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.     

Core protein-mediated 5'-3' annealing of the West Nile virus genomic RNA in vitro

Genome cyclization through conserved RNA sequences located in the 5' and 3' terminal regions of flavivirus genomic RNA is essential for virus replication. Although the role of various cis-acting RNA elements in panhandle formation is well characterized, almost nothing is known about the potential contribution of protein cofactors to viral RNA cyclization. Proteins with nucleic acid chaperone activities are encoded by many viruses (e.g., retroviruses, coronaviruses) to facilitate RNA structural rearrangements and RNA-RNA interactions during the viral replicative cycle. Since the core protein of flaviviruses is also endowed with potent RNA chaperone activities, we decided to examine the effect of West Nile virus (WNV) core on 5'-3' genomic RNA annealing in vitro. Core protein binding resulted in a dramatic, dose-dependent increase in 5'-3' complex formation. Mutations introduced in either the UAR (upstream AUG region) or CS (conserved sequence) elements of the viral RNA diminished core protein-dependent annealing, while compensatory mutations restored the 5'-3' RNA interaction. The activity responsible for stimulating RNA annealing was mapped to the C-terminal RNA-binding region of WNV core protein. These results indicate that core protein - besides its function in viral particle formation - might be involved in the regulation of flavivirus genomic RNA cyclization, and thus virus replication.     

The flavivirus-conserved penta-nucleotide in the 3' stem-loop of the West Nile virus genome requires a specific sequence and structure for RNA synthesis, but not for viral translation

A reporting replicon of West Nile virus (WN) was used to distinguish between the function of the 3' untranslated region (UTR) in viral translation and RNA replication. Deletions of various regions of the 3' UTR of the replicon did not significantly affect viral translation, but abolished RNA replication. A systematic mutagenesis showed that the flavivirus-conserved penta-nucleotide (5'-CACAG-3' located at the top of the 3' stem-loop of the genome) requires a specific sequence and structure for WN RNA synthesis, but not for viral translation. (i) Basepair structure and sequence at the 1st position of the penta-nucleotide are critical for RNA replication. (ii) The conserved nucleotides at the 2nd, 3rd, and 5th positions, but not at the 4th position of the penta-nucleotide, are essential for RNA synthesis. (iii) The nucleotide U (which is partially conserved in the genus Flavivirus) immediately downstream of the penta-nucleotide is not essential for viral replication.     

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.     

In vitro translation of 42 S virus-specific RNA from cells infected with the flavivirus West Nile virus.

Virus-specific proteins synthesized in BHK cells infected with the flavivirus West Nile (WN) virus and in vitro using the virus-specific infectious 42 S plus-strand RNA as messenger RNA, have been studied. Mapping of the tryptic peptides indicates that the viral core protein V2 and the viral glycoprotein V3 do not share common sequences. No tryptic peptides identifiable by mapping were obtained from the viral membrane-associated protein V1. Seven apparently virus-specific intracellular proteins were detected by comparative SDS-PAGE of mock-infected and virus-infected [³⁵S]methionine-labeled cell lysates: p_i 15, p_i 20, p_i 27, p_i 37, p_i 49, p_i 71, and p_i 100 (the index i indicates the intracellular origin of the proteins, the number gives the apparent molecular weight in 10³ daltons). The proteins p_i 15 and p_i 49 represent the intracellular forms of the viral structural proteins V2 and V3, respectively. p_i 15 and V2 are not identical but differ slightly from each other. V1 has not been detected in infected cells. Mapping has shown that the other intracellular proteins (with the possible exception of p_i 37, which has not been analyzed) are unrelated to either V2 or V3 and do not share common sequences. They represent nonstructural proteins. The total molecular weight of the apparently unrelated nonstructural and structural proteins is about 290,000 daltons. Data obtained in a number of laboratories have shown that a virus-specific 42 S RNA molecule, which is structurally indistinguishable from the viral genome, probably functions as mRNA for all virus-specific proteins in vivo. This RNA has been isolated from WN virus-infected cells and translated in vitro in the wheat germ and the rabbit reticulocyte lysate system. Digestion of the total [³⁵S]methionine-labeled proteins synthesized in vitro in either of both systems with trypsin followed by peptide mapping has shown that the great majority of the resulting peptides are present in the structural proteins V2 and V3 and vice versa. No evidence was obtained for the in vitro synthesis of nonstructural proteins. Proteins synthesized in the reticulocyte lysate were fractionated by SDS-PAGE and isolated polypeptides studied by peptide mapping. Polypeptides of molecular weights between 11,500 and 90,000 daltons were obtained. Their peptide maps indicate that all polypeptides are translated from a single initiation sequence. The map of the smallest in vitro synthesized polypeptide P_retic 11.5, having a molecular weight of 11,500 daltons, was almost identical to that of V2. The map of the largest protein synthesized in significant amounts in vitro, the protein P_retic 90, was very similar to the map of a mixture of the viral proteins V2 and V3. The analyses suggest the following gene order on the 42 S RNA: 5′-terminus-V2-V3-(V1, p_i 20, p_i 27, p_i 37, p_i 71, p_i 100)-3′-terminus. The order of genes indicated in brackets remains to be determined. Some implications of these results concerning the possible mode of translation of flavivirus-specific 42 S RNA are discussed.     

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.     

Two cellular proteins that interact with a stem loop in the simian hemorrhagic fever virus 3'(+)NCR RNA

Both full-length and subgenomic negative-strand RNAs are initiated at the 3' terminus of the positive-strand genomic RNA of the arterivirus, simian hemorrhagic fever virus (SHFV). The SHFV 3'(+) non-coding region (NCR) is 76 nts in length and forms a stem loop (SL) structure that was confirmed by ribonuclease structure probing. Two cell proteins, p56 and p42, bound specifically to a probe consisting of the SHFV 3'(+)NCR RNA. The 3'(+)NCR RNAs of two additional members of the arterivirus genus specifically interacted with two cell proteins of the same size. p56 was identified as polypyrimidine tract-binding protein (PTB) and p42 was identified as fructose bisphosphate aldolase A. PTB binding sites were mapped to a terminal loop and to a bulged region of the SHFV 3'SL structure. Deletion of either of the PTB binding sites in the viral RNA significantly reduced PTB binding activity, suggesting that both sites are required for efficient binding of this protein. Changes in the top portion of the SHFV 3'SL structure eliminated aldolase binding, suggesting that the binding site for this protein is located near the top of the SL. These cell proteins may play roles in regulating the functions of the genomic 3' NCR.     

The amino and carboxyl domains of the infectious bronchitis virus nucleocapsid protein interact with 3' genomic RNA

Previous studies indicated that the nucleocapsid (N) protein of infectious bronchitis virus (IBV) interacted with specific sequences in the 3' non-coding region of IBV RNA. In order to identify domains in the N protein that bind to RNA, the whole protein (409 amino acids) and six overlapping fragments were expressed as fusion polypeptides with six histidine-tags. Using gel shift assays, the intact N protein and amino polypeptides, from residues 1 to 171 and residues 1 to 274, and carboxyl polypeptides, extending from residues 203 to 409 and residues 268 to 407, were found to interact with positive-stranded IBV RNA representing the 3' end of the genome. The two 32P-labeled probes that interacted with N and the amino and carboxyl fragments of N were RNA consisting of the IBV N gene and adjacent 3' non-coding terminus, and RNA consisting of the 155-nucleotide sequences at the 3' end of the 504-nt 3' untranslated region. In contrast, the polypeptide fragment from the middle region, residues 101-283, did not interact with these 3' IBV RNAs. The binding site in the amino region of N was either not present or only partially present in the first 91 residues because no interaction with RNA was observed with the polypeptide incorporating these residues. Cache Valley virus N expressed with a histidine tag, bovine serum albumin, and the basic lysozyme protein did not shift the IBV RNA. The lower molarities of the carboxyl fragment compared with residue 1-274 fragment needed for equivalent shifts suggested that the binding avidity for RNA at the carboxyl domain was greater than the amino domain.     

Safety and immunogenicity of a chimeric vaccine for West Nile virus in aged subjects

A recent Phase II clinical trial has demonstrated comparable safety and immunogenicity of ChimeriVax-WN02, a chimeric West Nile virus (WNV) vaccine candidate based on yellow fever 17D, in small cohorts of healthy adults aged 18-40, 41-64 and 65-80 years. Adults ≥65 years of age are an important target population for candidate WNV vaccines as they have a high risk for severe WNV neuroinvasive disease. The apparent safety and immunogenicity of ChimeriVax-WN02 in this population indicates that further development and clinical testing are justified.     

Nucleotide sequences of the 3' leader and 5' trailer regions of human respiratory syncytial virus genomic RNA.

The nucleotide sequences of the 3' extracistronic (leader) and 5' extracistronic (trailer) regions were determined for genomic RNA (vRNA) of human respiratory syncytial virus (RSV) strain A2. To sequence the 3' leader region, vRNA was extracted from purified virions, size-selected, polyadenylated, copied into cDNA, amplified by the polymerase chain reaction, cloned, and sequenced. The 3' leader sequence is 44 nt, which is somewhat shorter than its counterparts (50 to 70 nt) in other nonsegmented negative-strand viruses sequenced to date. The 5' trailer region was mapped and sequenced in part directly by dideoxynucleotide sequencing of vRNA. The sequence was confirmed and completed by analysis of cDNA clones derived from vRNA. The 5' trailer sequence is 155 nt in length, which is substantially longer than its counterparts (40 to 70 nt) in other nonsegmented negative-strand viruses. Ten of the 11 terminal nt of the 3' leader and 5' trailer regions were complementary. Among the other paramyxoviruses, the terminal 5 to 16 nt of the leader and trailer regions are highly conserved, but the corresponding RSV sequences were identical to the others only for the terminal 2 nt of each end. Surprisingly, the termini of the RSV leader and trailer regions were in somewhat better agreement with those of the rhabdoviruses vesicular stomatitis virus and rabies virus, sharing identity for the first 3 or 4 nt.     

Microarray hybridization for assessment of the genetic stability of chimeric West Nile/dengue 4 virus

Genetic stability is an important characteristic of live viral vaccines because an accumulation of mutants can cause reversion to a virulent phenotype as well as a loss of immunogenic properties. This study was aimed at evaluating the genetic stability of a live attenuated West Nile (WN) virus vaccine candidate that was generated by replacing the pre-membrane and envelope protein genes of dengue 4 virus with those from WN. Chimeric virus was serially propagated in Vero, SH-SY5Y human neuroblastoma and HeLa cells and screened for point mutations using hybridization with microarrays of overlapping oligonucleotide probes covering the entire genome. The analysis revealed several spontaneous mutations that led to amino acid changes, most of which were located in the envelope (E) and non-structural NS4A, NS4B, and NS5 proteins. Viruses passaged in Vero and SH-SY5Y cells shared two common mutations: G(2337) C (Met(457) Ile) in the E gene and A(6751) G (Lys(125) Arg) in the NS4A gene. Quantitative assessment of the contents of these mutants in viral stocks indicated that they accumulated independently with different kinetics during propagation in cell cultures. Mutant viruses grew better in Vero cells compared to the parental virus, suggesting that they have a higher fitness. When tested in newborn mice, the cell culture-passaged viruses did not exhibit increased neurovirulence. The approach described in this article could be useful for monitoring the molecular consistency and quality control of vaccine strains.     

Separate molecules of West Nile virus methyltransferase can independently catalyze the N7 and 2'-O methylations of viral RNA cap

West Nile virus methyltransferase catalyzes N7 and 2'-O methylations of the viral RNA cap (GpppA-RNA-->m(7)GpppAm-RNA). The two methylation events are independent, as evidenced by efficient N7 methylation of GpppA-RNA-->m(7)GpppA-RNA and GpppAm-RNA-->m(7)GpppAm-RNA, and by the 2'-O methylation of GpppA-RNA-->GpppAm-RNA and m(7)GpppA-RNA-->m(7)GpppAm-RNA. However, the 2'-O methylation activity prefers substrate m(7)GpppA-RNA to GpppA-RNA, thereby determining the dominant methylation pathway as GpppA-RNA-->m(7)GpppA-RNA-->m(7)GpppAm-RNA. Mutant enzymes with different methylation defects can trans complement one another in vitro. Furthermore, sequential treatment of GpppA-RNA with distinct methyltransferase mutants generates fully methylated m(7)GpppAm-RNA, demonstrating that separate molecules of the enzyme can independently catalyze the two cap methylations in vitro.     

Downregulation of Bamboo mosaic virus replication requires the 5' apical hairpin stem loop structure and sequence of satellite RNA

Satellite RNAs associated with Bamboo mosaic virus (satBaMV) exhibit different phenotypes. Some isolates could reduce the accumulation of BaMV RNA and attenuate the BaMV-induced symptoms in co-inoculated plants. The determinants of the downregulation of BaMV replication were mapped in the 5' hypervariable region of satBaMV, which folds into a conserved apical hairpin stem loop (AHSL) structure comprising an apical loop and two internal loops, as evidenced by enzymatic probing. We also demonstrated that the integrity of the AHSL structure of interfering satBaMV was essential for the interference of BaMV accumulation. Concurrent analyses of natural satBaMV isolates revealed that all of the interfering isolates contained the same structures and sequences in the internal loops. Further, refined analyses indicated that, besides the AHSL structure, specific nucleotides in the internal loops play a crucial role in the downregulation, which implies that they may be required for the interaction of viral/cellular factors in this process.     

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.     

West Nile virus infection of the placenta

Intrauterine infection of fetuses with West Nile virus (WNV) has been implicated in cases of women infected during pregnancy. Infection of timed-pregnant mice on 5.5, 7.5, and 9.5 days post-coitus (dpc) resulted in fetal infection. Infection of dams on 11.5 and 14.5 dpc resulted in little and no fetal infection, respectively. Pre-implantation embryos in culture were also infected with WNV after the blastocyst stage and the formation of trophectoderm. Green fluorescent protein (GFP) expression was observed in a trophoblast stem (TS) cell line after infection with a GFP-expressing WNV construct. However, no fluorescence was observed in differentiated trophoblast giant cell (TGC) cultures. GFP fluorescence was present in TGC cultures if infected TS cells were induced to differentiate. These results suggest that embryos are susceptible to WNV infection after the formation of the trophectoderm around 3.5 dpc through the formation of the functional placenta around 10.5 dpc.     

Analysis of the in vitro coding properties of the 3' region of turnip yellow mosaic virus genomic RNA

The genomic RNA of turnip yellow mosaic virus (TYMV) codes in vitro for two proteins of 195,000 (195K) and 150,000 (150K) daltons initiated at the same site of the RNA. In the presence of yeast amber suppressor tRNA, synthesis of the 195K protein is reduced in favor of a 210,000-dalton (210K) protein. Using TYMV RNA sequence data and comparison of tryptic peptides of the 150K, 195K, 210K, and coat proteins, we postulate that the silent region between the 195K gene and the coat protein gene located in the 3' region of TYMV genomic RNA is only 14 nucleotides long.     

The DE loop of the domain III of the envelope protein appears to be associated with West Nile virus neutralization

The envelope (E) protein of WNV plays an important role in the virus neutralization. Using a mAb 5E8, a neutralizing epitope on the domain III of the E of the New York strain of WN virus was characterized. Results from neutralization-escape mutants and site-directed mutagenesis revealed that the 5E8 epitope is a highly conformation dependent epitope consisting of at least residues E330, E332 and E367 on the domain III. Besides known critical neutralizing epitopes E330 and E332, our results indicate that residue E367, a component of DE loop on the domain III, appeared to be associated with neutralization but little with neuroinvasion of the virus, as reported previously (Beasley et al., 2002).