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

An Extended Primer Grip of Picornavirus Polymerase Facilitates Sexual RNA Replication Mechanisms

Picornaviruses have both asexual and sexual RNA replication mechanisms. Asexual RNA replication mechanisms involve one parental template, whereas sexual RNA replication mechanisms involve two or more parental templates. Because sexual RNA replication mechanisms counteract ribavirin-induced error catastrophe, we selected for ribavirin-resistant poliovirus to identify polymerase residues that facilitate sexual RNA replication mechanisms. We used serial passage in ribavirin, beginning with a variety of ribavirin-sensitive and ribavirin-resistant parental viruses. Ribavirin-sensitive virus contained an L420A polymerase mutation, while ribavirin-resistant virus contained a G64S polymerase mutation. A G64 codon mutation (G64Fix) was used to inhibit emergence of G64S-mediated ribavirin resistance. Revertants (L420) or pseudorevertants (L420V and L420I) were selected from all independent lineages of L420A, G64Fix L420A, and G64S L420A parental viruses. Ribavirin resistance G64S mutations were selected in two independent lineages, and novel ribavirin resistance mutations were selected in the polymerase in other lineages (M299I, M323I, M392V, and T353I). The structural orientation of M392, immediately adjacent to L420 and the polymerase primer grip region, led us to engineer additional polymerase mutations into poliovirus (M392A, M392L, M392V, K375R, and R376K). L420A revertants and pseudorevertants (L420V and L420I) restored efficient viral RNA recombination, confirming that ribavirin-induced error catastrophe coincides with defects in sexual RNA replication mechanisms. Viruses containing M392 mutations (M392A, M392L, and M392V) and primer grip mutations (K375R and R376K) exhibited divergent RNA recombination, ribavirin sensitivity, and biochemical phenotypes, consistent with changes in the fidelity of RNA synthesis. We conclude that an extended primer grip of the polymerase, including L420, M392, K375, and R376, contributes to the fidelity of RNA synthesis and to efficient sexual RNA replication mechanisms.IMPORTANCE Picornaviruses have both asexual and sexual RNA replication mechanisms. Sexual RNA replication shapes picornavirus species groups, contributes to the emergence of vaccine-derived polioviruses, and counteracts error catastrophe. Can viruses distinguish between homologous and nonhomologous partners during sexual RNA replication? We implicate an extended primer grip of the viral polymerase in sexual RNA replication mechanisms. By sensing RNA sequence complementarity near the active site, the extended primer grip of the polymerase has the potential to distinguish between homologous and nonhomologous RNA templates during sexual RNA replication.

Effects of TDP2/VPg Unlinkase Activity on Picornavirus Infections Downstream of Virus Translation

In this study, we characterized the role of host cell protein tyrosyl-DNA phosphodiesterase 2 (TDP2) activity, also known as VPg unlinkase, in picornavirus infections in a human cell model of infection. TDP2/VPg unlinkase is used by picornaviruses to remove the small polypeptide, VPg (Virus Protein genome-linked, the primer for viral RNA synthesis), from virus genomic RNA. We utilized a CRISPR/Cas-9-generated TDP2 knock out (KO) human retinal pigment epithelial-1 (hRPE-1) cell line, in addition to the wild type (WT) counterpart for our studies. We determined that in the absence of TDP2, virus growth kinetics for two enteroviruses (poliovirus and coxsackievirus B3) were delayed by about 2 h. Virus titers were reduced by ~2 log10 units for poliovirus and 0.5 log10 units for coxsackievirus at 4 hours post-infection (hpi), and by ~1 log10 unit at 6 hpi for poliovirus. However, virus titers were nearly indistinguishable from those of control cells by the end of the infectious cycle. We determined that this was not the result of an alternative source of VPg unlinkase activity being activated in the absence of TPD2 at late times of infection. Viral protein production in TDP2 KO cells was also substantially reduced at 4 hpi for poliovirus infection, consistent with the observed growth kinetics delay, but reached normal levels by 6 hpi. Interestingly, this result differs somewhat from what has been reported previously for the TDP2 KO mouse cell model, suggesting that either cell type or species-specific differences might be playing a role in the observed phenotype. We also determined that catalytically inactive TDP2 does not rescue the growth defect, confirming that TDP2 5' phosphodiesterase activity is required for efficient virus replication. Importantly, we show for the first time that polysomes can assemble efficiently on VPg-linked RNA after the initial round of translation in a cell culture model, but both positive and negative strand RNA production is impaired in the absence of TDP2 at mid-times of infection, indicating that the presence of VPg on the viral RNA affects a step in the replication cycle downstream of translation (e.g., RNA synthesis). In agreement with this conclusion, we found that double-stranded RNA production (a marker of viral RNA synthesis) is delayed in TDP2 KO RPE-1 cells. Moreover, we show that premature encapsidation of nascent, VPg-linked RNA is not responsible for the observed virus growth defect. Our studies provide the first lines of evidence to suggest that either negative- or positive-strand RNA synthesis (or both) is a likely candidate for the step that requires the removal of VPg from the RNA for an enterovirus infection to proceed efficiently.

Picornaviral polymerase structure, function, and fidelity modulation

Like all positive strand RNA viruses, the picornaviruses replicate their genomes using a virally encoded RNA-dependent RNA polymerase enzyme known as 3Dpol. Over the past decade we have made tremendous advances in our understanding of 3Dpol structure and function, including the discovery of a novel mechanism for closing the active site that allows these viruses to easily fine tune replication fidelity and quasispecies distributions. This review summarizes current knowledge of picornaviral polymerase structure and how the enzyme interacts with RNA and other viral proteins to form stable and processive elongation complexes. The picornaviral RdRPs are among the smallest viral polymerases, but their fundamental molecular mechanism for catalysis appears to be generally applicable as a common feature of all positive strand RNA virus polymerases.

Reversion to wildtype of a mutated and nonfunctional coxsackievirus B3CRE(2C)

The cis-acting replication element (CRE) in the 2C protein coding region [CRE(2C)] of enteroviruses (EV) facilitates the addition of two uridine residues (uridylylation) onto the virus-encoded protein VPg in order for it to serve as the RNA replication primer. We demonstrated that coxsackievirus B3 (CVB3) is replication competent in the absence of a native (uridylylating) CRE(2C) and also demonstrated that lack of a functional CRE(2C) led to generation of 5' terminal genomic deletions in the CVB3 CRE-knock-out (CVB3-CKO) population. We asked whether reversion of the mutated CRE(2C) occurred, thus permitting sustained replication, and when were 5' terminal deletions generated during replication. Virions were isolated from HeLa cells previously electroporated with infectious CVB3-CKO T7 transcribed RNA or from hearts and spleens of mice after transfection with CVB3-CKO RNA. Viral RNA was isolated in order to amplify the CRE(2C) coding region and the genomic 5' terminal sequences. Sequence analysis revealed reversion of the CVB3-CKO sequence to wildtype occurs by 8 days post-electroporation of HeLa cells and by 20days post-transfection in mice. However, 5' terminal deletions evolve prior to these times. Reversion of the CRE(2C) mutations to wildtype despite loss of the genomic 5' termini is consistent with the hypothesis that an intact CRE(2C) is inherently vital to EV replication even when it is not enabling efficient positive strand initiation.

Initiation of protein-primed picornavirus RNA synthesis

Plus strand RNA viruses use different mechanisms to initiate the synthesis of their RNA chains. The Picornaviridae family constitutes a large group of plus strand RNA viruses that possess a small terminal protein (VPg) covalently linked to the 5'-end of their genomes. The RNA polymerases of these viruses use VPg as primer for both minus and plus strand RNA synthesis. In the first step of the initiation reaction the RNA polymerase links a UMP to the hydroxyl group of a tyrosine in VPg using as template a cis-replicating element (cre) positioned in different regions of the viral genome. In this review we will summarize what is known about the initiation reaction of protein-primed RNA synthesis by the RNA polymerases of the Picornaviridae. As an example we will use the RNA polymerase of poliovirus, the prototype of Picornaviridae. We will also discuss models of how these nucleotidylylated protein primers might be used, together with viral and cellular replication proteins and other cis-replicating RNA elements, during minus and plus strand RNA synthesis.

Picornavirus RNA polyadenylation by 3D(pol), the viral RNA-dependent RNA polymerase

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Picornaviral RdRPs are responsible for the polyadenylation of viral RNA.

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Reiterative transcription mechanisms occur during replication of poly(A) tails.

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Conserved RdRP structures influence the size of poly(A) tails.

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Common features of picornavirus RdRPs and telomerase reverse transcriptase.

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Poly(A) tails are a telomere of picornavirus RNA genomes.

Poly(A) tails are functionally important features of all picornavirus RNA genomes. Some viruses have genomes with relatively short poly(A) tails (encephalomyocarditis virus) whereas others have genomes with longer poly(A) tails (polioviruses and rhinoviruses). Here we review the polyadenylation of picornavirus RNA as it relates to the structure and function of 3D^pol. Poliovirus 3D^pol uses template-dependent reiterative transcription mechanisms as it replicates the poly(A) tails of viral RNA (Steil et al., 2010). These mechanisms are analogous to those involved in the polyadenylation of vesicular stomatitis virus and influenza virus mRNAs. 3D^pol residues intimately associated with viral RNA templates and products regulate the size of poly(A) tails in viral RNA (Kempf et al., 2013). Consistent with their ancient evolutionary origins, picornavirus 3D^pol and telomerase reverse transcriptase (TERT) share structural and functional features. Structurally, both 3D^pol and TERT assume a “right-hand” conformation with thumb, palm and fingers domains encircling templates and products. Functionally, both 3D^pol and TERT use template-dependent reiterative transcription mechanisms to synthesize repetitive sequences: poly(A) tails in the case of picornavirus RNA genomes and DNA telomeres in the case of eukaryotic chromosomes. Thus, picornaviruses and their eukaryotic hosts (humans and animals) maintain the 3′ ends of their respective genomes via evolutionarily related mechanisms.

Unmasking the information encoded as structural motifs of viral RNA genomes: a potential antiviral target

RNA viruses show enormous capacity to evolve and adapt to new cellular and molecular contexts, a consequence of mutations arising from errors made by viral RNA-dependent RNA polymerase during replication. Sequence variation must occur, however, without compromising functions essential for the completion of the viral cycle. RNA viruses are safeguarded in this respect by their genome carrying conserved information that does not code only for proteins but also for the formation of structurally conserved RNA domains that directly perform these critical functions. Functional RNA domains can interact with other regions of the viral genome and/or proteins to direct viral translation, replication and encapsidation. They are therefore potential targets for novel therapeutic strategies. This review summarises our knowledge of the functional RNA domains of human RNA viruses and examines the achievements made in the design of antiviral compounds that interfere with their folding and therefore their function.

Structural features of a picornavirus polymerase involved in the polyadenylation of viral RNA

Picornaviruses have 3' polyadenylated RNA genomes, but the mechanisms by which these genomes are polyadenylated during viral replication remain obscure. Based on prior studies, we proposed a model wherein the poliovirus RNA-dependent RNA polymerase (3D(pol)) uses a reiterative transcription mechanism while replicating the poly(A) and poly(U) portions of viral RNA templates. To further test this model, we examined whether mutations in 3D(pol) influenced the polyadenylation of virion RNA. We identified nine alanine substitution mutations in 3D(pol) that resulted in shorter or longer 3' poly(A) tails in virion RNA. These mutations could disrupt structural features of 3D(pol) required for the recruitment of a cellular poly(A) polymerase; however, the structural orientation of these residues suggests a direct role of 3D(pol) in the polyadenylation of RNA genomes. Reaction mixtures containing purified 3D(pol) and a template RNA with a defined poly(U) sequence provided data consistent with a template-dependent reiterative transcription mechanism for polyadenylation. The phylogenetically conserved structural features of 3D(pol) involved in the polyadenylation of virion RNA include a thumb domain alpha helix that is positioned in the minor groove of the double-stranded RNA product and lysine and arginine residues that interact with the phosphates of both the RNA template and product strands.

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.

Non-template functions of viral RNA in picornavirus replication

The genomic RNA of poliovirus and closely related picornaviruses perform template and non-template functions during viral RNA replication. The non-template functions are mediated by cis-active RNA sequences that bind viral and cellular proteins to form RNP complexes. The RNP complexes mediate temporally dynamic, long-range interactions in the viral genome and ensure the specificity of replication. The 5' cloverleaf (5' CL)-RNP complex serves as a key cis-active element in all of the non-template functions of viral RNA. The 5'CL-RNP complex is proposed to interact with the cre-RNP complex during VPgpUpU synthesis, the 3'NTR-poly(A) RNP complex during negative-strand initiation and the 30 end negative-strand-RNP complex during positive-strand initiation. Co-ordinating these long-range interactions is important in regulating each step in the replication cycle.

Selection and characterisation of guanidine-resistant mutants of human enterovirus 71

The replication of human enterovirus 71 (HEV71) in cell culture is inhibited by concentrations of guanidine that do not have an observable adverse effect on host cell metabolism. Although the HEV71 non-structural protein 2C is known to play an important role in viral RNA replication, its precise biochemical activities and structure have not been fully determined. Here we describe amino acid substitutions in HEV71 protein 2C that confer resistance to guanidine. Three guanidine-resistant virus populations were independently isolated and found to contain five mutations in protein 2C, one of which, A4657T (2C-M193L), was present in two of the independently selected populations. This mutation was introduced into a HEV71 infectious cDNA clone and was sufficient to confer complete resistance to growth inhibition in the presence of 4mM guanidine. In the first guanidine-resistant population selected, the 2C-M193L mutation occurred in association with an additional mutation, A4459G (2C-I127V), located in the putative cis-acting replication element (cre) of coding region 2C. This mutation conferred only partial guanidine resistance when introduced into the HEV71-26M infectious clone. When the 2C-I127V and 2C-M193L mutations were introduced into HEV71-26M together, the 2C-I127V mutation did not increase the level of guanidine resistance due to the 2C-M193L mutation alone. This study confirms that guanidine resistance can be readily selected in HEV71 and is attributable to mutations within protein 2C.

Poly(A) at the 3' end of positive-strand RNA and VPg-linked poly(U) at the 5' end of negative-strand RNA are reciprocal templates during replication of poliovirus RNA

A 3' poly(A) tail is a common feature of picornavirus RNA genomes and the RNA genomes of many other positive-strand RNA viruses. We examined the manner in which the homopolymeric poly(A) and poly(U) portions of poliovirus (PV) positive- and negative-strand RNAs were used as reciprocal templates during RNA replication. Poly(A) sequences at the 3' end of viral positive-strand RNA were transcribed into VPg-linked poly(U) products at the 5' end of negative-strand RNA during PV RNA replication. Subsequently, VPg-linked poly(U) sequences at the 5' ends of negative-strand RNA templates were transcribed into poly(A) sequences at the 3' ends of positive-strand RNAs. The homopolymeric poly(A) and poly(U) portions of PV RNA products of replication were heterogeneous in length and frequently longer than the corresponding homopolymeric sequences of the respective viral RNA templates. The data support a model of PV RNA replication wherein reiterative transcription of homopolymeric templates ensures the synthesis of long 3' poly(A) tails on progeny RNA genomes.

Conversion of VPg into VPgpUpUOH before and during poliovirus negative-strand RNA synthesis

There are two protein primers involved in picornavirus RNA replication, VPg, the viral protein of the genome, and VPgpUpU(OH). A cis-acting replication element (CRE) within the open reading frame of poliovirus (PV) RNA allows the viral RNA-dependent RNA polymerase 3D(Pol) to catalyze the conversion of VPg into VPgpUpU(OH). In this study, we used preinitiation RNA replication complexes (PIRCs) to determine when CRE-dependent VPg uridylylation occurs relative to the sequential synthesis of negative- and positive-strand RNA. Guanidine HCl (2 mM), a reversible inhibitor of PV 2C(ATPase), prevented CRE-dependent VPgpUpU(OH) synthesis and the initiation of negative-strand RNA synthesis. VPgpUpU(OH) and nascent negative-strand RNA molecules were synthesized coincident in time following the removal of guanidine, consistent with PV RNA functioning simultaneously as a template for CRE-dependent VPgpUpU(OH) synthesis and negative-strand RNA synthesis. The amounts of [(32)P]UMP incorporated into VPgpUpU(OH) and negative-strand RNA products indicated that 100 to 400 VPgpUpU(OH) molecules were made coincident in time with each negative-strand RNA. 3'-dCTP inhibited the elongation of nascent negative-strand RNAs without affecting CRE-dependent VPg uridylylation. A 3' nontranslated region mutation which inhibited negative-strand RNA synthesis did not inhibit CRE-dependent VPg uridylylation. Together, the data implicate 2C(ATPase) in the mechanisms whereby PV RNA functions as a template for reiterative CRE-dependent VPg uridylylation before and during negative-strand RNA synthesis.

Cis-acting RNA elements in human and animal plus-strand RNA viruses

The RNA genomes of plus-strand RNA viruses have the ability to form secondary and higher-order structures that contribute to their stability and to their participation in inter- and intramolecular interactions. Those structures that are functionally important are called cis-acting RNA elements because their functions cannot be complemented in trans. They can be involved not only in RNA/RNA interactions but also in binding of viral and cellular proteins during the complex processes of translation, RNA replication and encapsidation. Most viral cis-acting RNA elements are located in the highly structured 5'- and 3'-nontranslated regions of the genomes but sometimes they also extend into the adjacent coding sequences. In addition, some cis-acting RNA elements are embedded within the coding sequences far away from the genomic ends. Although the functional importance of many of these structures has been confirmed by genetic and biochemical analyses, their precise roles are not yet fully understood. In this review we have summarized what is known about cis-acting RNA elements in nine families of human and animal plus-strand RNA viruses with an emphasis on the most thoroughly characterized virus families, the Picornaviridae and Flaviviridae.

Cis-active RNA elements (CREs) and picornavirus RNA replication

Our understanding of picornavirus RNA replication has improved over the past 10 years, due in large part to the discovery of cis-active RNA elements (CREs) within picornavirus RNA genomes. CREs function as templates for the conversion of VPg, the Viral Protein of the genome, into VPgpUpU(OH). These so called CREs are different from the previously recognized cis-active RNA sequences and structures within the 5' and 3' NTRs of picornavirus genomes. Two adenosine residues in the loop of the CRE RNA structures allow the viral RNA-dependent RNA polymerase 3D(Pol) to add two uridine residues to the tyrosine residue of VPg. Because VPg and/or VPgpUpU(OH) prime the initiation of viral RNA replication, the asymmetric replication of viral RNA could not be explained without an understanding of the viral RNA template involved in the conversion of VPg into VPgpUpU(OH) primers. We review the growing body of knowledge regarding picornavirus CREs and discuss how CRE RNAs work coordinately with viral replication proteins and other cis-active RNAs in the 5' and 3' NTRs during RNA replication.