Poliovirus RNA-dependent RNA polymerase and host cell protein synthesize product RNA twice the size of poliovirion RNA in vitro

Direct nanopore RNA sequencing of umbra-like virus-infected plants reveals long non-coding RNAs, specific cleavage sites, D-RNAs, foldback RNAs, and temporal- and tissue-specific profiles

The traditional view of plus (+)-strand RNA virus transcriptomes is that infected cells contain a limited variety of viral RNAs, such as full-length (+)-strand genomic RNA(s), (-)-strand replication intermediate(s), 3' co-terminal subgenomic RNA(s), and viral recombinant defective (D)-RNAs. To ascertain the full complement of viral RNAs associated with the simplest plant viruses, long-read direct RNA nanopore sequencing was used to perform transcriptomic analyses of two related umbra-like viruses: citrus yellow vein-associated virus (CY1) from citrus and CY2 from hemp. Analysis of different timepoints/tissues in CY1- and CY2-infected Nicotiana benthamiana plants and CY2-infected hemp revealed: (i) three 5' co-terminal RNAs of 281 nt, 442 nt and 671 nt, each generated by a different mechanism; (ii) D-RNA populations containing the 671 fragment at their 5'ends; (iii) many full-length genomic RNAs and D-RNAs with identical 3'end 61 nt truncations; (iv) virtually all (-)-strand reads missing 3 nt at their 3' termini; (v) (±) foldback RNAs comprising about one-third of all (-)-strand reads and (vi) a higher proportion of full-length gRNAs in roots than in leaves, suggesting that roots may be functioning as a gRNA reservoir. These findings suggest that viral transcriptomes are much more complex than previously thought.

Emergence of distinct brome mosaic virus recombinants is determined by the polarity of the inoculum RNA

Despite overwhelming interest in the impact exerted by recombination during evolution of RNA viruses, the relative contribution of the polarity of inoculum templates remains poorly understood. Here, by agroinfiltrating Nicotiana benthamiana leaves, we show that brome mosaic virus (BMV) replicase is competent to initiate positive-strand [(+)-strand] synthesis on an ectopically expressed RNA3 negative strand [(-) strand] and faithfully complete the replication cycle. Consequently, we sought to examine the role of RNA polarity in BMV recombination by expressing a series of replication-defective mutants of BMV RNA3 in (+) or (-) polarity. Temporal analysis of progeny sequences revealed that the genetic makeup of the primary recombinant pool is determined by the polarity of the inoculum template. When the polarity of the inoculum template was (+), the recombinant pool that accumulated during early phases of replication was a mixture of nonhomologous recombinants. These are longer than the inoculum template length, and a nascent 3' untranslated region (UTR) of wild-type (WT) RNA1 or RNA2 was added to the input mutant RNA3 3' UTR due to end-to-end template switching by BMV replicase during (-)-strand synthesis. In contrast, when the polarity of the inoculum was (-), the progeny contained a pool of native-length homologous recombinants generated by template switching of BMV replicase with a nascent UTR from WT RNA1 or RNA2 during (+)-strand synthesis. Repair of a point mutation caused by polymerase error occurred only when the polarity of the inoculum template was (+). These results contribute to the explanation of the functional role of RNA polarity in recombination mediated by copy choice mechanisms.

Relationship between poliovirus negative-strand RNA synthesis and the length of the 3' poly(A) tail

The precise relationship between the length of the 3' poly(A) tail and the replication and infectivity of poliovirus RNA was examined in this study. With both poly(A)(11) and poly(A)(12) RNAs, negative-strand synthesis was 1-3% of the level observed with poly(A)(80) RNA. In contrast, increasing the length of the poly(A) tail from (A)(12) to (A)(13) resulted in about a ten-fold increase in negative-strand synthesis. This increase continued with each successive increase in poly(A) tail length. With poly(A)(20) RNA, RNA synthesis approached the level observed with poly(A)(80) RNA. A similar relationship was observed between poly(A) tail length and the infectivity of the viral RNA. A replication model is described which suggests that viral RNA replication is dependent on a poly(A) tail that is long enough to bind poly(A) binding protein and to act as a template for VPg uridylylation and negative-strand initiation.

Effects of mutations of the initiation nucleotides on hepatitis C virus RNA replication in the cell

Replication of nearly all RNA viruses depends on a virus-encoded RNA-dependent RNA polymerase (RdRp). Our earlier work found that purified recombinant hepatitis C virus (HCV) RdRp (NS5B) was able to initiate RNA synthesis de novo by using purine (A and G) but not pyrimidine (C and U) nucleotides (G. Luo et al., J. Virol. 74:851-863, 2000). For most human RNA viruses, the initiation nucleotides of both positive- and negative-strand RNAs were found to be either an adenylate (A) or guanylate (G). To determine the nucleotide used for initiation and control of HCV RNA replication, a genetic mutagenesis analysis of the nucleotides at the very 5' and 3' ends of HCV RNAs was performed by using a cell-based HCV replicon replication system. Either a G or an A at the 5' end of HCV genomic RNA was able to efficiently induce cell colony formation, whereas a nucleotide C at the 5' end dramatically reduced the efficiency of cell colony formation. Likewise, the 3'-end nucleotide U-to-C mutation did not significantly affect the efficiency of cell colony formation. In contrast, a U-to-G mutation at the 3' end caused a remarkable decrease in cell colony formation, and a U-to-A mutation resulted in a complete abolition of cell colony formation. Sequence analysis of the HCV replicon RNAs recovered from G418-resistant Huh7 cells revealed several interesting findings. First, the 5'-end nucleotide G of the replicon RNA was changed to an A upon multiple rounds of replication. Second, the nucleotide A at the 5' end was stably maintained among all replicon RNAs isolated from Huh7 cells transfected with an RNA with a 5'-end A. Third, initiation of HCV RNA replication with a CTP resulted in a >10-fold reduction in the levels of HCV RNAs, suggesting that initiation of RNA replication with CTP was very inefficient. Fourth, the 3'-end nucleotide U-to-C and -G mutations were all reverted back to a wild-type nucleotide U. In addition, extra U and UU residues were identified at the 3' ends of revertants recovered from Huh7 cells transfected with an RNA with a nucleotide G at the 3' end. We also determined the 5'-end nucleotide of positive-strand RNA of some clinical HCV isolates. Either G or A was identified at the 5' end of HCV RNA genome depending on the specific HCV isolate. Collectively, these findings demonstrate that replication of positive-strand HCV RNA was preferentially initiated with purine nucleotides (ATP and GTP), whereas the negative-strand HCV RNA replication is invariably initiated with an ATP.

Crystal structure of norwalk virus polymerase reveals the carboxyl terminus in the active site cleft

Norwalk virus is a major cause of acute gastroenteritis for which effective treatments are sorely lacking. To provide a basis for the rational design of novel antiviral agents, the main replication enzyme in Norwalk virus, the virally encoded RNA-dependent RNA polymerase (RdRP), has been expressed in an enzymatically active form, and its structure has been crystallographically determined both in the presence and absence of divalent metal cations. Although the overall fold of the enzyme is similar to that seen previously in the RdRP from rabbit hemorrhagic disease virus, the carboxyl terminus, surprisingly, is located in the active site cleft in five independent copies of the protein in three distinct crystal forms. The location of this carboxyl-terminal segment appears to interfere with the binding of double-stranded RNA in the active site cleft and may play a role in the initiation of RNA synthesis or mediate interactions with accessory replication proteins.

Biochemical characterization of rhinovirus RNA-dependent RNA polymerase

Human rhinoviruses (HRV) represent the single most important causative agent of the common cold. The HRV genome encodes an RNA-dependent RNA polymerase (RdRp) designated 3D polymerase that is required for replication of the HRV RNA genome. We have expressed and purified recombinant HRV-16 3D polymerase to near homogeneity from Escherichia coli transformed with an expression plasmid containing the full-length 460 amino acid HRV-16 3D sequence with a methionine at the N-terminus and a glycine-serine linker followed by a 6-histidine affinity tag at the C-terminus. The purified recombinant protein has rifampicin-resistant activity in a poly(A)-dependent poly(U) polymerase assay while corresponding fractions similarly purified from E. coli transformed with an expression plasmid without the HRV-16 3D sequence showed no activity. The optimal conditions for temperature, pH, divalent cations Mg(2+) and Mn(2+), and KCl were determined. The recombinant protein has RNA polymerase activity on homopolymeric templates poly(A) and poly(C) and heteropolymeric RNA templates primed with either RNA or DNA oligonucleotide primers or self-primed by a copy-back mechanism. A unique, secondary structureless heteropolymeric RNA template that is an efficient substrate was developed to facilitate kinetic characterizations of the enzyme. In the presence of Mg(2+), the enzyme displayed strong base and sugar specificity. However, when Mg(2+) was replaced by Mn(2+) specificity for ribonucleotides was lost, utilization of deoxynucleotides became possible and primer-independent activity was observed on the poly(C) template. Zn(2+) was found to inhibit HRV-16 3D polymerase with an IC(50) as low as 0.6 microM by a mechanism distinct from the magnesium ion stimulation. The activity of this 6His-tagged HRV-16 3D polymerase was compared with that of a recombinant HRV-16 3D polymerase expressed without the 6His-tag and was found to be identical. The availability of recombinant rhinovirus RdRp in a purified form will facilitate the structure-function analysis of this enzyme as well as the identification of specific inhibitors to the rhinovirus 3D polymerase that have therapeutic value in the treatment of the common cold.

Factors regulating template switch in vitro by viral RNA-dependent RNA polymerases: implications for RNA-RNA recombination

Copy-choice RNA recombination occurs during viral RNA synthesis when the viral transcription complex switches templates. We demonstrate that RNA-dependent RNA polymerase from bovine viral diarrhea virus and the replicases from three plant-infecting RNA viruses can produce easily detectable recombination products in vitro by switching templates during elongative RNA synthesis. Template sequence and/or structure, and NTP availability affected the frequency of template switch by the transcription complex. Our results provide biochemical support for copy-choice recombination and establish assays for mechanistic analyses of intermolecular RNA recombination in vitro.

Translating ribosomes inhibit poliovirus negative-strand RNA synthesis

Poliovirus has a single-stranded RNA genome of positive polarity that serves two essential functions at the start of the viral replication cycle in infected cells. First, it is translated to synthesize viral proteins and, second, it is copied by the viral polymerase to synthesize negative-strand RNA. We investigated these two reactions by using HeLa S10 in vitro translation-RNA replication reactions. Preinitiation RNA replication complexes were isolated from these reactions and then used to measure the sequential synthesis of negative- and positive-strand RNAs in the presence of different protein synthesis inhibitors. Puromycin was found to stimulate RNA replication overall. In contrast, RNA replication was inhibited by diphtheria toxin, cycloheximide, anisomycin, and ricin A chain. Dose-response experiments showed that precisely the same concentration of a specific drug was required to inhibit protein synthesis and to either stimulate or inhibit RNA replication. This suggested that the ability of these drugs to affect RNA replication was linked to their ability to alter the normal clearance of translating ribosomes from the input viral RNA. Consistent with this idea was the finding that the protein synthesis inhibitors had no measurable effect on positive-strand synthesis in normal RNA replication complexes. In marked contrast, negative-strand synthesis was stimulated by puromycin and was inhibited by cycloheximide. Puromycin causes polypeptide chain termination and induces the dissociation of polyribosomes from mRNA. Cycloheximide and other inhibitors of polypeptide chain elongation "freeze" ribosomes on mRNA and prevent the normal clearance of ribosomes from viral RNA templates. Therefore, it appears that the poliovirus polymerase was not able to dislodge translating ribosomes from viral RNA templates and mediate the switch from translation to negative-strand synthesis. Instead, the initiation of negative-strand synthesis appears to be coordinately regulated with the natural clearance of translating ribosomes to avoid the dilemma of ribosome-polymerase collisions.

A novel in vitro replication system for Dengue virus. Initiation of RNA synthesis at the 3'-end of exogenous viral RNA templates requires 5'- and 3'-terminal complementary sequence motifs of the viral RNA

Positive strand viral replicases are membrane-bound complexes of viral and host proteins. The mechanism of viral replication and the role of host proteins are not well understood. To understand this mechanism, a viral replicase assay that utilizes extracts from dengue virus-infected mosquito (C6/36) cells and exogenous viral RNA templates is reported in this study. The 5'- and 3'-terminal regions (TR) of the template RNAs contain the conserved elements including the complementary (cyclization) motifs and stem-loop structures. RNA synthesis in vitro requires both 5'- and 3'-TR present in the same template molecule or when the 5'-TR RNA was added in trans to the 3'-untranslated region (UTR) RNA. However, the 3'-UTR RNA alone is not active. RNA synthesis occurs by elongation of the 3'-end of the template RNA to yield predominantly a double-stranded hairpin-like RNA product, twice the size of the template RNA. These results suggest that an interaction between 5'- and 3'-TR of the viral RNA that modulates the 3'-UTR RNA structure is required for RNA synthesis by the viral replicase. The complementary cyclization motifs of the viral genome also seem to play an important role in this interaction.

The RNA-dependent RNA polymerases of different members of the family Flaviviridae exhibit similar properties in vitro

The virus-encoded RNA-dependent RNA polymerase (RdRp), which is required for replication of the positive-strand RNA genome, is a key enzyme of members of the virus family Flaviviridae. By using heterologously expressed proteins, we demonstrate that the 77 kDa NS5B protein of two pestiviruses, bovine viral diarrhoea virus and classical swine fever virus, and the 100 kDa NS5 protein of the West Nile flavivirus possess RdRp activity in vitro. As originally shown for the RdRp of hepatitis C virus, RNA synthesis catalysed by the pestivirus and flavivirus enzymes is strictly primer-dependent in vitro. Accordingly, initiation of RNA polymerization on homopolymeric RNAs and heteropolymeric templates, the latter with a blocked 3'-hydroxyl group, was found to be dependent on the presence of complementary oligonucleotide primer molecules. On unblocked heteropolymeric templates, including authentic viral RNAs, the RdRps were shown to initiate RNA synthesis via intramolecular priming at the 3'-hydroxyl group of the template and 'copy-back' transcription, thus yielding RNase-resistant hairpin molecules. Taken together, the RdRps of different members of the Flaviviridae were demonstrated to exhibit a common reactivity profile in vitro, typical of nucleic acid-polymerizing enzymes.

A recombinant hepatitis C virus RNA-dependent RNA polymerase capable of copying the full-length viral RNA

All of the previously reported recombinant RNA-dependent RNA polymerases (RdRp), the NS5B enzymes, of hepatitis C virus (HCV) could function only in a primer-dependent and template-nonspecific manner, which is different from the expected properties of the functional viral enzymes in the cells. We have now expressed a recombinant NS5B that is able to synthesize a full-length HCV genome in a template-dependent and primer-independent manner. The kinetics of RNA synthesis showed that this RdRp can initiate RNA synthesis de novo and yield a full-length RNA product of genomic size (9.5 kb), indicating that it did not use the copy-back RNA as a primer. This RdRp was also able to accept heterologous viral RNA templates, including poly(A)- and non-poly(A)-tailed RNA, in a primer-independent manner, but the products in these cases were heterogeneous. The RdRp used some homopolymeric RNA templates only in the presence of a primer. By using the 3'-end 98 nucleotides (nt) of HCV RNA, which is conserved in all genotypes of HCV, as a template, a distinct RNA product was generated. Truncation of 21 nt from the 5' end or 45 nt from the 3' end of the 98-nt RNA abolished almost completely its ability to serve as a template. Inclusion of the 3'-end variable sequence region and the U-rich tract upstream of the X region in the template significantly enhanced RNA synthesis. The 3' end of minus-strand RNA of HCV genome also served as a template, and it required a minimum of 239 nt from the 3' end. These data defined the cis-acting sequences for HCV RNA synthesis at the 3' end of HCV RNA in both the plus and minus senses. This is the first recombinant HCV RdRp capable of copying the full-length HCV RNA in the primer-independent manner expected of the functional HCV RNA polymerase.

Intracellular localization of poliovirus plus- and minus-strand RNA visualized by strand-specific fluorescent In situ hybridization

The time courses of poliovirus plus- and minus-strand RNA synthesis in infected HEp-2 cells were monitored separately, using a quantitative RNase assay. In parallel, viral RNA and proteins were located in situ by confocal microscopy within cells fixed by a protocol determined to retain their native size and shape. Plus- and minus-strand RNAs were visualized by fluorescent in situ hybridization (FISH) with strand-specific riboprobes. The probes were labelled with different fluorochromes to allow for the simultaneous detection of plus- and minus-strand RNA. The FISH experiments showed minus-strand RNA to be present in distinct, regularly sized, round structures throughout the viral replication cycle. Plus-strand RNA was found in the same structures and also in smaller clusters of vesicles. Association of viral RNA with membranes was demonstrated by combining FISH with immunofluorescence (IF) detection of the viral 2B- and 2C-containing P2 proteins, which are known to be markers for virus-induced membranes. At early times postinfection, the virus-induced membranous structures were distributed through most of the cytoplasm, whereas around peak RNA synthesis, both RNA-associated membranous structures migrated to the center of the cell. During this process, the plus- and minus-strand-containing larger structures stayed as recognizable entities, whereas the plus-strand-containing granules coalesced into a juxtanuclear area of membranous vesicles. An involvement of Golgi-derived membranes in the formation of virus-induced vesicles and RNA synthesis early in infection was investigated by IF with 2C- and Golgi-specific antibodies.

Expression of enzymatically active rabbit hemorrhagic disease virus RNA-dependent RNA polymerase in Escherichia coli

The rabbit hemorrhagic disease virus (RHDV) (isolate AST/89) RNA-dependent RNA-polymerase (3Dpol) coding region was expressed in Escherichia coli by using a glutathione S-transferase-based vector, which allowed milligram purification of a homogeneous enzyme with an expected molecular mass of about 58 kDa. The recombinant polypeptide exhibited rifampin- and actinomycin D-resistant, poly(A)-dependent poly(U) polymerase. The enzyme also showed RNA polymerase activity in in vitro reactions with synthetic RHDV subgenomic RNA in the presence or absence of an oligo(U) primer. Template-size products were synthesized in the oligo(U)-primed reactions, whereas in the absence of added primer, RNA products up to twice the length of the template were made. The double-length RNA products were double stranded and hybridized to both positive- and negative-sense probes.

Novel structures of two virus-like RNA elements from a diseased isolate of the Dutch elm disease fungus, Ophiostoma novo-ulmi

The nucleotide sequences of 2 of the 10 mitochondrial double-stranded (ds) RNA segments in a diseased isolate, Log 1/3-8d2 (Ld), of Ophiostoma novo-ulmi, RNA-7 (1057 nucleotides) and RNA-10 (317-330 nucleotides), have been determined. Both RNAs are A-U-rich, but in Southern and Northern blots, no hybridization with mitochondrial DNA or RNA could be detected. Only very short open reading frames were found in both RNAs. As most of its sequence is unrelated to any of the other Ld dsRNAs, RNA-7 may be regarded as a satellite RNA. Northern blotting detected a full-length single-stranded (ss) form of RNA-7 in nucleic acid extracts from Ld. The 5'- and 3'-terminal 39 nucleotides of ssRNA-7 are imperfect inverted complementary repeats of each other, which could cause ssRNA-7 to form a panhandle structure. In addition, the 5'-terminal nucleotides 1-28 and 3'-terminal nucleotides 1032-1057 of ssRNA-7 each contained inverted complementary sequences, allowing the possibility for each terminus to form separate stem-loop structures. The combination of these two structural features has not been found previously in any dsRNA or ssRNA virus. RNA-10 was shown to have an unusual structure, consisting of a mosaic of sequences derived from regions of the 5'- and 3'-termini, or just the 5'-terminus, of RNA-7, RNA-10 has a high degree of inverted complementarity, with the potential to be folded into a very stable hairpin structure. A model for the formation of RNA-10 is presented, involving replicase-driven strand switching between (-)-strand and (+)-strand templates during RNA synthesis, followed by utilization of the nascent strand as a primer and template to form a snap-back RNA.

Synchronous replication of poliovirus RNA: initiation of negative-strand RNA synthesis requires the guanidine-inhibited activity of protein 2C

We report that protein 2C, the putative nucleoside triphosphatase/helicase protein of poliovirus, is required for the initiation of negative-strand RNA synthesis. Preinitiation RNA replication complexes formed upon the translation of poliovirion RNA in HeLa S10 extracts containing 2 mM guanidine HCI, a reversible inhibitor of viral protein 2C. Upon incubation in reactions lacking guanidine, preinitiation RNA replication complexes synchronously initiated and elongated negative-strand RNA molecules, followed by the synchronous initiation and elongation of positive-strand RNA molecules. The immediate and exclusive synthesis of negative-strand RNA upon the removal of guanidine demonstrates that guanidine specifically blocks the initiation of negative-strand RNA synthesis. Readdition of guanidine HCl to reactions synchronously elongating nascent negative-strand RNA molecules did not prevent their continued elongation and completion. In fact, readdition of guanidine HCl to reactions containing preinitiation complexes elongating nascent negative-strand RNA molecules had no effect on subsequent positive-strand RNA synthesis initiation or elongation. Thus, the guanidine-inhibited function of viral protein 2C was not required for the elongation of negative-strand RNA molecules, the initiation of positive-strand RNA molecules, or the elongation of positive-strand RNA molecules. The guanidine-inhibited function of viral protein 2C is required only immediately before or during the initiation of negative-strand RNA synthesis. We suggest that guanidine may block an irreversible structural maturation of protein 2C and/or RNA replication complexes necessary for the initiation of RNA replication.

Identification and properties of the RNA-dependent RNA polymerase of hepatitis C virus

Hepatitis C virus (HCV) is the major etiological agent of non-A, non-B post-transfusion hepatitis. Its genome, a (+)-stranded RNA molecule of approximately 9.4 kb, encodes a large polyprotein that is processed by viral and cellular proteases into at least nine different viral polypeptides. As with other (+)-strand RNA viruses, the replication of HCV is thought to proceed via the initial synthesis of a complementary (-) RNA strand, which serves, in turn, as a template for the production of progeny (+)-strand RNA molecules. An RNA-dependent RNA polymerase has been postulated to be involved in both of these steps. Using the heterologous expression of viral proteins in insect cells, we present experimental evidence that an RNA-dependent RNA polymerase is encoded by HCV and that this enzymatic activity is the function of the 65 kDa non-structural protein 5B (NS5B). The characterization of the HCV RNA-dependent RNA polymerase product revealed that dimer-sized hairpin-like RNA molecules are generated in vitro, indicating that NS5B-mediated RNA polymerization proceeds by priming on the template via a 'copy-back' mechanism. In addition, the purified HCV NS5B protein was shown to perform RNA- or DNA oligonucleotide primer-dependent RNA synthesis on templates with a blocked 3' end or on homopolymeric templates. These results represent a first important step towards a better understanding of the life cycle of the HCV.

Comparison of the replication of positive-stranded RNA viruses of plants and animals

It is clear from the experimental data that there are some similarities in RNA replication for all eukaryotic positive-stranded RNA viruses—that is, the mechanism of polymerization of the nucleotides is probably similar for all. It is noteworthy that all mechanisms appear to utilize host membranes as a site of replication. Membranes appear to function not only as a way of compartmentalizing virus RNA replication but also appear to have a central role in the organization and functioning of the replication complex, and further studies in this area are needed. Within virus supergroups, similarities are evident between animal and plant viruses—for example, in the nature and arrangements of replication genes and in sequence similarities of functional domains. However, it is also clear that there has been considerable divergence, even within supergroups. For example, the animal alpha-viruses have evolved to encode proteinases which play a central controlling function in the replication cycle, whereas this is not common in the plant alpha-like viruses and even when it occurs, as in the tymoviruses, the strategies that have evolved appear to be significantly different. Some of the divergence could be host-dependent and the increasing interest in the role of host proteins in replication should be fruitful in revealing how different systems have evolved. Finally, there are virus supergroups that appear to have no close relatives between animals and plants, such as the animal coronavirus-like supergroup and the plant carmo-like supergroup.

Poliovirus protein 3AB forms a complex with and stimulates the activity of the viral RNA polymerase, 3Dpol

Poliovirus protein 3B (also known as VPg) is covalently linked to the 5' ends of both genomic and antigenomic viral RNA. Genetic and biochemical studies have implicated protein 3AB, the membrane-bound precursor to VPg, in the initiation of genomic RNA synthesis. We have purified 3AB to near homogeneity following thrombin cleavage of purified glutathione S-transferase-3AB. When added to transcription reaction mixtures catalyzed by poliovirus RNA polymerase (3Dpol), 3AB stimulated RNA synthesis up to 75-fold with oligo(U)-primed virion RNA, globin mRNA, and unprimed synthetic, full-length minus-strand viral RNA as the templates. Synthetic VPg also stimulated RNA synthesis but was only 1 to 2% as effective as 3AB on a molar basis. The increased level of transcription was not the result of enhancing the elongation rate of the polymerase. No evidence was found for uridylylation of 3AB or for covalent linkage to RNA transcription products. 3AB sedimented as a multimer in glycerol gradients. In the presence of the polymerase, the sedimentation rate of both proteins increased, suggesting the formation of a complex. Detergent prevented both multimerization and complex formation. The polymerase also bound to immobilized glutathione S-transferase-3AB; this procedure was used to purify the polymerase to near homogeneity. These results suggest a mechanism for bringing together 3AB, 3Dpol (or its precursor 3CD), and viral RNA in host cell membranous vesicles in which all viral RNA synthesis occurs.

Complete replication of poliovirus in vitro: preinitiation RNA replication complexes require soluble cellular factors for the synthesis of VPg-linked RNA

Translation of poliovirion RNA in HeLa S10 extracts resulted in the formation of RNA replication complexes which catalyzed the asymmetric replication of poliovirus RNA. Synthesis of poliovirus RNA was detected in unfractionated HeLa S10 translation reactions and in RNA replication complexes isolated from HeLa S10 translation reactions by pulse-labeling with [32P]CTP. The RNA replication complexes formed in vitro contained replicative-intermediate RNA and were enriched in viral protein 3CD and the membrane-associated viral proteins 2C, 2BC, and 3AB. Genome-length poliovirus RNA covalently linked to VPg was synthesized in large amounts by the replication complexes. RNA replication was highly asymmetric, with predominantly positive-polarity RNA products. Both anti-VPg antibody and guanidine HCl inhibited RNA replication and virus formation in the HeLa S10 translation reactions without affecting viral protein synthesis. The inhibition of RNA synthesis by guanidine was reversible. The reversible nature of guanidine inhibition was used to demonstrate the formation of preinitiation RNA replication complexes in reaction mixes containing 2 mM guanidine HCl. Preinitiation complexes sedimented upon centrifugation at 15,000 x g and initiated RNA replication upon their resuspension in reaction mixes lacking guanidine. Initiation of RNA synthesis by preinitiation complexes did not require active protein synthesis or the addition of soluble viral proteins. Initiation of RNA synthesis by preinitiation complexes, however, was absolutely dependent on soluble HeLa cytoplasmic factors. Preinitiation complexes also catalyzed the formation of infectious virus in reaction mixes containing exogenously added capsid proteins. The titer of infectious virus produced in such trans-encapsidation reactions reached 4 x 10(7) PFU/ml. The HeLa S10 translation-RNA replication reactions represent an efficient in vitro system for authentic poliovirus replication, including protein synthesis, polyprotein processing, RNA replication, and virus assembly.

Synthesis of novel products in vitro by an RNA-dependent RNA polymerase

RNA-dependent RNA polymerase from turnip crinkle virus-infected turnip transcribes both strands of a virus-associated satellite RNA, sat-RNA C (356 bases), in vitro. While both plus- and minus-strand sat-RNA C can direct the synthesis of full-length complementary-strand products, transcription of minus-strand RNA also generates two non-template-sized products, L-RNA and S-RNA (C. Song and A. E. Simon, Proc. Natl. Acad. Sci. USA 91:8792-8796, 1994). Here we report that synthesis of L-RNA and S-RNA results from terminal elongation of the 3' end of the template. L-RNA has a panhandle structure and is composed of minus-strand template covalently linked to newly synthesized RNA complementary to its 5' 190 bases. S-RNA is composed of template covalently linked to its full-length complementary strand. All minus-strand templates tested yielded S-RNA. However, synthesis of L-RNA was affected by deletion of the 3' end of the minus-strand template or several internal regions and base alterations near the 5' end or in an internal sequence immediately upstream from the template-product junction that could potentially form a heteroduplex with the 3' end. Furthermore, mutations that disrupted or restored a stem-loop involved in RNA recombination in vivo affected the level of L-RNA produced in vitro, suggesting that the mechanisms for intramolecular formation of panhandle RNAs and intermolecular RNA recombination involve similar features.

The antiviral compound enviroxime targets the 3A coding region of rhinovirus and poliovirus

Enviroxime is an antiviral compound that inhibits the replication of rhinoviruses and enteroviruses. We have explored the mechanism of action of enviroxime by using poliovirus type 1 and human rhinovirus type 14 as model systems. By varying the time of drug addition to virus-infected cells, we determined that enviroxime could be added several hours postinfection without significant loss of inhibition. This suggested that the drug targeted a step involved in RNA replication or protein processing. To identify this target, we mapped 23 independent mutations in mutants that could multiply in the presence of 1 microgram of enviroxime per ml. Each of these mutants contained a single nucleotide substitution that altered one amino acid in the 3A coding region. Using oligonucleotide-directed mutagenesis of cDNA clones, we have confirmed that these single-amino-acid substitutions are sufficient to confer the resistance phenotype. In addition, we conducted two experiments to support the hypothesis that enviroxime inhibits a 3A function. First, we determined by dot blot analysis of RNA from poliovirus-infected cells that enviroxime preferentially inhibits synthesis of the viral plus strand. Second, we demonstrated that enviroxime inhibits the initiation of plus-strand RNA synthesis as measured by the addition of [32P]uridine to 3AB in poliovirus crude replication complexes. To our knowledge, this is the first evidence that 3A can be targeted by antiviral drugs. We anticipate that enviroxime will be a useful tool for investigating the natural function of the 3A protein.

Functional oligomerization of poliovirus RNA-dependent RNA polymerase

Using a hairpin primer/template RNA derived from sequences present at the 3' end of the poliovirus genome, we investigated the RNA-binding and elongation activities of highly purified poliovirus 3D polymerase. We found that surprisingly high polymerase concentrations were required for efficient template utilization. Binding of template RNAs appeared to be the primary determinant of efficient utilization because binding and elongation activities correlated closely. Using a three-filter binding assay, polymerase binding to RNA was found to be highly cooperative with respect to polymerase concentration. At pH 5.5, where binding was most cooperative, a Hill coefficient of 5 was obtained, indicating that several polymerase molecules interact to retain the 110-nt RNA in a filter-bound complex. Chemical crosslinking with glutaraldehyde demonstrated physical polymerase-polymerase interactions, supporting the cooperative binding data. We propose a model in which poliovirus 3D polymerase functions both as a catalytic polymerase and as a cooperative single-stranded RNA-binding protein during RNA-dependent RNA synthesis.

RNA-dependent RNA polymerase from plants infected with turnip crinkle virus can transcribe (+)- and (-)-strands of virus-associated RNAs

RNA-dependent RNA polymerase (RdRp) was solubilized from membranes of turnip infected with turnip crinkle virus (TCV), a single-stranded, monopartite RNA virus. The RdRp activity could be separated into three peaks by Sephacryl S500HR chromatography. RdRp from peak I, which contained substantial amounts of endogenous TCV genomic RNA, and peak II were template-specific, synthesizing full-length complementary strands of exogenous TCV subviral RNAs but not control RNA templates. Peak III RdRp was nonspecific, synthesizing full-sized products for all added RNA templates. Peak II RdRp transcribed several different TCV satellite (sat) and defective interfering RNA templates in both (+)- and (-)-sense orientations but did not transcribe (+)-strands of satellite RNAs associated with unrelated viruses. Monomeric-length sat-RNA C was synthesized from a template containing as many as 220 nonsatellite bases at the 3' ends of either (+)- or (-)-strands, indicating that the RdRp was able to recognize 3'-end sequences in an internal location. Deletion of 95-242 bases from the 3' end of (+)-strand sat-RNA C abolished the synthesis of template-length product. However, transcription of template-length products was not affected by the deletion of at least 257 bases from the 3' end of (-)-strand sat-RNA C template (leaving only the 100 5'-terminal residues), implying that different mechanisms exist for synthesis of (+)-and (-)-strand satellite RNA in vitro.

Characteristics of the poliovirus replication complex

In the infected cell, the poliovirus replication complex (RC) is found in the center of a rosette formed by many virus-induced vesicles. The RC is attached to the vesicular membranes and contains a compact central part which encloses the replication forks of the replicative intermediate and all proteins necessary for strand elongation. The growing plus strands of the replicative intermediate protrude from the central part of the RC, but are still enclosed by membraneous structures of the rosette. After completion, progeny 36S RNA is set free at the surface of the rosette. In an in vitro transcription system, isolated replication complex-containing rosettes are active in initiation, elongation and maturation (release) of plus strand progeny RNA. Full functionality of the RC depends on an intact structural framework of all membraneous components of the rosette.

RNA duplex unwinding activity of poliovirus RNA-dependent RNA polymerase 3Dpol

The ability of highly purified preparations of poliovirus RNA-dependent RNA polymerase, 3Dpol, to unwind RNA duplex structures was examined during a chain elongation reaction in vitro. Using an antisense RNA prehybridized to an RNA template, we show that poliovirus polymerase can elongate through a highly stable RNA duplex of over 1,000 bp. Radiolabeled antisense RNA was displaced from the template during the reaction, and product RNAs which were equal in length to the template strand were synthesized. Unwinding did not occur in the absence of chain elongation and did not require hydrolysis of the gamma-phosphate of ATP. The rate of elongation through the duplex region was comparable to the rate of elongation on the single-stranded region of the template. Parallel experiments conducted with avian myeloblastosis virus reverse transcriptase showed that this enzyme was not able to unwind the RNA duplex, suggesting that strand displacement by poliovirus 3Dpol is not a property shared by all polymerases.

Coupled translation and replication of poliovirus RNA in vitro: synthesis of functional 3D polymerase and infectious virus

Poliovirus RNA polymerase and infectious virus particles were synthesized by translation of virion RNA in vitro in HeLa S10 extracts. The in vitro translation reactions were optimized for the synthesis of the viral proteins found in infected cells and in particular the synthesis of the viral polymerase 3Dpol. There was a linear increase in the amount of labeled protein synthesized during the first 6 h of the reaction. The appearance of 3Dpol in the translation products was delayed because of the additional time required for the proteolytic processing of precursor proteins. 3Dpol was first observed at 1 h in polyacrylamide gels, with significant amounts being detected at 6 h and later. Initial attempts to assay for polymerase activity directly in the translation reaction were not successful. Polymerase activity, however, was easily detected by adding a small amount (3 microliters) of translation products to a standard polymerase assay containing poliovirion RNA. Full-length minus-strand RNA was synthesized in the presence of an oligo(U) primer. In the absence of oligo(U), product RNA about twice the size of virion RNA was synthesized in these reactions. RNA stability studies and plaque assays indicated that a significant fraction of the input virion RNA in the translation reactions was very stable and remained intact for 20 h or more. Plaque assays indicated that infectious virus was synthesized in the in vitro translation reactions. Under optimal conditions, the titer of infectious virus produced in the in vitro translation reactions was greater than 100,000 PFU/ml. Virus was first detected at 6 h and increased to maximum levels by 12 h. Overall, the kinetics of poliovirus replication (protein synthesis, polymerase activity, and virus production) observed in the HeLa S10-initiation factor in vitro translation reactions were similar to those observed in infected cells.

Structural and functional characterization of the poliovirus replication complex

Two populations of membrane-bound replication complexes were isolated from poliovirus-infected HEp-2 cells by sucrose gradient centrifugation. The two fractions show similar ultrastructural features: the replication complex is enclosed in a rosettelike shell of virus-induced vesicles and contains a very tightly packed second membrane system (compact membranes). The vesicular fraction, which bands in 30% sucrose, contains replicative intermediate (RI) and 36S RNA. The fraction banding in 45% sucrose contains only minute amounts of RI and contains mainly 36S RNA, two-thirds of which is encapsidated. In vitro, the two fractions show similar RNA synthesizing capacities and produce 36S plus-strand RNA. Dissolving the membranes within and around synthetically active replication complexes with sodium deoxycholate abolishes the completion of 36S RNA but still allows elongation in the RI. Our findings suggest an architecture of the replication complex that has the nascent plus strands on the RI enclosed in the compact membranes and the replication forks wrapped additionally in protein. Plus-strand RNA can be localized by in situ hybridization with a biotinylated riboprobe between the replication complex and the rosette of the virus-induced vesicles. It was found that the progeny RNA strands are set free soon after completion from the replication complex at the sites where the compact membranes within the replication complex are in close contact with the surrounding virus-induced vesicles.

VPg gene amplification correlates with infective particle formation in foot-and-mouth disease virus

In order to analyze the function of VPg amplification in aphthoviruses, we have undertaken the first mutational analysis of the repetitive VPg-coding region using an improved foot-and-mouth disease virus (FMDV) cDNA clone from which infective viral RNA was synthesized. A set of VPg mutants was constructed by site-directed mutagenesis which includes different VPg deletion mutations, a VPg insertion mutation, and amino acid residue replacement mutations that interfere with binding of the VPg protein to the viral RNA and with its proteolytic processing. Our results revealed that an amazing flexibility in the number of VPgs is tolerated in FMDV. Optimal viability is given when three VPgs are encoded. Deletion as well as insertion of one VPg gene still resulted in infective particle production. Infective particle formation was observed as long as one VPg remained intact. No obvious differences in the individual VPg molecules with regard to their promoting viral RNA synthesis were observed, indicating that all three VPgs can act equally in FMDV replication. Mutant polyprotein processing was comparable to that of the wild-type virus. However, VPg mutants showed reduced viral RNA synthesis levels after infection. The levels of viral RNA synthesis and infective particle formation were found to correlate with the number of functional VPgs left in the mutant virus. These findings suggest a direct VPg gene dosage effect on viral RNA synthesis, with a secondary effect on infective particle formation.

Expression, purification, and properties of recombinant encephalomyocarditis virus RNA-dependent RNA polymerase

Encephalomyocarditis (EMC) virus RNA-dependent RNA polymerase was expressed in Escherichia coli as a fusion protein with glutathione S-transferase (GST), which allowed easy purification of the fusion protein by affinity chromatography on immobilized glutathione. Inclusion of a thrombin cleavage site between the GST carrier and the viral enzyme facilitated the release of purified mature EMC virus RNA polymerase from the GST carrier by proteolysis with thrombin. The purified recombinant enzyme has a molecular mass of about 52 kDa and is recognized by polyclonal immune serum raised against a peptide sequence corresponding to the C-terminal region of the protein. The recombinant enzyme comigrates with immunoprecipitated EMC virus RNA polymerase from infected mouse L929 cell extracts when run in parallel lanes on a sodium dodecyl sulfate-polyacrylamide gel. The enzyme exhibits rifampin-resistant, poly(A)-dependent poly(U) polymerase activity and RNA polymerase activity, which are both oligo(U) dependent. Template-size products are synthesized in in vitro reactions with EMC virus genomic RNA or globin mRNA. The availability of recombinant EMC virus RNA polymerase in a purified form will allow biochemical analysis of its role in the replication of the virus as well as structure-function studies of this unique class of enzyme.

Role of a viral membrane polypeptide in strand-specific initiation of poliovirus RNA synthesis

A molecular genetic analysis has been combined with an in vitro biochemical approach to define the functional interactions required for nucleotidyl protein formation during poliovirus RNA synthesis. A site-directed lesion into the hydrophobic domain of a viral membrane protein produced a mutant virus that is defective in RNA synthesis at 39 degrees C. The phenotypic expression of this lesion affects initiation of RNA synthesis, in vitro uridylylation of the genome-linked protein (VPg), and the in vivo synthesis of plus-strand viral RNAs. Our results support a model that employs a viral membrane protein as carrier for VPg in the initiation of plus-strand RNA synthesis. Our data also suggest that a separate mechanism could be used in the initiation of minus-strand RNA synthesis, thereby providing a means for strand-specific regulation of picornavirus RNA replication.

Encephalomyocarditis virus RNA polymerase preparations, with and without RNA helicase activity

RNA template- and primer-dependent preparations of RNA polymerase were purified from encephalomyocarditis virus-infected Krebs-2 cells, using a three-step chromatographic procedure. The RNA duplex-unwinding activity of these preparations was investigated by two assays, using a partially double-stranded RNA template (encephalomyocarditis virus RNA annealed with a long segment of antisense transcript). Less purified preparations of the polymerase appeared to be able to efficiently displace, in an ATP-dependent and RNA elongation-dependent reaction, the antisense segment from the template. However, upon a more extensive purification, the unwinding activity of the RNA polymerase preparations was lost.

A functional ribonucleoprotein complex forms around the 5' end of poliovirus RNA

The existence of a computer-predicted cloverleaf structure for the first 100 nucleotides at the 5' end of poliovirus RNA was verified by site-directed mutagenesis and by chemical and RNAase probing. Mutations that modified the cloverleaf in the positive strand but not the negative strand were lethal to the virus. This RNA cloverleaf structure binds a cellular protein and the viral proteins 3Cpro and 3Dpol. Mutations in specific regions of the RNA cloverleaf prevented this binding. Mutations in either 3Cpro or the RNA that disrupted ribonucleoprotein complex formation inhibited virus growth and selectively affected positive strand RNA accumulation. Phenotypic reversion of these mutations restored the ability to form the complex. Thus, a cloverleaf structure in poliovirus RNA plays a central role in organizing viral and cellular proteins involved in positive strand production.

Identification of a nucleotide deletion in parts of polypeptide 3A in two independent attenuated aphthovirus strains

A set of antisera specific for each viral polypeptide of foot-and-mouth disease virus was used to provide a full comparison of polypeptides of two strains attenuated for cattle with respect to their parental virulent strains. Both attenuated strains, belonging to serotypes O1 Campos and C3 Resende, were obtained through serial passages of the corresponding virulent strains in chicken embryos. Although mutations were scattered throughout the genome, both attenuated strains showed an electrophoretic mobility on sodium dodecyl sulfate-polyacrylamide gel electrophoresis of viral polypeptide 3A faster than that of their respective wild-type strains. To determine the nature of this alteration, the nucleotide sequences of the genomic region encoding this polypeptide were determined. Comparative sequence analysis of wild-type and attenuated strains revealed 57 and 60 nucleotide deletions in the attenuated strains O1 Campos and C3 Resende, respectively. These studies, in conjunction with our previous analysis of recombinant viruses between wild-type and attenuated strains, which concluded that the major determinants of attenuation are located in the 3' half of the viral genome, strongly suggest that the alteration in polypeptide 3A of the attenuated strains is important for their reduced virulence in cattle.

Complete nucleotide sequence of infectious Coxsackievirus B3 cDNA: two initial 5' uridine residues are regained during plus-strand RNA synthesis

A full-length reverse-transcribed, infectious cDNA copy of coxsackievirus B3 (CVB3) was used to determine the nucleotide sequence of this cardiotropic enterovirus. Comparison of the nucleotide sequence and the deduced amino acid sequence of the viral precursor polyprotein with the sequences of other group B coxsackieviruses (CVB1 and CVB4) demonstrates a high degree of genetic identity. They share about 80% homology at the nucleotide level and about 90% when the amino acid sequences of the polyproteins are compared. The potential processing sites of the coxsackievirus polyproteins, as deduced from alignment with the poliovirus sequence, are conserved among these enteroviruses with the exception of the cleavage sites between VP1 and 2Apro and between polypeptides 2B and 2C. Comparison of the 5' termini of the enteroviral genomes reveals a high degree of identity, including the initial 5' consensus UUAAAACAGC, suggesting essential functions in virus replication. An important finding concerning the molecular basis of infectivity was that both recombinant CVB3 cDNA and in vitro-synthesized CVB3 RNA transcripts are infectious, although two initial 5' uridine residues found on the authentic CVB3 RNA were missing. Here, we report that cDNA-generated CVB3, as well as CVB3 generated by in vitro-synthesized RNA transcripts, regains the authentic initial 5' uridine residues during replication in transfected cells, indicating that the picornaviral primer molecule VPg-pUpU may be uridylylated in a template-independent fashion. The generation of virus or virus mutants with infectious recombinant CVB3 cDNA and in vitro-synthesized infectious CVB3 transcripts should provide a valuable means for studying the molecular basis of the pathogenicity of this cardiotropic enterovirus.

Identification and characterization of the woodchuck hepatitis virus origin of DNA replication

Replication of the woodchuck hepatitis virus (WHV) genome requires the synthesis of minus-strand DNA from an RNA template, the pregenome, by reverse transcription. During this reaction, the 5' end of minus-strand DNA becomes covalently linked to a protein. The position of the 5' end of minus-strand DNA was identified previously, but the initiation site for DNA synthesis on pregenomic RNA remained ambiguous because of a sequence repetition at the termini of the RNA template for reverse transcription. Employing a recently designed expression vector for the production of infectious WHV, we localized the origin of minus-strand DNA synthesis to the 3' end of pregenomic RNA. In addition, we identified the nucleotide sequences on pregenomic RNA that provide the signal for the initiation of reverse transcription. Removal of this signal sequence from pregenomic RNA abolished minus-strand DNA synthesis. Insertion of a DNA oligomer bearing this signal sequence at the 3' end of pregenomic RNA restored the production of minus-strand DNA joined to protein. Our results support a model in which protein is the primer for reverse transcription of minus-strand DNA of WHV.

Self-catalyzed linkage of poliovirus terminal protein VPg to poliovirus RNA

The poliovirus terminal protein, VPg, was covalently linked to poliovirus RNA in a reaction that required synthetic VPg, Mg2+, and a replication intermediate synthesized in vitro. The VPg linkage reaction did not require the viral polymerase, host factor, or ribonucleoside triphosphates and was specific for template-linked minus-strand RNA synthesized on poliovirion RNA. The covalent nature of the bond between VPg and the RNA was demonstrated by the isolation of VPg-pUp from VPg-linked RNA. A model is proposed in which the tyrosine residue in VPg forms a phosphodiester bond with the 5'UMP in minus-strand RNA in a self-catalyzed transesterification reaction. It appears that either the RNA, VPg, or a combination of both forms the catalytic center for this reaction.

Purification and properties of poliovirus RNA polymerase expressed in Escherichia coli

A cDNA clone encoding the RNA polymerase of poliovirus has been expressed in Escherichia coli under the transcriptional control of a T7 bacteriophage promoter. The poliovirus enzyme was designed to contain only a single additional amino acid, the N-terminal methionine. The recombinant enzyme has been purified to near homogeneity, and polyclonal antibodies have been prepared against it. The enzyme exhibits poly(A)-dependent oligo(U)-primed poly(U) polymerase activity as well as RNA polymerase activity. In the presence of an oligo(U) primer, the enzyme catalyzes the synthesis of a full-length copy of either poliovirus or globin RNA templates. In the absence of added primer, RNA products up to twice the length of the template are synthesized. When incubated in the presence of a single nucleoside triphosphate, [alpha-32P]UTP, the enzyme catalyzes the incorporation of radioactive label into template RNA. These results are discussed in light of previously proposed models of poliovirus RNA synthesis in vitro.

Enzymatic activity of poliovirus RNA polymerase synthesized in Escherichia coli from viral cDNA

Plasmids have been constructed that contain DNA sequences that direct the expression of the poliovirus RNA-dependent RNA polymerase, in the form of recombinant fusion proteins. Inclusion of an additional gene for the poliovirus protease results in cleavage of the fusion protein to yield a 52-kDa, enzymatically active, polymerase protein, apparently identical to the functional enzyme isolated from virus-infected HeLa cells. A large amount of polymerase protein accumulates as particulate or insoluble material in bacteria, and this protein has little or no activity. However, significant amounts of soluble, active enzyme are recovered, such that the resulting specific activity of crude bacterial extracts is greater than that obtained from virus-infected HeLa cells. Purification of the enzyme from Escherichia coli is readily accomplished, and yields a preparation that will copy poliovirion RNA as template, in the presence of oligo(U) primer. The availability of cloned DNA sequences encoding catalytically active RNA polymerase will allow genetic manipulations to initiate structure-function studies of this enzyme.

Viral RNA polymerases

Recent progress in molecular biological techniques revealed that genomes of animal viruses are complex in structure, for example, with respect to the chemical nature (DNA or RNA), strandedness (double or single), genetic sense (positive or negative), circularity (circle or linear), and so on. In agreement with this complexity in the genome structure, the modes of transcription and replication are various among virus families. The purpose of this article is to review and bring up to date the literature on viral RNA polymerases involved in transcription of animal DNA viruses and in both transcription and replication of RNA viruses. This review shows that the viral RNA polymerases are complex in both structure and function, being composed of multiple subunits and carrying multiple functions. The functions exposed seem to be controlled through structural interconversion.

Primer-dependent synthesis of covalently linked dimeric RNA molecules by poliovirus replicase

Poliovirus-specific RNA-dependent RNA polymerase (replicase, 3Dpol) was purified from HeLa cells infected with poliovirus. The purified enzyme preparation contained two proteins of apparent molecular weights 63,000 and 35,000. The 63,000-Mr polypeptide was virus-specific RNA-dependent RNA polymerase, and the 35,000-Mr polypeptide was of host origin. Both polypeptides copurified through five column chromatographic steps. The purified enzyme preparation catalyzed synthesis of covalently linked dimeric RNA products from a poliovirion RNA template. This reaction was absolutely dependent on added oligo(U) primer, and the dimeric product appeared to be made of both plus- and minus-strand RNA molecules. Experiments with 5' [32P]oligo(U) primer and all four unlabeled nucleotides suggest that the viral replicase elongates the primer, copying the poliovirion RNA template (plus strand), and the newly synthesized minus strand snaps back on itself to generate a template-primer structure which is elongated by the replicase to form covalently linked dimeric RNA molecules. Kinetic studies showed that a partially purified preparation of poliovirus replicase contains a nuclease which can cleave the covalently linked dimeric RNA molecules, generating template-length RNA products.

Action of 3-methylquercetin on poliovirus RNA replication

3-Methylquercetin is a natural flavone that powerfully blocks poliovirus replication. This compound inhibits selectively poliovirus RNA synthesis both in infected cells and in cell-free systems. Poliovirus double-stranded RNA (replicative forms) is still made in the presence of this inhibitor, whereas the synthesis of single-stranded RNA and the formation of replicative intermediates are drastically blocked.

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.

Uridylylation of the genome-linked protein of poliovirus in vitro is dependent upon an endogenous RNA template

The properties of an in vitro replication system derived from a membrane fraction (crude replication complex, CRC) of poliovirus-infected HeLa cells were examined. This system was capable of producing the nucleotidyl-proteins VPg-pU and VPg-pUpU. Due to high intrinsic phosphoesterase(s) activity and endogenous nucleoside triphosphate pools the yield of labeled product was low. Treatment of CRC with DEAE-cellulose and addition of an ATP generating system resulted in a dramatic increase in the level of nucleotidyl-proteins formed. The capacity to form VPg-pU and VPg-pUpU could be completely abolished by pretreatment of CRC with nuclease, an observation suggesting that the uridylylation of VPg is a template-dependent reaction.

Poliovirus snapback double-stranded RNA isolated from infected HeLa cells is deficient in poly(A)

A portion of poliovirus double-stranded RNA (25 to 50%) isolated from infected HeLa cells contains hairpin loops at one end of the duplex structure. These structures rapidly reformed double-stranded molecules after denaturation and appeared as molecules of up to two times genome length upon electrophoresis in denaturing agarose gels. A second form of poliovirus double-stranded RNA was readily denaturable into genome length strands. When the hairpin RNA was treated with S1 nuclease, subsequent denaturation resulted in formation of strands of up to genome length. Hairpin molecules contained very little, if any, poly(A) sequences, suggesting that the hairpin forms after nucleolytic removal of the 3' end of plus-strand templates. We conclude that the hairpin double-stranded RNA found in infected cells is likely generated by intracellular nicking and self-priming and that it does not represent an intermediate in the process of RNA replication.