of ribonucleotide misincorporation for Glu-297 3Dpol was reduced by 14-fold relative to wild type. A 4- to 11-fold reduction in the rate of ribonucleotide incorporation was observed. Glu-297 PV was unable to grow in HeLa cells due to a replication defect equivalent to that observed for a mutant PV encoding an inactive polymerase. Evaluation of the protein-(VPg)-primed initiation reaction showed that only half of the Glu-297 3Dpol initiation complexes were capable of producing VPg-pUpU product and that the overall yield of uridylylated VPg products was reduced by 20-fold relative to wild-type enzyme, a circumstance attributable to a reduced affinity for UTP. These studies identify the first RdRp derivative with a mutator phenotype and provide a mechanistic basis for the elevated mutation frequency of RNA phage relative to animal RNA viruses observed in culture. Although protein-primed initiation and RNA-primed elongation complexes employ the same polymerase active site, the functional differences reported here imply significant structural differences between these complexes.     

Allosteric effects of ligands and mutations on poliovirus RNA-dependent RNA polymerase

Protein priming of viral RNA synthesis plays an essential role in the replication of picornavirus RNA. Both poliovirus and coxsackievirus encode a small polypeptide, VPg, which serves as a primer for addition of the first nucleotide during synthesis of both positive and negative strands. This study examined the effects on the VPg uridylylation reaction of the RNA template sequence, the origin of VPg (coxsackievirus or poliovirus), the origin of 3D polymerase (coxsackievirus or poliovirus), the presence and origin of interacting protein 3CD, and the introduction of mutations at specific regions in the poliovirus 3D polymerase. Substantial effects associated with VPg origin were traced to differences in VPg-polymerase interactions. The effects of 3CD proteins and mutations at polymerase-polymerase intermolecular Interface I were most consistent with allosteric effects on the catalytic 3D polymerase molecule. In conclusion, the efficiency and specificity of VPg uridylylation by picornavirus polymerases is greatly influenced by allosteric effects of ligand binding that are likely to be relevant during the viral replicative cycle.     

Nucleotide channel of RNA-dependent RNA polymerase used for intermolecular uridylylation of protein primer

Poliovirus VPg is a 22 amino acid residue peptide that serves as the protein primer for replication of the viral RNA genome. VPg is known to bind directly to the viral RNA-dependent RNA polymerase, 3D, for covalent uridylylation, yielding mono and di-uridylylated products, VPg-pU and VPg-pUpU, which are subsequently elongated. To model the docking of the VPg substrate to a putative VPg-binding site on the 3D polymerase molecule, we performed a variety of structure-based computations followed by experimental verification. First, potential VPg folded structures were identified, yielding a suite of predicted beta-hairpin structures. These putative VPg structures were then docked to the region of the polymerase implicated by genetic experiments to bind VPg, using grid-based and fragment-based methods. Residues in VPg predicted to affect binding were identified through molecular dynamics simulations, and their effects on the 3D-VPg interaction were tested computationally and biochemically. Experiments with mutant VPg and mutant polymerase molecules confirmed the predicted binding site for VPg on the back side of the polymerase molecule during the uridylylation reaction, opposite to that predicted to bind elongating RNA primers.     

Enterovirus 71 VPg Uridylation Uses a Two-Molecular Mechanism of 3D Polymerase

VPg uridylylation is essential for picornavirus RNA replication. The VPg uridylylation reaction consists of the binding of VPg to 3D polymerase (3D^pol) and the transfer of UMP by 3D^pol to the hydroxyl group of the third amino acid Tyr of VPg. Previous studies suggested that different picornaviruses employ distinct mechanisms during VPg binding and uridylylation. Here, we report a novel site (Site-311, located at the base of the palm domain of EV71 3D^pol) that is essential for EV71 VPg uridylylation as well as viral replication. Ala substitution of amino acids (T313, F314, and I317) at Site-311 reduced the VPg uridylylation activity of 3D^pol by >90%. None of the Site-311 mutations affected the RNA elongation activity of 3D^pol, which indicates that Site-311 does not directly participate in RNA polymerization. However, mutations that abrogated VPg uridylylation significantly reduced the VPg binding ability of 3D^pol, which suggests that Site-311 is a potential VPg binding site on enterovirus 71 (EV71) 3D^pol. Mutation of a polymerase active site in 3D^pol and Site-311 in 3D^pol remarkably enables trans complementation to restore VPg uridylylation. In contrast, two distinct Site-311 mutants do not cause trans complementation in vitro. These results indicate that Site-311 is a VPg binding site that stabilizes the VPg molecule during the VPg uridylylation process and suggest a two-molecule model for 3D^pol during EV71 VPg uridylylation, such that one 3D^pol presents the hydroxyl group of Tyr3 of VPg to the polymerase active site of another 3D^pol, which in turn catalyzes VPg→VPg-pU conversion. For genome-length RNA, the Site-311 mutations that reduced VPg uridylylation were lethal for EV71 replication, which indicates that Site-311 is a potential antiviral target.     

Biochemical and genetic studies of the VPg uridylylation reaction catalyzed by the RNA polymerase of poliovirus

The first step in poliovirus (PV) RNA synthesis is the covalent linkage of UMP to the terminal protein VPg. This reaction can be studied in vitro with two different assays. The simpler assay is based on a poly(A) template and requires synthetic VPg, purified RNA polymerase 3D(pol), UTP, and a divalent cation. The other assay uses specific viral sequences [cre(2C)] as a template for VPg uridylylation and requires the addition of proteinase 3CD(pro). Using one or both of these assays, we analyzed the VPg specificities and metal requirements of the uridylylation reactions. We determined the effects of single and double amino acid substitutions in VPg on the abilities of the peptides to serve as substrates for 3D(pol). Mutations in VPg, which interfered with uridylylation in vitro, were found to abolish viral growth. A chimeric PV containing the VPg of human rhinovirus 14 (HRV14) was viable, but substitutions of HRV2 and HRV89 VPgs for PV VPg were lethal. Of the three rhinoviral VPgs tested, only the HRV14 peptide was found to function as a substrate for PV1(M) 3D(pol) in vitro. We also examined the metal specificity of the VPg uridylylation reaction on a poly(A) template. Our results show a strong preference of the RNA polymerase for Mn(2+) as a cofactor compared to Mg(2+) or other divalent cations.     

Viability of poliovirus/rhinovirus VPg chimeric viruses and identification of an amino acid residue in the VPg gene critical for viral RNA replication

Picornaviral RNA replication utilizes a small virus-encoded protein, termed 3B or VPg, as a primer to initiate RNA synthesis. This priming step requires uridylylation of the VPg peptide by the viral polymerase protein 3D(pol), in conjunction with other viral or host cofactors. In this study, we compared the viral specificity in 3D(pol)-catalyzed uridylylation reactions between poliovirus (PV) and human rhinovirus 16 (HRV16). It was found that HRV16 3D(pol) was able to uridylylate PV VPg as efficiently as its own VPg, but PV 3D(pol) could not uridylylate HRV16 VPg. Two chimeric viruses, PV containing HRV16 VPg (PV/R16-VPg) and HRV16 containing PV VPg (R16/PV-VPg), were constructed and tested for replication capability in H1-HeLa cells. Interestingly, only PV/R16-VPg chimeric RNA produced infectious virus particles upon transfection. No viral RNA replication or cytopathic effect was observed in cells transfected with R16/PV-VPg chimeric RNA, despite the ability of HRV16 3D(pol) to uridylylate PV VPg in vitro. Sequencing analysis of virion RNA isolated from the virus particles generated by PV/R16-VPg chimeric RNA identified a single residue mutation in the VPg peptide (Glu(6) to Val). Reverse genetics confirmed that this mutation was highly compensatory in enhancing replication of the chimeric viral RNA. PV/R16-VPg RNA carrying this mutation replicated with similar kinetics and magnitude to wild-type PV RNA. This cell culture-induced mutation in HRV16 VPg moderately increased its uridylylation by PV 3D(pol) in vitro, suggesting that it might be involved in other function(s) in addition to the direct uridylylation reaction. This study demonstrated the use of chimeric viruses to characterize viral specificity and compatibility in vivo between PV and HRV16 and to identify critical amino acid residue(s) for viral RNA replication.     

Factors required for the Uridylylation of the foot-and-mouth disease virus 3B1, 3B2, and 3B3 peptides by the RNA-dependent RNA polymerase (3Dpol) in vitro

The 5' terminus of picornavirus genomic RNA is covalently linked to the virus-encoded peptide 3B (VPg). Foot-and-mouth disease virus (FMDV) is unique in encoding and using 3 distinct forms of this peptide. These peptides each act as primers for RNA synthesis by the virus-encoded RNA polymerase 3D(pol). To act as the primer for positive-strand RNA synthesis, the 3B peptides have to be uridylylated to form VPgpU(pU). For certain picornaviruses, it has been shown that this reaction is achieved by the 3D(pol) in the presence of the 3CD precursor plus an internal RNA sequence termed a cis-acting replication element (cre). The FMDV cre has been identified previously to be within the 5' untranslated region, whereas all other picornavirus cre structures are within the viral coding region. The requirements for the in vitro uridylylation of each of the FMDV 3B peptides has now been determined, and the role of the FMDV cre (also known as the 3B-uridylylation site, or bus) in this reaction has been analyzed. The poly(A) tail does not act as a significant template for FMDV 3B uridylylation.     

NMR structure of stem-loop D from human rhinovirus-14

The 5'-cloverleaf of the picornavirus RNA genome is essential for the assembly of a ribonucleoprotein replication complex. Stem-loop D (SLD) of the cloverleaf is the recognition site for the multifunctional viral protein 3Cpro. This protein is the principal viral protease, and its interaction with SLD also helps to position the viral RNA-dependent RNA polymerase (3Dpol) for replication. Human rhinovirus-14 (HRV-14) is distinct from the majority of picornaviruses in that its SLD forms a cUAUg triloop instead of the more common uYACGg tetraloop. This difference appears to be functionally significant, as 3Cpro from tetraloop-containing viruses cannot bind the HRV-14 SLD. We have determined the solution structure of the HRV-14 SLD using NMR spectroscopy. The structure is predominantly an A-form helix, but with a central pyrimidine-pyrimidine base-paired region and a significantly widened major groove. The stabilizing hydrogen bonding present in the uYACGg tetraloop was not found in the cUAUg triloop. However, the triloop uses different structural elements to present a largely similar surface: sequence and underlying architecture are not conserved, but key aspects of the surface structure are. Important structural differences do exist, though, and may account for the observed cross-isotype binding specificities between 3Cpro and SLD.     

Poliovirus cis-acting replication element-dependent VPg Uridylylation lowers the Km of the initiating nucleoside triphosphate for viral RNA replication

Initiation of RNA synthesis by RNA-dependent RNA polymerases occurs when a phosphodiester bond is formed between the first two nucleotides in the 5′ terminus of product RNA. The concentration of initiating nucleoside triphosphates (NTPi) required for RNA synthesis is typically greater than the concentration of NTPs required for elongation. VPg, a small viral protein, is covalently attached to the 5′ end of picornavirus negative- and positive-strand RNAs. A cis-acting replication element (CRE) within picornavirus RNAs serves as a template for the uridylylation of VPg, resulting in the synthesis of VPgpUpU_OH. Mutations within the CRE RNA structure prevent VPg uridylylation. While the tyrosine hydroxyl of VPg can prime negative-strand RNA synthesis in a CRE- and VPgpUpU_OH-independent manner, CRE-dependent VPgpUpU_OH synthesis is absolutely required for positive-strand RNA synthesis. As reported herein, low concentrations of UTP did not support negative-strand RNA synthesis when CRE-disrupting mutations prevented VPg uridylylation, whereas correspondingly low concentrations of CTP or GTP had no negative effects on the magnitude of CRE-independent negative-strand RNA synthesis. The experimental data indicate that CRE-dependent VPg uridylylation lowers the K_m of UTP required for viral RNA replication and that CRE-dependent VPgpUpU_OH synthesis was required for efficient negative-strand RNA synthesis, especially when UTP concentrations were limiting. By lowering the concentration of UTP needed for the initiation of RNA replication, CRE-dependent VPg uridylylation provides a mechanism for a more robust initiation of RNA replication.     

Structure-function relationships of the RNA-dependent RNA polymerase from poliovirus (3Dpol). A surface of the primary oligomerization domain functions in capsid precursor processing and VPg uridylylation

The primary oligomerization domain of poliovirus polymerase, 3Dpol, is stabilized by the interaction of the back of the thumb subdomain of one molecule with the back of the palm subdomain of a second molecule, thus permitting the head-to-tail assembly of 3Dpol monomers into long fibers. The interaction of Arg-455 and Arg-456 of the thumb with Asp-339, Ser-341, and Asp-349 of the palm is key to the stability of this interface. We show that mutations predicted to completely disrupt this interface do not produce equivalent growth phenotypes. Virus encoding a polymerase with changes of both residues of the thumb to alanine is not viable; however, virus encoding a polymerase with changes of all three residues of the palm to alanine is viable. Biochemical analysis of 3Dpol derivatives containing the thumb or palm substitutions revealed that these derivatives are both incapable of forming long fibers, suggesting that polymerase fibers are not essential for virus viability. The RNA binding activity, polymerase activity, and thermal stability of these derivatives were equivalent to that of the wild-type enzyme. The two significant differences observed for the thumb mutant were a modest reduction in the ability of the altered 3CD proteinase to process the VP0/VP3 capsid precursor and a substantial reduction in the ability of the altered 3Dpol to catalyze oriI-templated uridylylation of VPg. The defect to uridylylation was a result of the inability of 3CD to stimulate this reaction. Because 3C alone can substitute for 3CD in this reaction, we conclude that the lethal replication phenotype associated with the thumb mutant is caused, in part, by the disruption of an interaction between the back of the thumb of 3Dpol and some undefined domain of 3C. We speculate that this interaction may also be critical for assembly of other complexes required for poliovirus genome replication.     

Novel, structure-based mechanism for uridylylation of the genome-linked peptide (VPg) of picornaviruses

The VPg peptide, which is found in poliovirus infected cells either covalently bound to the 5'-end of both plus and minus strand viral RNA, or in a uridylylated free form, is essential for picornavirus replication. Combining experimental structure and mutation results with molecular modeling suggests a new mechanism for VPg uridylylation, which assigns an additional function, that of scaffold, to the polymerase. The polarity of the NMR structure of VPg is complementary to the binding site on the surface of poliovirus polymerase determined previously by mutagenesis. Docking VPg at this position places the reactive tyrosinate close to the 5'-end of Poly(A)7 RNA when this is bound with its 3'-end in the active site of the polymerase. The triphosphate tail of a UTP moiety, base paired with the 5'-end of the RNA, projects back over the Tyr3-OH and is held in position by conserved positively charged side-chains of VPg. Other conserved residues mediate binding to the polymerase surface and serve as ligands for metal ion catalyzed transphosphorylation. Additional viral proteins or a second polymerase molecule may aid in stabilizing the components of the reaction. In the model complex, VPg can direct its own uridylylation before entering the polymerase active site.