West Nile virus genome cyclization and RNA replication require two pairs of long-distance RNA interactions

West Nile virus (WNV) genome cyclization and replication require two pairs of long-distance RNA interactions. Besides the previously reported 5'CS/3'CSI (conserved sequence) interaction, a 5'UAR/3'UAR (upstream AUG region) interaction also contributes to genome cyclization and replication. WNVs containing mutant 5'UARs capable of forming the 5'/3' viral RNA interaction were replicative. In contrast, WNV containing a 5'UAR mutation that abolished the 5'/3' viral RNA interaction was non-replicative; however, the replication defect could be rescued by a single-nucleotide adaptation that restored the 5'/3' RNA interaction. The 5'UAR/3'UAR interaction is critical for RNA synthesis, but not for viral translation. Antisense oligomers targeting the 5'UAR/3'UAR interaction effectively inhibited WNV replication. Phylogenic analysis showed that the 3'UAR could alternate between pairing with the 5'UAR or with the 3' end of the flaviviral genome. Therefore, the 5'UAR/3'UAR pairing may release the 3' end of viral genome (as a template) during the initiation of minus-strand RNA synthesis.     

Functional analysis of dengue virus cyclization sequences located at the 5' and 3'UTRs

Flavivirus RNA replication involves cyclization of the viral genome. A model for this process includes a promoter element at the 5' end of the genome and long-range RNA-RNA interactions. Two pairs of complementary sequences present at the ends of the viral RNA, known as 5'-3'CS and 5'-3'UAR, have been proposed to be involved in dengue virus genome cyclization. The requirement of 5'-3'CS complementarity for viral replication has been experimentally demonstrated for dengue and other mosquito borne flaviviruses. Here, we performed a functional analysis to study the role of 5'-3'UAR sequences using genomic and subgenomic dengue virus RNAs. We found that single mutations disrupting 5'-3' complementarity greatly compromised viral RNA synthesis. Although in most of the cases incorporation of compensatory mutations re-established viral RNA replication, certain nucleotides were found to be involved in alternative secondary structures also important for viral replication. In addition, mutations within 5' or 3'UAR in the context of an infectious dengue virus RNA resulted in spontaneous mutations that restored UAR base pairings. Together, we propose that specific UAR nucleotides as well as 5'-3'UAR complementarity constitute cis-acting signals involved in amplification of the dengue virus genome.     

Terminal structures of West Nile virus genomic RNA and their interactions with viral NS5 protein

Genome cyclization is essential for flavivirus replication. We used RNases to probe the structures formed by the 5′-terminal 190 nucleotides and the 3′-terminal 111 nucleotides of the West Nile virus (WNV) genomic RNA. When analyzed individually, the two RNAs adopt stem-loop structures as predicted by the thermodynamic-folding program. However, when mixed together, the two RNAs form a duplex that is mediated through base-pairings of two sets of RNA elements (5′CS/3′CSI and 5′UAR/3′UAR). Formation of the RNA duplex facilitates a conformational change that leaves the 3′-terminal nucleotides of the genome (position − 8 to − 16) to be single-stranded. Viral NS5 binds specifically to the 5′-terminal stem-loop (SL1) of the genomic RNA. The 5′SL1 RNA structure is essential for WNV replication. The study has provided further evidence to suggest that flavivirus genome cyclization and NS5/5′SL1 RNA interaction facilitate NS5 binding to the 3′ end of the genome for the initiation of viral minus-strand RNA synthesis.     

The majority of the nucleotides in the top loop of the genomic 3' terminal stem loop structure are cis-acting in a West Nile virus infectious clone

The flavivirus genome RNA terminates with a conserved 3' stem loop (SL) structure that was shown to be essential for virus replication. A stretch of conserved nts is located in the top loop (TL) of this structure. Mutation of the TL nts (5' ACAGUGC 3') in a WNV infectious clone indicated that 3 of the 7 TL nts (5' ACAGUGC 3') are critical for virus replication. Mutation of 3 of the other nts reduced the efficiency of virus replication. The four 5' TL nts are conserved in both mosquito- and tick-borne flavivirus genomes, while the TL 3' C is conserved in mosquito-borne viruses. The conservation of two or three G-C base pairs in the TL flanking sequences suggests that a stable stem is necessary for precise presentation of the TL sequence. The TL may participate in RNA as well as protein interactions.     

The 3' stem loop of the West Nile virus genomic RNA can suppress translation of chimeric mRNAs

Cis-acting elements that regulate translation have been identified in the 3' noncoding regions (NCRs) of cellular and viral mRNAs. As one means of analyzing the effect on translation of the conserved 3' terminal RNA structure of the West Nile virus (WNV) genome, the translation efficiencies of chimeric mRNAs composed of a CAT reporter gene flanked by viral or nonviral 5' and 3' terminal sequences were compared. In vitro, the WNV 3'(+) stem loop (SL) RNA reduced the translation efficiencies of chimeric mRNAs with either viral or nonviral 5' NCRs, suggesting that a specific 3'-5' RNA-RNA interaction was not involved. In contrast, the 3' terminal sequence of a togavirus, rubella virus, enhanced translation efficiency. The WNV 3'(+)SL reduced translation efficiency both in cis and in trans and of both capped and uncapped chimeric mRNAs. We have previously reported that three cellular proteins bind specifically to the WNV 3'(+)SL RNA. Competition between the WNV 3'(+)SL and the 5' terminus of the chimeric mRNAs for proteins involved in translation initiation could explain the translation inhibition observed.     

Genome cyclization as strategy for flavivirus RNA replication

Long-range and local RNA-RNA contacts in viral RNA genomes result in tertiary structures that modulate the function of enhancers, promoters, and silencers during translation, RNA replication, and encapsidation. In the case of flaviviruses, the presence of inverted complementary sequences at the 5' and 3' ends of the genome mediate long-range RNA interactions and RNA cyclization. The circular conformation of flavivirus genomes was demonstrated to be essential for RNA amplification. New ideas about the mechanisms by which circular genomes participate in flavivirus replication have emerged in the last few years. Here, we will describe the latest information about cis-acting elements involved in flavivirus genome cyclization, RNA promoter elements required for viral polymerase recognition, and how these elements together coordinate viral RNA synthesis.     

A 5' RNA element promotes dengue virus RNA synthesis on a circular genome

The mechanisms of RNA replication of plus-strand RNA viruses are still unclear. Here, we identified the first promoter element for RNA synthesis described in a flavivirus. Using dengue virus as a model, we found that the viral RdRp discriminates the viral RNA by specific recognition of a 5' element named SLA. We demonstrated that RNA-RNA interactions between 5' and 3' end sequences of the viral genome enhance dengue virus RNA synthesis only in the presence of an intact SLA. We propose a novel mechanism for minus-strand RNA synthesis in which the viral polymerase binds SLA at the 5' end of the genome and reaches the site of initiation at the 3' end via long-range RNA-RNA interactions. These findings provide an explanation for the strict requirement of dengue virus genome cyclization during viral replication.     

Structure-function relationship in viral RNA genomes: The case of hepatitis C virus

The acquisition of a storage information system beyond the nucleotide sequence has been a crucial issue for the propagation and dispersion of RNA viruses. This system is composed by highly conserved, complex structural units in the genomic RNA, termed functional RNA domains. These elements interact with other regions of the viral genome and/or proteins to direct viral translation, replication and encapsidation. The genomic RNA of the hepatitis C virus(HCV) is a good model for investigating about conserved structural units. It contains functional domains, defined by highly conserved structural RNA motifs, mostly located in the 5'-untranslatable regions(5'UTRs) and 3'UTR, but also occupying long stretches of the coding sequence. Viral translation initiation is mediated by an internal ribosome entry site located at the 5' terminus of the viral genome and regulated by distal functional RNA domains placed at the 3' end. Subsequent RNA replication strongly depends on the 3'UTR folding and is also influenced by the 5' end of the HCV RNA. Further increase in the genome copy number unleashes the formation of homodimers by direct interaction of two genomic RNA molecules, which are finally packed and released to the extracellular medium. All these processes, as well as transitions between them, are controlled by structural RNA elements that establish a complex, direct and long-distance RNARNA interaction network. This review summarizes current knowledge about functional RNA domains within the HCV RNA genome and provides an overview of the control exerted by direct, long-range RNA-RNA contacts for the execution of the viral cycle.     

Composition of the sequence downstream of the dengue virus 5' cyclization sequence (dCS) affects viral RNA replication

RNA replication of dengue virus (DENV) requires an RNA-RNA mediated circularization of the viral genome, which includes at least three sets of complementary RNA sequences on both ends of the genome. The 5′ and the 3′ untranslated regions form several additional RNA elements that are involved in regulation of translation and required for RNA replication. Communication between the genomic termini results in a structural reorganization of the RNA elements, forming a functional RNA panhandle structure. Here we report that the sequence composition downstream of the 5′ CS element in the capsid gene, designated as downstream CS (dCS) sequence - but not the capsid protein - also influences the ability of the viral genome to circularize and hence replicate by modulating the topology of the 5′ end. These results provide insights for the design of reporter sub-genomic and genomic mosquito-borne flavivirus constructs and contribute to the understanding of viral RNA replication.     

West Nile virus (WNV) genome RNAs with up to three adjacent mutations that disrupt long distance 5'-3' cyclization sequence basepairs are viable

Mosquito-borne flavivirus genomes contain conserved 5′ and 3′ cyclization sequences (CYC) that facilitate long distance RNA-RNA interactions. In previous studies, flavivirus replicon RNA replication was completely inhibited by single or multiple mismatching CYC nt substitutions. In the present study, full-length WNV genomes with one, two or three mismatching CYC substitutions showed reduced replication efficiencies but were viable and generated revertants with increased replication efficiency. Several different three adjacent mismatching CYC substitution mutant RNAs were rescued by a second site mutation that created an additional basepair (nts 147-10913) on the internal genomic side of the 5′-3′ CYC. The finding that full-length genomes with up to three mismatching CYC mutations are viable and can be rescued by a single nt spontaneous mutation indicates that more than three adjacent CYC basepair substitutions would be required to increase the safety of vaccine genomes by creating mismatches in inter-genomic recombinants.     

Analysis of the role of predicted RNA secondary structures in Ebola virus replication

Thermodynamic modeling of Ebola viral RNA predicts the formation of RNA stem-loop structures at the 3' and 5' termini and panhandle structures between the termini of the genomic (or antigenomic) RNAs. Sequence analysis showed a high degree of identity among Ebola Zaire, Sudan, Reston, and Cote d'Ivoire subtype viruses in their 3' and 5' termini (18 nucleotides in length) and within a second region (internal by approximately 20 nucleotides). While base pairing of the two conserved regions could lead to the formation of the base of the putative stem-loop or panhandle structures, the intervening sequence variation altered the predictions for the rest of the structures. Using an in vivo minigenome replication system, we engineered mutations designed to disrupt potential base pairing in the viral RNA termini. Analysis of these variants by screening for enhanced green fluorescent protein reporter expression and by quantitation of minigenomic RNA levels demonstrated that the upper portions of the putative panhandle and 3' genomic structures can be destabilized without affecting virus replication.     

The capsid-coding region hairpin element (cHP) is a critical determinant of dengue virus and West Nile virus RNA synthesis

Dengue virus (DENV) and West Nile virus (WNV) are members of the Flavivirus genus of positive-strand RNA viruses. RNA sequences and structures, primarily in the untranslated regions, have been shown to modulate flaviviral gene expression and genome replication. Previously, we demonstrated that a structure in the DENV coding region (cHP) enhances translation start codon selection and is required for viral replication. Here we further characterize the role of the cHP in the DENV life cycle. We demonstrate that the cHP is required for efficient viral RNA synthesis in a sequence-independent manner. Viruses with a disrupted cHP are rescued by a spontaneous compensatory mutation that restabilizes the structure. Furthermore, the cHP, which is predicted to be conserved among arthropod-borne flaviviruses, is required for WNV replication. We propose that the cHP is a multifunctional determinant of flavivirus replication, functioning in both translation and RNA synthesis.     

Specific requirements for elements of the 5' and 3' terminal regions in flavivirus RNA synthesis and viral replication

We initially studied requirements for 5' and 3' terminal regions (TRs) in flavivirus negative strand synthesis in vitro. Purified West Nile (WNV) and dengue-2 (DV2) RNA polymerases were both active with all-WNV or all-DV2 subgenomic RNAs containing the 5'- and 3'TRs of the respective genomes. However, subgenomic RNAs in which the 5'-noncoding region (5'NCR) or the 5'ORF (nts 100-230) in the 5'TR were substituted by analogous sequences derived from the heterologous genome were modestly to severely defective as templates for either polymerase. We also evaluated the infectivity of substitution mutant WNV genome-length RNAs. All WNV RNAs containing the DV2 3'SL were unable to replicate. However, WNV RNAs containing substitutions of the 5'NCR, the capsid gene, and/or 3'NCR nt sequences upstream from the WNV 3'SL, by the analogous DV2 nt sequences, were infectious. Combined results suggested that replication was not dependent upon species homology between the 3'SL and NS5.     

Genetic analysis of West Nile virus containing a complete 3'CSI RNA deletion

We report a genetic interplay among three pairs of long-distance RNA interactions that are involved in West Nile virus (WNV) genome cyclization and replication: 5′CS/3′CSI (conserved sequence), 5′UAR/3′UAR (upstream AUG region), and 5′DAR/3′DAR (downstream AUG region). Deletion of the complete 3′CSI element is lethal for WNV replication, but the replication of the 3′CSI deletion virus could be rescued by second site mutations. Functional analysis, using a genome-length RNA and replicon, mapped the compensatory mutations to the 5′UAR/3′UAR and 5′DAR/3′DAR regions. Biochemical analysis showed that the 3′CSI deletion abolished the 5′ and 3′ RNA interaction of the genome; the compensatory mutations could partially restore the 5′ and 3′ genome cyclization. These results demonstrate, for the first time, that a flavivirus without 3′CSI could restore genome cyclization and viral replication through enhancement of the 5′UAR/3′UAR and 5′DAR/3′DAR interactions.     

The 3'-nucleotides of flavivirus genomic RNA form a conserved secondary structure

The terminal noncoding regions of viral RNA genomes are presumed to contain signal sequences and sometimes also secondary structures involved in regulating viral RNA synthesis. Such signals would be expected to be highly conserved among related viruses. In order to identify replication signal features for flaviviruses we have compared the 3'-terminal nucleotide sequences of West Nile virus (WNV), Saint Louis encephalitis (SLE) virus, and yellow fever virus (YFV) genome RNAs. The existence of a stable 3'-terminal secondary structure was previously predicted by a cDNA sequence obtained from YFV genome RNA. We have confirmed the existence of this structure by direct RNA sequencing methods. Even though the size and shape of the 3'-terminal secondary structure is highly conserved, sequence conservation is restricted to the loop regions of the secondary structure and to 27 nucleotides immediately adjacent to the 5' side of the structure. The regions of conserved sequence represent likely signals for viral polymerase recognition and binding. However, the preservation of the configuration of the secondary structure by a means other than sequence conservation indicate that this structure is important for the survival of the virus. A WNV mutant, which replicates progeny genome RNA more efficiently than parental WNV, was found to have a 3'-genomic sequence identical to that of its parent virus. The sequence change conferring the phenotype of this mutant is therefore located in another region of the genome.     

Insights into the oligomerization state-helicase activity relationship of West Nile virus NS3 NTPase/helicase

West Nile virus (WNV) is a member of the Flaviviridae family of positive-strand RNA viruses. Its viral RNA is translated to produce a polyprotein precursor that is further processed into three structural and seven non-structural proteins. The non-structural protein 3 (NS3) possess both protease and helicase activities. The C-terminal portion of the NS3 contains the ATPase/helicase domain presumably involved in viral replication. This domain has been expressed in Escherichia coli, purified in soluble form and structurally characterized. As judged by analytical centrifugation and size exclusion chromatography, the purified enzyme behaves as a monomer in solution. It has ATPase activity that is stimulated by the presence of RNA and single-stranded DNA molecules (ssDNA). However, we were unable to detect helicase activity at protein concentrations up to 500nM. It has been reported that longer constructions of NS3 helicase domains from other flavivirus, like those which include residues of the linker region between the protease and the helicase domains, have helicase activity. Since all the conformational features of the purified WNV NS3 domain are those of a native protein, it is tempting to assume that the linker region plays a critical role in determining the protein-protein interactions that leads to the formation of the active oligomer.     

Spatial and temporal organization of tick-borne encephalitis flavivirus replicated RNA in living cells

Flaviviruses are positive RNA viruses that assemble the replication complex in the cytoplasm of the infected cells. In order to get a dynamic view of the formation and distribution of flavivirus genomes in living cells we engineered a tick-borne encephalitis virus (TBEV) replicon with an array of binding sites for the phage MS2 core protein. The modified TBEV replicons were competent for RNA replication and allowed the visualization of replicated genomic RNA that accumulated in cytoplasmic structures with a distinct subcellular localization. Sites of TBEV replicated RNA accumulation were enriched in non-structural viral proteins and co-localized with the markers of the rough endoplasmic reticulum protein disulphide isomerase (PDI). In contrast no co-localization was observed with the markers CD-71 and EEA-1 for recycling vesicles, ERGIC53 for the intermediate compartment and TGN-46 for the trans-Golgi network. In human HOS cells, but not in hamster BHK21 cells, replicated TBEV RNA was found also associated with the marker Giantin for the Golgi indicating differences according to the cellular background.This study confirms and extends previous observations on the subcellular localization of flavivirus RNA and provides a useful tool to monitor the formation and distribution of flavivirus RNA genomes in living cells.     

Complete genome sequence, taxonomic assignment, and comparative analysis of the untranslated regions of the Modoc virus, a flavivirus with no known vector

We recently developed a model for flavivirus infection in mice and hamsters using the Modoc virus (MODV), a flavivirus with no known vector (P. Leyssen, A. Van Lommel, C. Drosten, H. Schmitz, E. De Clercq, and J. Neyts, 2001, Virology 279, 27-37). We now present the coding and noncoding sequence of MODV. The Modoc virus genome was determined to be 10,600 nucleotides in length with a single open reading frame extending from nucleotides 110 to 10,234, encoding 3374 amino acids. The deduced gene order of the single open reading frame is C-prM-E-NS1-NS2A-NS2B-NS3-NS4A-NS4B-NS5, which is exactly the same as that of the mosquito- and tick-borne flaviviruses. It is flanked by a 5'- and 3'-untranslated region (UTR) of 109 and 366 nucleotides, respectively. Alignment of the MODV amino acid sequence with that of 20 other flaviviruses revealed several regions with high sequence similarity corresponding to functionally important domains (e.g., the serine protease/helicase/NTPase of NS3 and the methyltransferase/RNA-dependent RNA polymerase of NS5) and conserved sites for proteolytic cleavage by viral and cellular proteases. Phylogenetic analysis of the entire coding region confirmed the classification of MODV within the flaviviruses with no known vector, which is in agreement with previous findings based on partial NS5 sequences. A detailed comparative analysis of the putative folding patterns of the 5'- and 3'-UTR of MODV and of the tick- and mosquito-borne viruses was carried out. Structural elements in the 5'- and 3' UTR of MODV that are preserved among vector-borne flaviviruses were noted and so were structural elements distinguishing the MODV UTRs from mosquito-borne and tick-borne flaviviruses. Also the putative secondary structure of circularized MODV RNA is presented.     

Rose spring dwarf-associated virus has RNA structural and gene-expression features like those of Barley yellow dwarf virus

We determined the complete nucleotide sequence of the Rose spring dwarf-associated virus (RSDaV) genomic RNA (GenBank accession no. EU024678) and compared its predicted RNA structural characteristics affecting gene expression. A cDNA library was derived from RSDaV double-stranded RNAs (dsRNAs) purified from infected tissue. Nucleotide sequence analysis of the cloned cDNAs, plus for clones generated by 5'- and 3'-RACE showed the RSDaV genomic RNA to be 5808 nucleotides. The genomic RNA contains five major open reading frames (ORFs), and three small ORFs in the 3'-terminal 800 nucleotides, typical for viruses of genus Luteovirus in the family Luteoviridae. Northern blot hybridization analysis revealed the genomic RNA and two prominent subgenomic RNAs of approximately 3 kb and 1 kb. Putative 5' ends of the sgRNAs were predicted by identification of conserved sequences and secondary structures which resembled the Barley yellow dwarf virus (BYDV) genomic RNA 5' end and subgenomic RNA promoter sequences. Secondary structures of the BYDV-like ribosomal frameshift elements and cap-independent translation elements, including long-distance base pairing spanning four kb were identified. These contain similarities but also informative differences with the BYDV structures, including a strikingly different structure predicted for the 3' cap-independent translation element. These analyses of the RSDaV genomic RNA show more complexity for the RNA structural elements for members of the Luteoviridae.