Residues of the rotavirus RNA-dependent RNA polymerase template entry tunnel that mediate RNA recognition and genome replication

To replicate its segmented, double-stranded RNA (dsRNA) genome, the rotavirus RNA-dependent RNA polymerase, VP1, must recognize viral plus-strand RNAs (+RNAs) and guide them into the catalytic center. VP1 binds to the conserved 3' end of rotavirus +RNAs via both sequence-dependent and sequence-independent contacts. Sequence-dependent contacts permit recognition of viral +RNAs and specify an autoinhibited positioning of the template within the catalytic site. However, the contributions to dsRNA synthesis of sequence-dependent and sequence-independent VP1-RNA interactions remain unclear. To analyze the importance of VP1 residues that interact with +RNA on genome replication, we engineered mutant VP1 proteins and assayed their capacity to synthesize dsRNA in vitro. Our results showed that, individually, mutation of residues that interact specifically with RNA bases did not diminish replication levels. However, simultaneous mutations led to significantly lower levels of dsRNA product, presumably due to impaired recruitment of +RNA templates. In contrast, point mutations of sequence-independent RNA contact residues led to severely diminished replication, likely as a result of improper positioning of templates at the catalytic site. A noteworthy exception was a K419A mutation that enhanced the initiation capacity and product elongation rate of VP1. The specific chemistry of Lys419 and its position at a narrow region of the template entry tunnel appear to contribute to its capacity to moderate replication. Together, our findings suggest that distinct classes of VP1 residues interact with +RNA to mediate template recognition and dsRNA synthesis yet function in concert to promote viral RNA replication at appropriate times and rates.     

De novo synthesis of RNA by the dengue virus RNA-dependent RNA polymerase exhibits temperature dependence at the initiation but not elongation phase

Replication of positive strand flaviviruses is mediated by the viral RNA-dependent RNA polymerases (RdRP). To study replication of dengue virus (DEN), a flavivirus family member, an in vitro RdRP assay was established using cytoplasmic extracts of DEN-infected mosquito cells and viral subgenomic RNA templates containing 5'- and 3'-terminal regions (TRs). Evidence supported that an interaction between the TRs containing conserved stem-loop, cyclization motifs, and pseudoknot structural elements is required for RNA synthesis. Two RNA products, a template size and a hairpin, twice that of the template, were formed. To isolate the function of the viral RdRP (NS5) from that of other host or viral factors present in the cytoplasmic extracts, the NS5 protein was expressed and purified from Escherichia coli. In this study, we show that the purified NS5 alone is sufficient for the synthesis of the two products and that the template-length RNA is the product of de novo initiation. Furthermore, the incubation temperature during initiation, but not elongation phase of RNA synthesis modulates the relative amounts of the hairpin and de novo RNA products. A model is proposed that a specific conformation of the viral polymerase and/or structure at the 3' end of the template RNA is required for de novo initiation.     

Characterization of a Nodavirus Replicase Revealed a de Novo Initiation Mechanism of RNA Synthesis and Terminal Nucleotidyltransferase Activity

Nodaviruses are a family of positive-stranded RNA viruses with a bipartite genome of RNAs. In nodaviruses, genomic RNA1 encodes protein A, which is recognized as an RNA-dependent RNA polymerase (RdRP) and functions as the sole viral replicase protein responsible for its RNA replication. Although nodaviral RNA replication has been studied in considerable detail, and nodaviruses are well recognized models for investigating viral RNA replication, the mechanism(s) governing the initiation of nodaviral RNA synthesis have not been determined. In this study, we characterized the RdRP activity of Wuhan nodavirus (WhNV) protein A in detail and determined that this nodaviral protein A initiates RNA synthesis via a de novo mechanism, and this RNA synthesis initiation could be independent of other viral or cellular factors. Moreover, we uncovered that WhNV protein A contains a terminal nucleotidyltransferase (TNTase) activity, which is the first time such an activity has been identified in nodaviruses. We subsequently found that the TNTase activity could function in vitro to repair the 3′ initiation site, which may be digested by cellular exonucleases, to ensure the efficiency and accuracy of viral RNA synthesis initiation. Furthermore, we determined the cis-acting elements for RdRP or TNTase activity at the 3′-end of positive or negative strand RNA1. Taken together, our data establish the de novo synthesis initiation mechanism and the TNTase activity of WhNV protein A, and this work represents an important advance toward understanding the mechanism(s) of nodaviral RNA replication.     

Poliovirus RNA replication requires genome circularization through a protein-protein bridge.

The mechanisms and factors involved in the replication of positive stranded RNA viruses are still unclear. Using poliovirus as a model, we show that a long-range interaction between ribonucleoprotein (RNP) complexes formed at the ends of the viral genome is necessary for RNA replication. Initiation of negative strand RNA synthesis requires a 3' poly(A) tail. Strikingly, it also requires a cloverleaf-like RNA structure located at the other end of the genome. An RNP complex formed around the 5' cloverleaf RNA structure interacts with the poly(A) binding protein bound to the 3' poly(A) tail, thus linking the ends of the viral RNA and effectively circularizing it. Formation of this circular RNP complex is required for initiation of negative strand RNA synthesis. RNA circularization may be a general replication mechanism for positive stranded RNA viruses.     

Mechanism of RNA synthesis initiation by the vesicular stomatitis virus polymerase

The minimal RNA synthesis machinery of non-segmented negative-strand RNA viruses comprises a genomic RNA encased within a nucleocapsid protein (N-RNA), and associated with the RNA-dependent RNA polymerase (RdRP). The RdRP is contained within a viral large (L) protein, which associates with N-RNA through a phosphoprotein (P). Here, we define that vesicular stomatitis virus L initiates synthesis via a de-novo mechanism that does not require N or P, but depends on a high concentration of the first two nucleotides and specific template requirements. Purified L copies a template devoid of N, and P stimulates L initiation and processivity. Full processivity of the polymerase requires the template-associated N protein. This work provides new mechanistic insights into the workings of a minimal RNA synthesis machine shared by a broad group of important human, animal and plant pathogens, and defines a mechanism by which specific inhibitors of RNA synthesis function.     

Flock House Virus RNA Polymerase Initiates RNA Synthesis De Novo and Possesses a Terminal Nucleotidyl Transferase Activity

Flock House virus (FHV) is a positive-stranded RNA virus with a bipartite genome of RNAs, RNA1 and RNA2, and belongs to the family Nodaviridae. As the most extensively studied nodavirus, FHV has become a well-recognized model for studying various aspects of RNA virology, particularly viral RNA replication and antiviral innate immunity. FHV RNA1 encodes protein A, which is an RNA-dependent RNA polymerase (RdRP) and functions as the sole viral replicase protein responsible for RNA replication. Although the RNA replication of FHV has been studied in considerable detail, the mechanism employed by FHV protein A to initiate RNA synthesis has not been determined. In this study, we characterized the RdRP activity of FHV protein A in detail and revealed that it can initiate RNA synthesis via a de novo (primer-independent) mechanism. Moreover, we found that FHV protein A also possesses a terminal nucleotidyl transferase (TNTase) activity, which was able to restore the nucleotide loss at the 3′-end initiation site of RNA template to rescue RNA synthesis initiation in vitro, and may function as a rescue and protection mechanism to protect the 3′ initiation site, and ensure the efficiency and accuracy of viral RNA synthesis. Altogether, our study establishes the de novo initiation mechanism of RdRP and the terminal rescue mechanism of TNTase for FHV protein A, and represents an important advance toward understanding FHV RNA replication.     

Plant virus RNAs. Coordinated recruitment of conserved host functions by (+) ssRNA viruses during early infection events

Positive-sense single-stranded RNA viruses have developed strategies to exploit cellular resources at the expense of host mRNAs. The genomes of these viruses display a variety of structures at their 5' and 3' ends that differentiate them from cellular mRNAs. Despite this structural diversity, viral RNAs are still circularized by juxtaposition of their 5' and 3' ends, similar to the process used by cellular mRNAs. Also reminiscent of the mechanisms used by host mRNAs, translation of viral RNAs involves the recruitment of translation initiation factors. However, the roles played by these factors likely differ from those played by cellular mRNAs. In keeping with the general parsimony typical of RNA viruses, these host factors also participate in viral RNA replication. However, the dual use of host factors requires that viral RNA template utilization be regulated to avoid conflict between replication and translation. The molecular composition of the large ribonucleoprotein complexes that form the viral RNA replication and translation machineries likely evolves over the course of infection to allow for switching template use from translation to replication.     

Location of the sequences coding for capsid proteins VP1 and VP2 on polyoma virus DNA.

The 19S and 16S polyoma virus late mRNAs have been separated on sucrose-formamide density gradients and translated in vitro. The 16S RNA codes only for polyoma capsid protein VP1, while the 19S RNA codes in addition for capsid protein VP2. Since the 19S and 16S species have been previously mapped on the viral genome, these results allow us to deduce the location of the sequences coding for VP1 and VP2. Comparison of the chain lengths of the capsid proteins with the size of the viral mRNAs coding for them suggests that VP1 and VP2 are entirely virus-coded. Purified polyoma 19S RNA directs the synthesis of very little VP1 in vitro, although it contains all the sequences required to code for the protein. The initiation site for VP1 synthesis which is located at an internal position on the messenger is probably inactive either because it is inaccessible or because it lacks an adjacent "capped" 5' terminus. Similar inactive internal initiation sites have been reported for other eucarotic viral mRNAs (for example, Semliki forest virus, Brome mosaic virus, and tobacco mosaic virus), suggesting that while eucaryotic mRNAs may have more than one initiation site for protein synthesis, only those sites nearer the 5' terminus of the mRNA are active.     

Minus-strand initiation by brome mosaic virus replicase within the 3' tRNA-like structure of native and modified RNA templates

An RNA-dependent RNA polymerase (replicase) extract from brome mosaic virus-infected barley leaves has been shown to initiate synthesis of (-) sense RNA from (+) sense virion RNA. Initiation occurred de novo, as demonstrated by the incorporation of [gamma-32P]GTP into the product. Sequencing using cordycepin triphosphate to terminate (-) strands during their synthesis by the replicase generated sequence ladders that confirmed that copying was accurate, and that initiation occurred very close to the 3' end. The precise site of initiation was further defined by testing the replicase template activity after stepwise removal of 3'-terminal nucleotides. Whereas removal of the terminal A did not decrease template activity, removal of the next nucleotide (C-2) did. Thus, initiation almost certainly occurs opposite the penultimate 3'-nucleotide (C-2) in vitro. The structure of the double-stranded replicative form of RNA isolated from brome mosaic virus-infected leaves was consistent with such a mechanism occurring in vivo, in that it lacked the 3'-terminal A found on virion RNAs. The specific site of (-) strand initiation and normal template activity were retained for RNAs with as many as 15 to 30 A residues added to the 3' end. However, only limited oligonucleotide 3' extensions can be present on active templates. In order to assess the 5' extent of sequences required for an active template, a 134-nucleotide-long fragment of brome mosaic virus RNA, corresponding to the tRNA-like structure, was generated. This RNA had high template activity, but a shorter 3' (85-nucleotide) fragment was inactive. RNAs with various heterologous sequences 5' to position 134 also showed high template activity. Thus, the 3'-terminal tRNA-like structure common to all four brome mosaic virus virion RNAs contains all of the signals required for initiation of replication, and sequences 5' to it do not play a role in template selection.     

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.