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.     

Encapsidation of poliovirus replicons encoding the complete human immunodeficiency virus type 1 gag gene by using a complementation system which provides the P1 capsid protein in trans.

Poliovirus genomes which contain small regions of the human immunodeficiency virus type 1 (HIV-1) gag, pol, and env genes substituted in frame for the P1 capsid region replicate and express HIV-1 proteins as fusion proteins with the P1 capsid precursor protein upon transfection into cells (W. S. Choi, R. Pal-Ghosh, and C. D. Morrow, J. Virol. 65:2875-2883, 1991). Since these genomes, referred to as replicons, do not express capsid proteins, a complementation system was developed to encapsidate the genomes by providing P1 capsid proteins in trans from a recombinant vaccinia virus, VV-P1. Virus stocks of encapsidated replicons were generated after serial passage of the replicon genomes into cells previously infected with VV-P1 (D. C. Porter, D. C. Ansardi, W. S. Choi, and C. D. Morrow, J. Virol. 67:3712-3719, 1993). Using this system, we have further defined the role of the P1 region in viral protein expression and RNA encapsidation. In the present study, we constructed poliovirus replicons which contain the complete 1,492-bp gag gene of HIV-1 substituted for the entire P1 region of poliovirus. To investigate whether the VP4 coding region was required for the replication and encapsidation of poliovirus RNA, a second replicon in which the complete gag gene was substituted for the VP2, VP3, and VP1 capsid sequences was constructed. Transfection of replicon RNA with and without the VP4 coding region into cells resulted in similar levels of expression of the HIV-1 Gag protein and poliovirus 3CD protein, as indicated by immunoprecipitation using specific antibodies. Northern (RNA) blot analysis of RNA from transfected cells demonstrated comparable levels of RNA replication for each replicon. Transfection of the replicon genomes into cells infected with VV-P1 resulted in the encapsidation of the genomes; serial passage in the presence of VV-P1 resulted in the generation of virus stocks of encapsidated replicons. Analysis of the levels of protein expression and encapsidated replicon RNA from virus stocks after 21 serial passages of the replicon genomes with VV-P1 indicated that the replicon which contained the VP4 coding region was present at a higher level than the replicon which contained a complete substitution of the P1 capsid sequences. These differences in encapsidation, though, were not detected after only two serial passages of the replicons with VV-P1 or upon coinfection and serial passage with type 1 Sabin poliovirus.(ABSTRACT TRUNCATED AT 400 WORDS)     

Similar interactions of the poliovirus and rhinovirus 3D polymerases with the 3' untranslated region of rhinovirus 14

We showed previously that a human rhinovirus 14 (HRV14) 3' untranslated region (3' UTR) on a poliovirus genome was able to replicate with nearly wild-type kinetics (J. B. Rohll, D. H. Moon, D. J. Evans, and J. W. Almond, J. Virol 69:7835-7844, 1995). This enabled the HRV14 single 3' UTR stem-loop structure to be studied in combination with a sensitive reporter system, poliovirus FLC/REP, in which the capsid coding region is replaced by an in-frame chloramphemicol acetyltransferase (CAT) gene. Using such a construct, we identified a mutant (designated mut4), in which the structure and stability of the stem were predicted to be maintained, that replicated very poorly as determined by its level of CAT activity. The effect of this mutant 3' UTR on replication has been further investigated by transferring it onto the full-length cDNAs of both poliovirus type 3 (PV3) and HRV14. Virus was recovered with a parental plaque phenotype at a low frequency, indicating the acquisition of compensating changes, which sequence analysis revealed were, in both poliovirus- and rhinovirus-derived viruses, located in the active-site cleft of 3D polymerase and involved the substitution of Asn18 for Tyr. These results provide further evidence of a specific interaction between the 3' UTR of picornaviruses and the viral polymerase and also indicate similar interactions of the 3' UTR of rhinovirus with both poliovirus and rhinovirus polymerases.     

An RNA hairpin at the extreme 5'' end of the poliovirus RNA genome modulates viral translation in human cells.

Several mutations were introduced into an infectious poliovirus cDNA clone by inserting different oligodeoxynucleotide linkers into preexisting DNA restriction endonuclease sites in the viral cDNA. Ten mutated DNAs were constructed whose lesions mapped in the 5' noncoding region or in the capsid coding region of the viral genome. Eight of these mutated cDNAs did not give rise to infectious virus upon transfection into human cells, one yielded virus with a wild-type phenotype, and one gave rise to a viral mutant with a small-plaque phenotype. This last mutant, designated 1-5NC-S21, bears a 6-nucleotide insertion in the loop of a stable RNA hairpin at the very 5' end of the viral genome. Detailed analysis of the biological properties of 1-5NC-S21 showed that the primary defect in mutant-infected cells is a fivefold decrease in translation relative to wild-type-infected cells. Transfection into HeLa cells of in vitro-synthesized RNA molecules bearing either the 5' noncoding region of 1-5NC-S21 or wild-type poliovirus upstream of a luciferase reporter gene showed that the mutated RNA hairpin was responsible for the observed decrease in viral translation in mutant-infected cells and conferred this defect to heterologous RNAs. These findings indicate that an RNA hairpin located at the extreme 5' end of the viral RNA and highly conserved among enteroviruses and rhinoviruses profoundly affects the translation efficiency of poliovirus RNA in infected cells.     

Identification of two determinants that attenuate vaccine-related type 2 poliovirus.

The poliovirus P2/P712 strain is an attenuated virus that is closely related to the type 2 Sabin vaccine strain. By using a mouse model for poliomyelitis, sequences responsible for attenuation of the P2/P712 strain were previously mapped to the 5' noncoding region of the genome and a central region encoding VP1, 2Apro, 2B, and part of 2C. To identify specific determinants that attenuate the P2/P712 strain, recombinants between this virus and the mouse-adapted P2/Lansing were constructed and their neurovirulence in mice was determined. By using this approach, the attenuation determinant in the central region was mapped to capsid protein VP1. Candidate attenuating sequences in VP1 and the 5' noncoding region were identified by comparing the P2/P712 sequence with that of vaccine-associated isolate P2/P117, and the P2/117 sequences were introduced into the P2/Lansing-P2/P712 recombinants by site-directed mutagenesis. Results of neurovirulence assays in mice indicate that an A at nucleotide 481 in the 5' noncoding region and isoleucine (Ile) at position 143 of capsid protein VP1 are the major determinants of attenuation of P2/P712. These determinants also attenuated neurovirulence in transgenic mice expressing human poliovirus receptors, a new model for poliomyelitis in which virulent viruses are not host restricted. These results demonstrate that A-481 and Ile-143 are general determinants of attenuation.     

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.     

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.     

Mapping of attenuating sequences of an avirulent poliovirus type 2 strain.

A mouse model for poliomyelitis was used to identify genomic sequences that attenuate neurovirulence of poliovirus strain P2/P712. This type 2 strain is avirulent in primates and mice yet grows as well as virulent strains in cell culture. The approach used was to exchange portions of the genome of the mouse-virulent P2/Lansing strain with the corresponding region from P2/P712 to identify sequences that could attenuate Lansing neurovirulence in mice. A full-length infectious cDNA of P2/P712 was assembled and used to construct recombinants between P2/P712 and P2/Lansing. The results of neurovirulence testing of 11 recombinants indicated that strong attenuating determinants are located in the 5' noncoding region of P2/P712 and a region encoding capsid protein VP1 and 2Apro, 2B, and part of 2C. An attenuating determinant was further localized to between nucleotides 456 and 628 of P2/P712. A third sequence from P2/P712, nucleotides 752 to 2268, encoding VP4, VP2, and part of VP3, was weakly attenuating. The sequence from nucleotide 4454, approximately halfway through the 2C-coding region, to the end of the P2/P712 genome did not contain attenuating determinants. Nucleotide sequence analysis revealed that P2/P712 differs from the type 2 Sabin vaccine strain by only 22 nucleotides. Six differences lead to amino acid changes in the coding region, and four differences are in the 5' noncoding region. These studies show that, like the type 1 and type 3 Sabin vaccine strains, the attenuated type 2 strain P712 contains multiple attenuating sequences, including strongly attenuating sequences in the 5' noncoding region of the genome.     

Nucleotide sequence of a neurovirulent variant of the type 2 oral poliovirus vaccine.

Infectious cDNAs of the Sabin type 2 poliovirus vaccine virus and a vaccine-derived neurovirulent type 2 strain (P2/117) have been cloned in Escherichia coli. Nucleotide sequence analysis revealed that P2/117 differs from the vaccine strain by just 23 point mutations. Three occur in the 5' noncoding region. The remainder result in a total of 5 coding changes located in VP1, VP4, 2B, and 3D. The likely role of these mutations in the evolution to neurovirulence is discussed.     

The deletion of 41 proximal nucleotides reverts a poliovirus mutant containing a temperature-sensitive lesion in the 5'' noncoding region of genomic RNA.

We generated a number of small deletions and insertions in the 5' noncoding region of an infectious cDNA copy of the poliovirus RNA genome. Transfection of these mutated cDNAs into COS-1 cells produced the following phenotypic categories: (i) wild-type mutations, (ii) lethal mutations, (iii) mutations exhibiting slow growth or low-titer properties, and (iv) temperature-sensitive (ts) mutations. The deletion of nucleotides 221 to 224 produced a ts virus, 220D1. Mutant 220D1 was found to have a dramatic reduction in growth, virus-specific protein and RNA synthesis, and the shutoff of host cell protein synthesis at 37 or 39 degrees C compared with 33 degrees C. Temperature shift experiments showed that the mutant viral RNA is not an effective template for protein or RNA synthesis at 39 degrees C and suggested a decreased stability of the 220D1 RNA at 39 degrees C. Selection for a non-ts revertant of 220D1 yielded the virus R2, which was no longer ts for growth or viral protein and RNA synthesis. Sequencing the 5' noncoding region of the genomic RNA from R2 revealed the deletion of 41 proximal nucleotides for an overall deletion of nucleotides 184 to 228. These data suggest that the deleted sequences are nonessential to the poliovirus life cycle during growth in HeLa cells. According to computer-predicted RNA secondary structures of the 5' noncoding region of poliovirus RNA, the R2 revertant virus has deleted an entire predicted stem-loop structure.     

Construction of recombinant DNA molecules by the use of a single stranded DNA generated by the polymerase chain reaction: its application to chimeric hepatitis A virus/poliovirus subgenomic cDNA.

In order to study the importance of VP4 in picornavirus replication and translation, we replaced the hepatitis A virus (HAV) VP4 with the poliovirus (PV1) VP4. Using a modification of oligonucleotide site directed mutagenesis and the polymerase chain reaction (PCR), we created a subgenomic cDNA chimera of hepatitis A virus in which the precise sequences coding for HAV VP4 capsid protein were replaced by the sequences coding for the poliovirus VP4 capsid protein. The method involved the use of PCR primers corresponding to the 3' and 5' ends of the poliovirus VP4 sequence and that had HAV VP4 3' and 5' flanking sequences on their 5'ends. Single stranded DNA of 240 and 242 nt containing the 204 nt coding for the complete poliovirus VP4 were produced by using a limiting amount of one of the primers in a PCR reaction. These single stranded PCR products were used like mutagenic oligonucleotides on a single stranded phagemid containing the first 2070 bases of the HAV genome. Using this technique, we precisely replaced the HAV VP4 gene by the poliovirus VP4 gene as determined by DNA sequencing. The cDNA was transcribed into RNA and translated in vitro. The resulting protein could be precipitated by antibody to poliovirus VP4 but not to HAV VP4.     

Inherent instability of poliovirus genomes containing two internal ribosome entry site (IRES) elements supports a role for the IRES in encapsidation

Previous studies have described poliovirus genomes in which the internal ribosome entry (IRES) for encephalomyocarditis virus (EMCV) is positioned between the P1 and P2-P3 open reading frames of the poliovirus genome. Although these dicistronic poliovirus genomes were replication competent, most exhibited evidence of genetic instability, and the EMCV IRES was deleted upon serial passage. One possible reason for instability of the genome is that the dicistronic genome was at least 108% larger than the wild-type poliovirus genome, which could reduce the efficiency of encapsidation. To address this possibility, we have constructed dicistronic poliovirus replicons by substituting the EMCV IRES and the gene encoding luciferase in place of the poliovirus P1 region; the resulting dicistronic replicons are smaller than the wild-type poliovirus genome. One dicistronic genome was constructed in which the poliovirus 5' nontranslated region was fused to the gene encoding luciferase, followed by the complete EMCV IRES fused to the P2-P3 region of the poliovirus genome (PV-Luc-EMCV). A second dicistronic genome, EMCV-Luc-PV, was constructed with the first 108 nucleotides of the poliovirus genome fused to the EMCV IRES, followed by the gene encoding luciferase and the poliovirus IRES fused to the remaining P2-P3 region of the poliovirus genome. Both dicistronic replicons expressed abundant luciferase following transfection of in vitro-transcribed RNA into HeLa cells at 30, 33, or 37 degrees C. The luciferase activity detected from PV-Luc-EMCV increased rapidly during the first 4 h following transfection and then plateaued, peaking after approximately 24 h. In contrast, the luciferase activity detected from EMCV-Luc-PV increased for approximately 12 h following transfection; by 24 h posttransfection, the overall levels of luciferase activity were similar to that of PV-Luc-EMCV. To analyze encapsidation of the dicistronic replicons, we used a system in which the capsid protein (P1) is provided in trans from a recombinant vaccinia virus (VV-P1). The PV-Luc-EMCV replicon was unstable upon serial passage in the presence of VV-P1, with deletions of the EMCV IRES region detected even during the initial transfection at 37 degrees C. Following serial passage in the presence of VV-P1 at 33 or 30 degrees C, we detected deleted genomes in which the luciferase gene was fused with the P2-P3 genes of the poliovirus genome so as to maintain the translational reading frame. In contrast, the EMCV-Luc-PV replicon was genetically stable during passage with VV-P1 at 33 or 30 degrees C. The encapsidation of EMCV-Luc-PV was compared to that of monocistronic replicons encoding luciferase with either a poliovirus or EMCV IRES. Analysis of the encapsidated replicons after four serial passages with VV-P1 revealed that the dicistronic replicon was encapsidated more efficiently than the monocistronic replicon with the EMCV IRES but less efficiently than the monicistronic replicon with the poliovirus IRES. The results of this study suggest a genetic predisposition for picornavirus genomes to contain a single IRES region and are discussed with respect to a role of the IRES in encapsidation.     

Genetic analysis of a poliovirus/hepatitis C virus chimera: new structure for domain II of the internal ribosomal entry site of hepatitis C virus

Internal ribosomal entry sites (IRESs) of certain plus-strand RNA viruses direct cap-independent initiation of protein synthesis both in vitro and in vivo, as can be shown with artificial dicistronic mRNAs or with chimeric viral genomes in which IRES elements were exchanged from one virus to another. Whereas IRESs of picornaviruses can be readily analyzed in the context of their cognate genome by genetics, the IRES of hepatitis C virus (HCV), a Hepacivirus belonging to Flaviviridae, cannot as yet be subjected to such analyses because of difficulties in propagating HCV in tissue culture or in experimental animals. This enigma has been overcome by constructing a poliovirus (PV) whose translation is controled by the HCV IRES. Within the PV/HCV chimera, the HCV IRES has been subjected to systematic 5' deletion analyses to yield a virus (P/H710-d40) whose replication kinetics match that of the parental poliovirus type 1 (Mahoney). Genetic analyses of the HCV IRES in P/H710-d40 have confirmed that the 5' border maps to domain II, thereby supporting the validity of the experimental approach applied here. Additional genetic experiments have provided evidence for a novel structural region within domain II. Arguments that the phenotypes observed with the mutant chimera relate solely to impaired genome replication rather than deficiencies in translation have been dispelled by constructing novel dicistronic poliovirus replicons with the gene order [PV]cloverleaf-[HCV]IRES-Deltacore-R-Luc-[PV]IRES-F-Luc-P2,3-3'NTR, which have allowed the measurement of HCV IRES-dependent translation independently from the replication of the replicon RNA.     

Yeast cells are incapable of translating RNAs containing the poliovirus 5'' untranslated region: evidence for a translational inhibitor.

We have expressed in the yeast Saccharomyces cerevisiae a full-length poliovirus cDNA clone under the control of the GAL10 promoter to better characterize the effect of poliovirus on host cell metabolism. We find that yeast cells are unable to translate poliovirus RNA in vivo and that this inhibition is mediated through the 5' untranslated region of the viral RNA. The in vivo inhibition of translation of poliovirus RNA and P2CAT RNA (which contains the 5' untranslated region fused upstream of the bacterial chloramphenicol transferase gene) can be mimicked in vitro in yeast translation lysates. In fact, a trans-acting inhibitor present in yeast lysates can inhibit translation of either poliovirus or P2CAT RNA in HeLa cell translation lysates. In contrast, when the inhibitor is added to translations programmed with chloramphenicol acetyltransferase RNA, yeast prepro-alpha-factor RNA, or an RNA containing the internal ribosome entry site of encephalomyocarditis virus, no inhibition is seen. The inhibitory activity has been partially purified by DEAE-Sephacel chromatography. The partially purified inhibitor is heat stable, escapes phenol extraction, is resistant to proteinase K and DNase I treatment, and is sensitive to RNase A digestion, suggesting that the inhibitor is an RNA. In an in vitro translation assay, the inhibitory activity can be overcome by increasing the concentration of HeLa cell lysate but not P2CAT RNA, suggesting that the inhibitor interacts (directly or indirectly) with one or more components of the HeLa cell translational machinery rather than with the viral RNA.     

An RNA sequence of hundreds of nucleotides at the 5'' end of poliovirus RNA is involved in allowing viral protein synthesis.

Twenty-one mutations were engineered in the 5' noncoding region of poliovirus type 1 RNA, using an infectious cDNA copy of the viral genome. RNA was made from these constructs and used to transfect HeLa cells. Viable virus was recovered from 12 of these transfection experiments, including six strains with a recognizable phenotype, mapping in four different regions. One mutant of each site was studied in more detail. Mutant 5NC-11, having a 4-base insertion at nucleotide 70, was dramatically deficient in RNA synthesis, suggesting that the far 5' end of the genome is primarily involved in one or more steps of RNA replication. Mutants 5NC-13, 5NC-114, and 5NC-116, mapping at nucleotides 224, 270, and 392, respectively, showed a similar behavior; they made very little viral protein, they did not inhibit host cell translation, and they synthesized a significant amount of viral RNA, although with some delay compared with wild type. These three mutants were efficiently complemented by all other poliovirus mutants tested, except those with lesions in protein 2A. Our results imply that these three mutants map in a region (region P) primarily involved in viral protein synthesis and that their inability to shut off host cell translation is secondary to a quantitative defect in protein 2A. The exact function of region P is still to be determined, but our data supports the hypothesis of a single functional module allowing viral protein synthesis and extending over several hundred nucleotides.     

Replicase gene of coxsackievirus B3.

A cDNA copy covering two-thirds of the coxsackievirus B3 genome was cloned in the PstI site of the pBR322 vector. A nucleotide sequence containing the gene for the viral replicase and the 3' noncoding region of the coxsackievirus B3 genome was determined. The predicted amino acid sequence of the coxsackievirus B3 replicase was shown to be remarkably similar to that of the poliovirus 1 replicase. The 3' noncoding region, in contrast, was only weakly homologous to the poliovirus 1 sequence but showed a close relationship to the sequence of swine vesicular disease virus, a variant of coxsackievirus B5. A 13-nucleotide-long segment located near the polyadenylic acid junction is conserved in several members of the enterovirus group and may thus serve an important function during replication of viral RNA.     

Characterization of poliovirus clones containing lethal and nonlethal mutations in the genome-linked protein VPg.

Viral RNA synthesis was assayed in HeLa cells transfected with nonviable poliovirus RNA mutated in the genome-linked protein VPg-coding region. The transfecting RNA was transcribed in vitro from full-length poliovirus type 1 (Mahoney) cDNA containing a VPg mutagenesis cartridge. Hybridization experiments using ribonucleotide probes specific for the 3' end of positive- and negative-sense poliovirus RNA indicated that all mutant RNAs encoding a linking tyrosine in position 3 or 4 of VPg were replicated even though no virus was produced. VPg, but no VPg precursor, was found to be linked to the 5' end of the newly synthesized RNA. Encapsidated mutant RNAs were not found in transfected-cell lysates. After extended maintenance of transfected HeLa cells, a viable revertant of one of the nonviable RNAs was recovered; the revertant lost the lethal lesion in VPg by restoring the wild-type amino acid, but it retained all other nucleotide changes introduced during construction of the mutagenesis cartridge. Mutant RNA encoding phenylalanine or serine rather than tyrosine, the linking amino acid in VPg, was not replicated in transfected cells. A chimeric mutant containing the VPg-coding region of coxsackievirus within the poliovirus genome was viable but displayed impaired multiplication. A poliovirus-coxsackievirus chimera lacking a linking tyrosine in VPg was nonviable and replication-negative. The results indicate that a linkage-competent VPg is necessary for poliovirus RNA synthesis to occur but that a step in poliovirus replication other than initiation of RNA synthesis can be interrupted by lethal mutations in VPg.