Crystal structure of the dengue virus RNA-dependent RNA polymerase catalytic domain at 1.85-angstrom resolution

A thiopurine drug inhibits West Nile virus production in cell culture, but not in mice

Many viruses within the Flavivirus genus cause significant disease in humans; however, effective antivirals against these viruses are not currently available. We have previously shown that a thiopurine drug, 6-methylmercaptopurine riboside (6MMPr), inhibits replication of distantly related viruses within the Flaviviridae family in cell culture, including bovine viral diarrhea virus and hepatitis C virus replicon. Here we further examined the potential antiviral effect of 6MMPr on several diverse flaviviruses. In cell culture, 6MMPr inhibited virus production of yellow fever virus, dengue virus-2 (DENV-2) and West Nile virus (WNV) in a dose-dependent manner, and DENV-2 was significantly more sensitive to 6MMPr treatment than WNV. We then explored the use of 6MMPr as an antiviral against WNV in an immunocompetent mouse model. Once a day treatment of mice with 0.5 mg 6MMPr was just below the toxic dose in our mouse model, and this dose was used in subsequent studies. Mice were treated with 6MMPr immediately after subcutaneous inoculation with WNV for eight consecutive days. Treatment with 6MMPr exacerbated weight loss in WNV-inoculated mice and did not significantly affect mortality. We hypothesized that 6MMPr has low bioavailability in the central nervous system (CNS) and examined the effect of pre-treatment with 6MMPr on viral loads in the periphery and CNS. Pre-treatment with 6MMPr had no significant effect on viremia or viral titers in the periphery, but resulted in significantly higher viral loads in the brain, suggesting that the effect of 6MMPr is tissue-dependent. In conclusion, despite being a potent inhibitor of flaviviruses in cell culture, 6MMPr was not effective against West Nile disease in mice; however, further studies are warranted to reduce the toxicity and/or improve the bioavailability of this potential antiviral drug.

Monoclonal antibodies against dengue NS2B and NS3 proteins for the study of protein interactions in the flaviviral replication complex

The replication of dengue virus (DENV) RNA requires at least two viral non-structural (NS) proteins, NS3 and NS5. To facilitate the study of the DENV replication complex, human monoclonal IgG that are specific for NS proteins have been generated and characterised. The anti-NS3 IgG, 3F8, binds a conserved epitope (aa526-531) in the NS3 helicase domain, and cross-reacts with NS3 from all four DENV serotypes and the related yellow fever virus. The anti-NS2B IgG, 3F10, binds aa49-66 of NS2B (CF18), which forms part of the 47 aa hydrophilic cofactor region required for NS3 protease activity. The specificity of the IgG for their respective non-structural proteins has been demonstrated by immunofluorescence of cells infected with DENV and Western blotting. 3F8 is able to co-immunoprecipitate NS3 and NS5 from BHK-21 cells infected with DENV2, and 3F10 is able to detect an interaction between recombinant NS2B(CF18)NS3 full-length protein and the NS5 RNA-dependent RNA polymerase (RdRp) domain in an ELISA-based binding assay. The assay is specific and highly reproducible, with a clear binding curve seen when RdRp is incubated with increasing amounts of full-length NS3, but not the NS3 protease domain. The NS3 helicase domain competes with NS3 full-length for NS5 RdRp binding, with a K(d.) of 2.5μM. Since NS3 and NS5 are required for DENV replication, this fascile assay could be used to screen for non-nucleoside, allosteric inhibitors that disrupt the interaction between the two proteins.

Full-length Dengue virus RNA-dependent RNA polymerase-RNA/DNA complexes: stoichiometries, intrinsic affinities, cooperativities, base, and conformational specificities

Fundamental aspects of interactions of the Dengue virus type 3 full-length polymerase with the single-stranded and double-stranded RNA and DNA have been quantitatively addressed. The polymerase exists as a monomer with an elongated shape in solution. In the absence of magnesium, the total site size of the polymerase-ssRNA complex is 26 ± 2 nucleotides. In the presence of Mg(2+), the site size increases to 29 ± 2 nucleotides, indicating that magnesium affects the enzyme global conformation. The enzyme shows a preference for the homopyrimidine ssRNAs. Positive cooperativity in the binding to homopurine ssRNAs indicates that the type of nucleic acid base dramatically affects the enzyme orientation in the complex. Both the intrinsic affinity and the cooperative interactions are accompanied by a net ion release. The polymerase binds the dsDNA with an affinity comparable with the ssRNAs affinity, indicating that the binding site has an open conformation in solution. The lack of detectable dsRNA or dsRNA-DNA hybrid affinities indicates that the entry to the binding site is specific for the sugar-phosphate backbone and/or conformation of the duplex.

Functional RNA elements in the dengue virus genome

Dengue virus (DENV) genome amplification is a process that involves the viral RNA, cellular and viral proteins, and a complex architecture of cellular membranes. The viral RNA is not a passive template during this process; it plays an active role providing RNA signals that act as promoters, enhancers and/or silencers of the replication process. RNA elements that modulate RNA replication were found at the 5′ and 3′ UTRs and within the viral coding sequence. The promoter for DENV RNA synthesis is a large stem loop structure located at the 5′ end of the genome. This structure specifically interacts with the viral polymerase NS5 and promotes RNA synthesis at the 3′ end of a circularized genome. The circular conformation of the viral genome is mediated by long range RNA-RNA interactions that span thousands of nucleotides. Recent studies have provided new information about the requirement of alternative, mutually exclusive, structures in the viral RNA, highlighting the idea that the viral genome is flexible and exists in different conformations. In this article, we describe elements in the promoter SLA and other RNA signals involved in NS5 polymerase binding and activity, and provide new ideas of how dynamic secondary and tertiary structures of the viral RNA participate in the viral life cycle.

Focus on flaviviruses: current and future drug targets

BACKGROUND

Infection by mosquito-borne flaviviruses (family Flaviviridae) is increasing in prevalence worldwide. The vast global, social and economic impact due to the morbidity and mortality associated with the diseases caused by these viruses necessitates therapeutic intervention. There is currently no effective clinical treatment for any flaviviral infection. Therefore, there is a great need for the identification of novel inhibitors to target the virus life cycle.

DISCUSSION

In this article, we discuss structural and nonstructural viral proteins that are the focus of current target validation and drug discovery efforts. Both inhibition of essential enzymatic activities and disruption of necessary protein–protein interactions are considered. In addition, we address promising new targets for future research.

CONCLUSION

As our molecular and biochemical understanding of the flavivirus life cycle increases, the number of targets for antiviral therapeutic discovery grows and the possibility for novel drug discovery continues to strengthen.

Mutational analysis of three predicted 5'-proximal stem-loop structures in the genome of tick-borne encephalitis virus indicates different roles in RNA replication and translation

Flavivirus gene expression is modulated by RNA secondary structure elements at the terminal ends of the viral RNA molecule. For tick-borne encephalitis virus (TBEV), four stem-loop (SL) elements have been predicted in the first 180 nucleotides of the viral genome: 5'-SL1, 5'-SL2, 5'-SL3 and 5'-SL4. The last three of these appear to be unique to tick-borne flaviviruses. Here, we report their characterization by mutagenesis in a TBEV luciferase reporter system. By manipulating their thermodynamic properties, we found that an optimal stability of the 5'-SL2 is required for efficient RNA replication. 5'-SL3 formation is also important for viral RNA replication, but although it contains the viral start codon, its formation is dispensable for RNA translation. 5'-SL4 appears to facilitate both RNA translation and replication. Our data suggest that maintenance of the balanced thermodynamic stability of these SL elements is important for temporal regulation of its different functions.

Important advances in the field of anti-dengue virus research

There are currently no licensed antivirals available for the treatment of dengue virus (DENV), which causes significant morbidity and mortality throughout tropical areas of the world and is now encroaching on the southern United States. Recent improvements in existing animal models and cell culture systems have been very important in elucidating the mechanisms of DENV pathogenesis in humans, including the identification of potential viral and host proteins that might be targeted for the treatment of DENV infection. The AG129 mouse model is a major advance in the development of antiviral and vaccine candidates for clinical use. It allows for testing of potential therapeutics in a relevant system that exhibits some aspects of disease that are similar to those observed in humans. This review focuses on recent developments in the AG129 mouse model and discusses compounds that have been found to be active in available cell and animal model systems within the past year.

The F1 motif of dengue virus polymerase NS5 is involved in promoter-dependent RNA synthesis

The mechanism by which viral RNA-dependent RNA polymerases (RdRp) specifically amplify viral genomes is still unclear. In the case of flaviviruses, a model has been proposed that involves the recognition of an RNA element present at the viral 5' untranslated region, stem-loop A (SLA), that serves as a promoter for NS5 polymerase binding and activity. Here, we investigated requirements for specific promoter-dependent RNA synthesis of the dengue virus NS5 protein. Using mutated purified NS5 recombinant proteins and infectious viral RNAs, we analyzed the requirement of specific amino acids of the RdRp domain on polymerase activity and viral replication. A battery of 19 mutants was designed and analyzed. By measuring polymerase activity using nonspecific poly(rC) templates or specific viral RNA molecules, we identified four mutants with impaired polymerase activity. Viral full-length RNAs carrying these mutations were found to be unable to replicate in cell culture. Interestingly, one recombinant NS5 protein carrying the mutations K456A and K457A located in the F1 motif lacked RNA synthesis dependent on the SLA promoter but displayed high activity using a poly(rC) template. Promoter RNA binding of this NS5 mutant was unaffected while de novo RNA synthesis was abolished. Furthermore, the mutant maintained RNA elongation activity, indicating a role of the F1 region in promoter-dependent initiation. In addition, four NS5 mutants were selected to have polymerase activity in the recombinant protein but delayed or impaired virus replication when introduced into an infectious clone, suggesting a role of these amino acids in other functions of NS5. This work provides new molecular insights on the specific RNA synthesis activity of the dengue virus NS5 polymerase.

Functional analysis of two cavities in flavivirus NS5 polymerase

Flavivirus NS5 protein encodes methyltransferase and RNA-dependent RNA polymerase (RdRp) activities. Structural analysis of flavivirus RdRp domains uncovered two conserved cavities (A and B). Both cavities are located in the thumb subdomains and represent potential targets for development of allosteric inhibitors. In this study, we used dengue virus as a model to analyze the function of the two RdRp cavities. Amino acids from both cavities were subjected to mutagenesis analysis in the context of genome-length RNA and recombinant NS5 protein; residues critical for viral replication were subjected to revertant analysis. For cavity A, we found that only one (Lys-756) of the seven selected amino acids is critical for viral replication. Alanine substitution of Lys-756 did not affect the RdRp activity, suggesting that this residue functions through a nonenzymatic mechanism. For cavity B, all four selected amino acids (Leu-328, Lys-330, Trp-859, and Ile-863) are critical for viral replication. Biochemical and revertant analyses showed that three of the four mutated residues (Leu-328, Trp-859, and Ile-863) function at the step of initiation of RNA synthesis, whereas the fourth residue (Lys-330) functions by interacting with the viral NS3 helicase domain. Collectively, our results have provided direct evidence for the hypothesis that cavity B, but not cavity A, from dengue virus NS5 polymerase could be a target for rational drug design.

Sequencing of a tick-borne encephalitis virus from Ixodes ricinus reveals a thermosensitive RNA switch significant for virus propagation in ectothermic arthropods

Tick-borne encephalitis virus (TBEV) is a flavivirus with major impact on global health. The geographical TBEV distribution is expanding, thus making it pivotal to further characterize the natural virus populations. In this study, we completed the earlier partial sequencing of a TBEV pulled out of a pool of RNA extracted from 115 ticks collected on Torö in the Stockholm archipelago. The total RNA was sufficient for all sequencing of a TBEV genome (Torö-2003), without conventional enrichment procedures such as cell culturing or suckling mice amplification. To our knowledge, this is the first time that the genome of TBEV has been sequenced directly from an arthropod reservoir. The Torö-2003 sequence has been characterized and compared with other TBE viruses. In silico analyses of secondary RNA structures formed by the two untranslated regions revealed a temperature-sensitive structural shift between a closed replicative form and an open AUG accessible form, analogous to a recently described bacterial thermoswitch. Additionally, novel phylogenetic conserved structures were identified in the variable part of the 3'-untranslated region, and their sequence and structure similarity when compared with earlier identified structures suggests an enhancing function on virus replication and translation. We propose that the thermo-switch mechanism may explain the low TBEV prevalence often observed in environmentally sampled ticks. Finally, we were able to detect variations that help in the understanding of virus adaptations to varied environmental temperatures and mammalian hosts through a comparative approach that compares RNA folding dynamics between strains with different mammalian cell passage histories.

A fluorescence-based alkaline phosphatase-coupled polymerase assay for identification of inhibitors of dengue virus RNA-dependent RNA polymerase

The flaviviral RNA-dependent RNA polymerase (RdRp) is an attractive drug target. To discover new inhibitors of dengue virus RdRp, the authors have developed a fluorescence-based alkaline phosphatase-coupled polymerase assay (FAPA) for high-throughput screening (HTS). A modified nucleotide analogue (2'-[2-benzothiazoyl]-6'-hydroxybenzothiazole) conjugated adenosine triphosphate (BBT-ATP) and 3'UTR-U(30) RNA were used as substrates. After the polymerase reaction, treatment with alkaline phosphatase liberates the BBT fluorophore from the polymerase reaction by-product, BBT(PPi), which can be detected at excitation and emission wavelengths of 422 and 566 nm, respectively. The assay was evaluated by examining the time dependency, assay reagent effects, reaction kinetics, and signal stability and was validated with 3'dATP and an adenosine-nucleotide triphosphate inhibitor, giving IC(50) values of 0.13 µM and 0.01 µM, respectively. A pilot screen of a diverse compound library of 40,572 compounds at 20 µM demonstrated good performance with an average Z factor of 0.81. The versatility and robustness of FAPA were evaluated with another substrate system, BBT-GTP paired with 3'UTR-C(30) RNA. The FAPA method presented here can be readily adapted for other nucleotide-dependent enzymes that generate PPi.

A comprehensive structure-function comparison of hepatitis C virus strain JFH1 and J6 polymerases reveals a key residue stimulating replication in cell culture across genotypes

The hepatitis C virus (HCV) genotype 2a isolate JFH1 represents the only cloned HCV wild-type sequence capable of efficient replication in cell culture as well as in vivo. Previous reports have pointed to NS5B, the viral RNA-dependent RNA polymerase (RdRp), as a major determinant for efficient replication of this isolate. To understand the contribution of the JFH1 NS5B gene at the molecular level, we aimed at conferring JFH1 properties to NS5B from the closely related J6 isolate. We created intragenotypic chimeras in the NS5B regions of JFH1 and J6 and compared replication efficiency in cell culture and RdRp activity of the purified proteins in vitro, revealing more than three independent mechanisms conferring the role of JFH1 NS5B in efficient RNA replication. Most critical was residue I405 in the thumb domain of the polymerase, which strongly stimulated replication in cell culture by enhancing overall de novo RNA synthesis. A structural comparison of JFH1 and J6 at high resolution indicated a clear correlation of a closed-thumb conformation of the RdRp and the efficiency of the enzyme at de novo RNA synthesis, in accordance with the proposal that I405 enhances de novo initiation. In addition, we identified several residues enhancing replication independent of RdRp activity in vitro. The functional properties of JFH1 NS5B could be restored by a few single-nucleotide substitutions to the J6 isolate. Finally, we were able to enhance the replication efficiency of a genotype 1b isolate with the I405 mutation, indicating that this mechanism of action is conserved across genotypes.

RNA sequences and structures required for the recruitment and activity of the dengue virus polymerase

Dengue virus RNA-dependent RNA polymerase specifically binds to the viral genome by interacting with a promoter element known as stem-loop A (SLA). Although a great deal has been learned in recent years about the function of this promoter in dengue virus-infected cells, the molecular details that explain how the SLA interacts with the polymerase to promote viral RNA synthesis remain poorly understood. Using RNA binding and polymerase activity assays, we defined two elements of the SLA that are involved in polymerase interaction and RNA synthesis. Mutations at the top of the SLA resulted in RNAs that retained the ability to bind the polymerase but impaired promoter-dependent RNA synthesis. These results indicate that protein binding to the SLA is not sufficient to induce polymerase activity and that specific nucleotides of the SLA are necessary to render an active polymerase-promoter complex for RNA synthesis. We also report that protein binding to the viral RNA induces conformational changes downstream of the promoter element. Furthermore, we found that structured RNA elements at the 3' end of the template repress dengue virus polymerase activity in the context of a fully active SLA promoter. Using assays to evaluate initiation of RNA synthesis at the viral 3'-UTR, we found that the RNA-RNA interaction mediated by 5'-3'-hybridization was able to release the silencing effect of the 3'-stem-loop structure. We propose that the long range RNA-RNA interactions in the viral genome play multiple roles during RNA synthesis. Together, we provide new molecular details about the promoter-dependent dengue virus RNA polymerase activity.

Organelle-like membrane compartmentalization of positive-strand RNA virus replication factories

Positive-strand RNA virus genome replication is invariably associated with extensively rearranged intracellular membranes. Recent biochemical and electron microscopy analyses, including three-dimensional electron microscope tomographic imaging, have fundamentally advanced our understanding of the ultrastructure and function of organelle-like RNA replication factories. Notably, for a range of positive-strand RNA viruses embodying many major differences, independent studies have revealed multiple common principles. These principles include that RNA replication often occurs inside numerous virus-induced vesicles invaginated or otherwise elaborated from a continuous, often endoplasmic reticulum-derived membrane network. Where analyzed, each such vesicle typically contains only one or a few genome replication intermediates in conjunction with many copies of viral nonstructural proteins. In addition, these genome replication compartments often are closely associated with sites of virion assembly and budding. Our understanding of these complexes is growing, providing substantial new insights into the organization, coordination, and potential control of crucial processes in virus replication.

Comparative analysis of full-length genomic sequences of 10 dengue serotype 1 viruses associated with different genotypes, epidemics, and disease severity isolated in Thailand over 22 years

Comparative sequence analysis was performed on the full-length genomic sequences of 10 representative dengue virus serotype 1 (DENV-1) strains sampled from patients at Children's Hospital, Bangkok, Thailand over a 22-year period, which represented different epidemics, disease severity, and sampling time. The results showed remarkable inter-genotypic variation between predominant and non-predominant genotypes and genotype-specific amino acids and nucleotides throughout the entire viral genome except for the 5'-non-translated region. The frequency of intra-genotypic variation was correlated with dengue transmission rate and sampling time. The 5'-non-translated region of all 10 viruses was highly conserved for predominant and non-predominant genotypes and NS2B was the most conserved protein. Some intra-genotypic substitutions of amino acids and nucleotides in predominant genotype strains were fixed in the viral genome since 1994, which indicated that the evolution of predominant genotype strains in situ over time might contribute to increased virus fitness important for sustaining dengue epidemics in Thailand.

Characterization of the elongation complex of dengue virus RNA polymerase: assembly, kinetics of nucleotide incorporation, and fidelity

Dengue virus (DENV) infects 50–100 million people worldwide per year, causing severe public health problems. DENV RNA-dependent RNA polymerase, an attractive target for drug development, catalyzes de novo replication of the viral genome in three phases: initiation, transition, and elongation. The aim of this work was to characterize the mechanism of nucleotide addition catalyzed by the polymerase domain of DENV serotype 2 during elongation using transient kinetic methods. We measured the kinetics of formation of the elongation complex containing the polymerase and a double-stranded RNA by preincubation experiments. The elongation complex assembly is slow, following a one-step binding mechanism with an association rate of 0.0016 ± 0.0001 μm⁻¹s⁻¹ and a dissociation rate of 0.00020 ± 0.00005 s⁻¹ at 37 °C. The elongation complex assembly is 6 times slower at 30 °C and requires Mg²⁺ during preincubation. The assembled elongation complex incorporates a correct nucleotide, GTP, to the primer with a K_d of 275 ± 52 μm and k_pol of 18 ± 1 s⁻¹. The fidelity of the polymerase is 1/34,000, 1/59,000, 1/135,000 for misincorporation of UTP, ATP, and CTP opposite CMP in the template, respectively. The fidelity of DENV polymerase is comparable with HIV reverse transcriptase and the poliovirus polymerase. This work reports the first description of presteady-state kinetics and fidelity for an RNA-dependent RNA polymerase from the Flaviviridae family.

Zn(2+) inhibits coronavirus and arterivirus RNA polymerase activity in vitro and zinc ionophores block the replication of these viruses in cell culture

Increasing the intracellular Zn²⁺ concentration with zinc-ionophores like pyrithione (PT) can efficiently impair the replication of a variety of RNA viruses, including poliovirus and influenza virus. For some viruses this effect has been attributed to interference with viral polyprotein processing. In this study we demonstrate that the combination of Zn²⁺ and PT at low concentrations (2 µM Zn²⁺ and 2 µM PT) inhibits the replication of SARS-coronavirus (SARS-CoV) and equine arteritis virus (EAV) in cell culture. The RNA synthesis of these two distantly related nidoviruses is catalyzed by an RNA-dependent RNA polymerase (RdRp), which is the core enzyme of their multiprotein replication and transcription complex (RTC). Using an activity assay for RTCs isolated from cells infected with SARS-CoV or EAV—thus eliminating the need for PT to transport Zn²⁺ across the plasma membrane—we show that Zn²⁺ efficiently inhibits the RNA-synthesizing activity of the RTCs of both viruses. Enzymatic studies using recombinant RdRps (SARS-CoV nsp12 and EAV nsp9) purified from E. coli subsequently revealed that Zn²⁺ directly inhibited the in vitro activity of both nidovirus polymerases. More specifically, Zn²⁺ was found to block the initiation step of EAV RNA synthesis, whereas in the case of the SARS-CoV RdRp elongation was inhibited and template binding reduced. By chelating Zn²⁺ with MgEDTA, the inhibitory effect of the divalent cation could be reversed, which provides a novel experimental tool for in vitro studies of the molecular details of nidovirus replication and transcription.

Positive-stranded RNA (+RNA) viruses include many important pathogens. They have evolved a variety of replication strategies, but are unified in the fact that an RNA-dependent RNA polymerase (RdRp) functions as the core enzyme of their RNA-synthesizing machinery. The RdRp is commonly embedded in a membrane-associated replication complex that is assembled from viral RNA, and viral and host proteins. Given their crucial function in the viral replicative cycle, RdRps are key targets for antiviral research. Increased intracellular Zn²⁺ concentrations are known to efficiently impair replication of a number of RNA viruses, e.g. by interfering with correct proteolytic processing of viral polyproteins. Here, we not only show that corona- and arterivirus replication can be inhibited by increased Zn²⁺ levels, but also use both isolated replication complexes and purified recombinant RdRps to demonstrate that this effect may be based on direct inhibition of nidovirus RdRps. The combination of protocols described here will be valuable for future studies into the function of nidoviral enzyme complexes.

Recent developments in understanding dengue virus replication

Dengue is the most important cause of mosquito-borne virus diseases in tropical and subtropical regions in the world. Severe clinical outcomes such as dengue hemorrhagic fever and dengue shock syndrome are potentially fatal. The epidemiology of dengue has undergone profound changes in recent years, due to several factors such as expansion of the geographical distribution of the insect vector, increase in traveling, and demographic pressure. As a consequence, the incidence of dengue has increased dramatically. Since mosquito control has not been successful and since no vaccine or antiviral treatment is available, new approaches to this problem are needed. Consequently, an in-depth understanding of the molecular and cellular biology of the virus should be helpful to design efficient strategies for the control of dengue. Here, we review the recently acquired knowledge on the molecular and cell biology of the dengue virus life cycle based on newly developed molecular biology technologies.

Yet another ten stories on antiviral drug discovery (part D): paradigms, paradoxes, and paraductions

This review article presents the fourth part (part D) in the series of stories on antiviral drug discovery. The stories told in part D focus on: (i) the cyclotriazadisulfonamide compounds; (ii) the {5-[(4-bromophenylmethyl]-2-phenyl-5H-imidazo[4,5-c]pyridine} compounds; (iii) (1H,3H-thiazolo[3,4-a]benzimidazole) derivatives; (iv) T-705 (6-fluoro-3-hydroxy-2-pyrazinecarboxamide) and (v) its structurally closely related analogue pyrazine 2-carboxamide (pyrazinamide); (vi) new strategies for the treatment of hemorrhagic fever virus infections, including, as the most imminent, (vii) dengue fever, (viii) the veterinary use of acyclic nucleoside phosphonates; (ix) the potential (off-label) use of cidofovir in the treatment of papillomatosis, particularly RRP (recurrent respiratory papillomatosis); and (x) finally, the prophylactic use of tenofovir to prevent HIV infections.

Crystal structure of the dengue virus methyltransferase bound to a 5'-capped octameric RNA

The N-terminal domain of the flavivirus NS5 protein functions as a methyltransferase (MTase). It sequentially methylates the N7 and 2'-O positions of the viral RNA cap structure (GpppA→(7me)GpppA→(7me)GpppA(2'-O-me)). The same NS5 domain could also have a guanylyltransferase activity (GTP+ppA-RNA→GpppA). The mechanism by which this protein domain catalyzes these three distinct functions is currently unknown. Here we report the crystallographic structure of DENV-3 MTase in complex with a 5'-capped RNA octamer (G(ppp)AGAACCUG) at a resolution of 2.9 A. Two RNA octamers arranged as kissing loops are encircled by four MTase monomers around a 2-fold non-crystallography symmetry axis. Only two of the four monomers make direct contact with the 5' end of RNA. The RNA structure is stabilised by the formation of several intra and intermolecular base stacking and non-canonical base pairs. The structure may represent the product of guanylylation of the viral genome prior to the subsequent methylation events that require repositioning of the RNA substrate to reach to the methyl-donor sites. The crystal structure provides a structural explanation for the observed trans-complementation of MTases with different methylation defects.

Further insights into the roles of GTP and the C terminus of the hepatitis C virus polymerase in the initiation of RNA synthesis

The hepatitis C virus (HCV) NS5b protein is an RNA-dependent RNA polymerase essential for replication of the viral RNA genome. In vitro and presumably in vivo, NS5b initiates RNA synthesis by a de novo mechanism. Different structural elements of NS5b have been reported to participate in RNA synthesis, especially a so-called "β-flap" and a C-terminal segment (designated "linker") that connects the catalytic core of NS5b to a transmembrane anchor. High concentrations of GTP have also been shown to stimulate de novo RNA synthesis by HCV NS5b. Here we describe a combined structural and functional analysis of genotype 1 HCV-NS5b of strains H77 (subtype 1a), for which no structure has been previously reported, and J4 (subtype 1b). Our results highlight the linker as directly involved in lifting the first boundary to processive RNA synthesis, the formation of the first dinucleotide primer. The transition from this first dinucleotide primer state to processive RNA synthesis requires removal of the linker and of the β-flap with which it is shown to strongly interact in crystal structures of HCV NS5b. We find that GTP specifically stimulates this transition irrespective of its incorporation in neosynthesized RNA.

Structure and functionality in flavivirus NS-proteins: perspectives for drug design

Flaviviridae are small enveloped viruses hosting a positive-sense single-stranded RNA genome. Besides yellow fever virus, a landmark case in the history of virology, members of the Flavivirus genus, such as West Nile virus and dengue virus, are increasingly gaining attention due to their re-emergence and incidence in different areas of the world. Additional environmental and demographic considerations suggest that novel or known flaviviruses will continue to emerge in the future. Nevertheless, up to few years ago flaviviruses were considered low interest candidates for drug design. At the start of the European Union VIZIER Project, in 2004, just two crystal structures of protein domains from the flaviviral replication machinery were known. Such pioneering studies, however, indicated the flaviviral replication complex as a promising target for the development of antiviral compounds. Here we review structural and functional aspects emerging from the characterization of two main components (NS3 and NS5 proteins) of the flavivirus replication complex. Most of the reviewed results were achieved within the European Union VIZIER Project, and cover topics that span from viral genomics to structural biology and inhibition mechanisms. The ultimate aim of the reported approaches is to shed light on the design and development of antiviral drug leads.

Characterization of dengue virus resistance to brequinar in cell culture

Brequinar is an inhibitor of dihydroorotate dehydrogenase, an enzyme that is required for de novo pyrimidine biosynthesis. Here we report that brequinar has activity against a broad spectrum of viruses. The compound not only inhibits flaviviruses (dengue virus, West Nile virus, yellow fever virus, and Powassan virus) but also suppresses a plus-strand RNA alphavirus (Western equine encephalitis virus) and a negative-strand RNA rhabdovirus (vesicular stomatitis virus). Using dengue virus serotype 2 (DENV-2) as a model, we found that brequinar suppressed the viral infection cycle mainly at the step of RNA synthesis. Supplementing the culture medium with pyrimidines (cytidine or uridine) but not purines (adenine or guanine) could be used to reverse the inhibitory effect of the compound. Continuous culturing of DENV-2 in the presence of brequinar generated viruses that were partially resistant to the inhibitor. Sequencing of the resistant viruses revealed two amino acid mutations: one mutation (M260V) located at a helix in the domain II of the viral envelope protein and another mutation (E802Q) located at the priming loop of the nonstructural protein 5 (NS5) polymerase domain. Functional analysis of the mutations suggests that the NS5 mutation exerts resistance through enhancement of polymerase activity. The envelope protein mutation reduced the efficiency of virion assembly/release; however, the mutant virus became less sensitive to brequinar inhibition at the step of virion assembly/release. Taken together, the results indicate that (i) brequinar blocks DENV RNA synthesis through depletion of intracellular pyrimidine pools and (ii) the compound may also exert its antiviral activity through inhibition of virion assembly/release.

Structures of EV71 RNA-dependent RNA polymerase in complex with substrate and analogue provide a drug target against the hand-foot-and-mouth disease pandemic in China

Enterovirus 71 (EV71), one of the major causative agents for hand-foot-and-mouth disease (HFMD), has caused more than 100 deaths among Chinese children since March 2008. The EV71 genome encodes an RNAdependent RNA polymerase (RdRp), denoted 3D(pol), which is central for viral genome replication and is a key target for the discovery of specific antiviral therapeutics. Here we report the crystal structures of EV71 RdRp (3D(pol)) and in complex with substrate guanosine-5'-triphosphate and analog 5-bromouridine-5'-triphosphate best to 2.4 Å resolution. The structure of EV71 RdRp (3D(pol)) has a wider open thumb domain compared with the most closely related crystal structure of poliovirus RdRp. And the EV71 RdRp (3D(pol)) complex with GTP or Br-UTP bounded shows two distinct movements of the polymerase by substrate or analogue binding. The model of the complex with the template:primer derived by superimposition with foot-and-mouth disease virus (FMDV) 3D/RNA complex reveals the likely recognition and binding of template:primer RNA by the polymerase. These results together provide a molecular basis for EV71 RNA replication and reveal a potential target for anti-EV71 drug discovery.

Biochemical characterization of the inhibition of the dengue virus RNA polymerase by beta-d-2'-ethynyl-7-deaza-adenosine triphosphate

Dengue virus (DENV), an emerging pathogen from the Flaviviridae family with neither vaccine nor antiviral treatment available, causes a serious worldwide public health threat. In theory, there are several ways by which small molecules could inhibit the replication cycle of DENV. Here, we show that the nucleoside analogue beta-d-2'-ethynyl-7-deaza-adenosine inhibits representative strains of all four serotypes of DENV with an EC(50) around or below 1microM. Using membrane-associated native replicase complex as well as recombinant RNA polymerase from each DENV serotype in enzymatic assays, we provide evidence that beta-d-2'-ethynyl-7-deaza-adenosine triphosphate (2'E-7D-ATP) targets viral replication at the polymerase active site by competing with the natural nucleotide substrate with an apparent K(i) of 0.060+/-0.016microM. In single-nucleotide incorporation experiments, the catalytic efficiency of 2'E-7D-ATP is 10-fold lower than for natural ATP, and the incorporated nucleotide analogue causes immediate chain termination. A combination of bioinformatics and site-directed mutagenesis demonstrates that 2'E-7D-ATP is equipotent across all serotypes because the nucleotide binding site residues are conserved in dengue virus. Overall, beta-d-2'-ethynyl-7-deaza-adenosine provides a promising scaffold for the development of inhibitors of dengue virus polymerase.

Acoustic matrix microseeding: improving protein crystal growth with minimal chemical bias

A crystal seeding technique is introduced that uses acoustic waves to deliver nanolitre volumes of seed suspension into protein drops. The reduction in delivery volume enables enhanced crystal growth in matrix-seeding experiments without concern for bias from chemical components in the seed-carrying buffer suspension. Using this technique, it was found that while buffer components alone without seed can marginally promote crystal growth in some cases, crystal seeding is far more effective in boosting the number of sparse-matrix conditions that yield protein crystals.

Mechanisms of evasion of the type I interferon antiviral response by flaviviruses

Virus survival and the ability to cause disease in mammalian hosts depend on their ability to avoid recognition and control by the interferon signal transduction and effector pathways. Flaviviruses comprise a large family of nonsegmented positive sense enveloped cytoplasmic RNA viruses, many of which are globally important human pathogens. Although the mechanistic details are still being dissected, new insight has emerged as to how a flavivirus minimizes the antiviral activity of type I interferon (IFN) to establish productive and potentially lethal infection. This review will summarize our current understanding of how mammalian cells recognize flaviviruses to induce an inhibitory IFN response and the countermeasures this group of viruses has evolved to antagonize this response.

Strategies for the treatment of dengue virus infections: a narrative account

In comparison with other virus infections, such as HIV, HBV, HCV, influenza and herpes virus, dengue virus infections have received relatively little attention from a (chemo)therapeutic viewpoint, despite their global incidence (2.5 billion people estimated to be at risk) and absence of an effective prophylactic measure (i.e., vaccination). However, the replicative cycle of the dengue virus offers a wealth of potential target sites, including virus adsorption and fusion, RNA-dependent RNA polymerase (and the associated 2´-O-methyltransferase) and the N-glycosylation process. Numerous compounds have been identified that interfere with dengue virus infections (i.e., ribavirin, interferon, sulfated polysaccharides, 2´-C-methylnucleoside analogs and iminosugar derivatives). For other compounds found to be effective against the dengue virus, including geneticin (G418) and FGI-106, the mechanism of action still remains unresolved.

Interplay of RNA elements in the dengue virus 5' and 3' ends required for viral RNA replication

Dengue virus (DENV) is a member of the Flavivirus genus of positive-sense RNA viruses. DENV RNA replication requires cyclization of the viral genome mediated by two pairs of complementary sequences in the 5' and 3' ends, designated 5' and 3' cyclization sequences (5'-3' CS) and the 5' and 3' upstream of AUG region (5'-3' UAR). Here, we demonstrate that another stretch of six nucleotides in the 5' end is involved in DENV replication and possibly genome cyclization. This new sequence is located downstream of the AUG, designated the 5' downstream AUG region (5' DAR); the motif predicted to be complementary in the 3' end is termed the 3' DAR. In addition to the UAR, CS and DAR motifs, two other RNA elements are located at the 5' end of the viral RNA: the 5' stem-loop A (5' SLA) interacts with the viral RNA-dependent RNA polymerase and promotes RNA synthesis, and a stem-loop in the coding region named cHP is involved in translation start site selection as well as RNA replication. We analyzed the interplay of these 5' RNA elements in relation to RNA replication, and our data indicate that two separate functional units are formed; one consists of the SLA, and the other includes the UAR, DAR, cHP, and CS elements. The SLA must be located at the 5' end of the genome, whereas the position of the second unit is more flexible. We also show that the UAR, DAR, cHP, and CS must act in concert and therefore likely function together to form the tertiary RNA structure of the circularized DENV genome.

Evidence for inter- and intra-genotypic variations in dengue serotype 4 viruses representing predominant and non-predominant genotypes co-circulating in Thailand from 1977 to 2001

In order to characterize viral genetic variation among predominant and non-predominant genotypes of Thai dengue serotype 4 viruses (DENV-4) and follow mutations that occur during virus evolution, we performed a comparative analysis of the complete genomic sequences of six DENV-4 isolates representing three genotypes (I, IIA, and III) co-circulating in Thailand over a 24-year period. The results revealed [1] remarkable genetic variation in the viral genome between predominant and non-predominant genotypes; [2] inter-genotype-specific amino acid and nucleotide mutations in most regions of the viral genome; [3] more amino acid and nucleotide substitutions in later as compared to earlier isolates for predominant genotype I strains; [4] a single nucleotide substitution at nucleotide position 77 of the 5-'NTR of two non-predominant genotype III strains that disrupted a small conserved 3'stem-loop (SL) in the cyclization sequence required for virus replication; [5] a high degree of conservation of PrM/M and NS2B proteins, and the 5'-NTR in predominant genotype I strains with no mutations observed over the 24-year period of observation; and [6] no molecular markers that appeared to correlate with disease severity. Several mutations identified in this study might have a significant impact on the persistence of virus in the population, including one in the 5'-NTR that disrupted a small, highly conserved 3'SL2 structure at the terminus of the cyclized 5'-3' RNA sequences in two genotype III strains, and three amino acid (aa) charge change mutations in the E and NS5 proteins of genotype I strains. The conserved 3'-SL structure may be a target for antiviral drug development.

Inhibition of dengue virus polymerase by blocking of the RNA tunnel

Dengue virus (DENV) is the most prevalent mosquito-borne viral pathogen in humans. Neither vaccine nor antiviral therapy is currently available for DENV. We report here that N-sulfonylanthranilic acid derivatives are allosteric inhibitors of DENV RNA-dependent RNA polymerase (RdRp). The inhibitor was identified through high-throughput screening of one million compounds using a primer extension-based RdRp assay [substrate poly(C)/oligo(G)(20)]. Chemical modification of the initial "hit" improved the compound potency to an IC(50) (that is, a concentration that inhibits 50% RdRp activity) of 0.7 microM. In addition to suppressing the primer extension-based RNA elongation, the compound also inhibited de novo RNA synthesis using a DENV subgenomic RNA, but at a lower potency (IC(50) of 5 microM). Remarkably, the observed anti-polymerase activity is specific to DENV RdRp; the compound did not inhibit WNV RdRp and exhibited IC(50)s of >100 microM against hepatitis C virus RdRp and human DNA polymerase alpha and beta. UV cross-linking and mass spectrometric analysis showed that a photoreactive inhibitor could be cross-linked to Met343 within the RdRp domain of DENV NS5. On the crystal structure of DENV RdRp, Met343 is located at the entrance of RNA template tunnel. Biochemical experiments showed that the order of addition of RNA template and inhibitor during the assembly of RdRp reaction affected compound potency. Collectively, the results indicate that the compound inhibits RdRp through blocking the RNA tunnel. This study has provided direct evidence to support the hypothesis that allosteric pockets from flavivirus RdRp could be targeted for antiviral development.

N-sulfonylanthranilic acid derivatives as allosteric inhibitors of dengue viral RNA-dependent RNA polymerase

A novel class of compounds containing N-sulfonylanthranilic acid was found to specifically inhibit dengue viral polymerase. The structural requirements for inhibition and a preliminary structure-activity relationship are described. A UV cross-linking experiment was used to map the allosteric binding site of the compound on the viral polymerase.

The flavivirus NS5 protein is a true RNA guanylyltransferase that catalyzes a two-step reaction to form the RNA cap structure

The 5'-end of the flavivirus genome harbors a methylated (m7)GpppA(2'OMe) cap structure, which is generated by the virus-encoded RNA triphosphatase, RNA (guanine-N7) methyltransferase, nucleoside 2'-O-methyltransferase, and RNA guanylyltransferase. The presence of the flavivirus guanylyltransferase activity in NS5 has been suggested by several groups but has not been empirically proven. Here we provide evidence that the N-terminus of the flavivirus NS5 protein is a true RNA guanylyltransferase. We demonstrate that GTP can be used as a substrate by the enzyme to form a covalent GMP-enzyme intermediate via a phosphoamide bond. Mutational studies also confirm the importance of a specific lysine residue in the GTP binding site for the enzymatic activity. We show that the GMP moiety can be transferred to the diphosphate end of an RNA transcript harboring an adenosine as the initiating residue. We also demonstrate that the flavivirus RNA triphosphatase (NS3 protein) stimulates the RNA guanylyltransferase activity of the NS5 protein. Finally, we show that both enzymes are sufficient and necessary to catalyze the de novo formation of a methylated RNA cap structure in vitro using a triphosphorylated RNA transcript. Our study provides biochemical evidence that flaviviruses encode a complete RNA capping machinery.

RNA-dependent RNA polymerases from Flaviviridae

Viral genome replication in Flaviviridae is carried out by a virally encoded RNA-dependent RNA polymerase (RdRp). These viruses initiate the RNA synthesis via a de novo mechanism that differs from the primer-dependent mechanism used by Picornaviridae. Like all polymerases, the structure of Flaviviridae RdRps resembles a right hand with characteristic fingers, palm, and thumb domains. Structural features that distinguish Flaviviridae RdRps from other polymerases are a large thumb domain and a C-terminal motif that encircles the active site. This domain arrangement restricts the volume of the template-binding channel, allowing only single-stranded RNA to enter the active site. While this closed form of the polymerase is ideal to stabilize a de novo initiation complex, significant conformational changes are expected to accommodate the elongation complex containing the RNA duplex product.

RNA-dependent RNA polymerases from flaviviruses and Picornaviridae

Flaviviruses and picornaviruses are positive-strand RNA viruses that encode the RNA-dependent RNA polymerase (RdRp) required for replicating the viral genome in infected cells. Because of their specific and essential role in the virus life cycle, RdRps are prime targets for antiviral drugs. Recent structural data have shed light on the different strategies used by RdRps from flaviviruses and Picornaviridae to initiate RNA polymerization. New details about the catalytic mechanism, the role of metal ions, how these RdRps interact with other nonstructural (NS) viral and host-cell proteins as well as with the viral RNA genome have also been published. These advances contribute to give a more complete picture of the 3D structure and mechanism of a membrane-bound viral replication complex for these two classes of medically important human pathogens.

The RNA polymerase activity of SARS-coronavirus nsp12 is primer dependent

An RNA-dependent RNA polymerase (RdRp) is the central catalytic subunit of the RNA-synthesizing machinery of all positive-strand RNA viruses. Usually, RdRp domains are readily identifiable by comparative sequence analysis, but biochemical confirmation and characterization can be hampered by intrinsic protein properties and technical complications. It is presumed that replication and transcription of the approximately 30-kb severe acute respiratory syndrome (SARS) coronavirus (SARS-CoV) RNA genome are catalyzed by an RdRp domain in the C-terminal part of nonstructural protein 12 (nsp12), one of 16 replicase subunits. However, thus far full-length nsp12 has proven refractory to expression in bacterial systems, which has hindered both the biochemical characterization of coronavirus RNA synthesis and RdRp-targeted antiviral drug design. Here, we describe a combined strategy involving bacterial expression of an nsp12 fusion protein and its in vivo cleavage to generate and purify stable SARS-CoV nsp12 (106 kDa) with a natural N-terminus and C-terminal hexahistidine tag. This recombinant protein possesses robust in vitro RdRp activity, as well as a significant DNA-dependent activity that may facilitate future inhibitor studies. The SARS-CoV nsp12 is primer dependent on both homo- and heteropolymeric templates, supporting the likeliness of a close enzymatic collaboration with the intriguing RNA primase activity that was recently proposed for coronavirus nsp8.

Chapter 2. New insights into flavivirus nonstructural protein 5

Disease caused by flavivirus infections is an increasing world health problem. Flavivirus nonstructural protein 5 (NS5) possesses enzymatic activities required for capping and synthesis of the viral RNA genome and is essential for virus replication. NS5 is comprised of two domains. The N-terminal domain binds GTP and can perform two biochemically distinct methylation reactions required for RNA cap formation. The C-terminal domain contains RNA-dependent RNA polymerase activity. As such, NS5 is an interesting target against which antiviral drugs could be developed and research toward this goal has accelerated our understanding of NS5 structure and function in recent years. The production and purification of recombinant versions of either the full-length NS5 or the two individual NS5 domains has led to detailed enzymatic studies on NS5 and the determination of structures of the two NS5 domains. In turn, studies using a combination of structural, biochemical, and reverse genetic approaches are revealing how NS5 performs its multifunctional roles in genome replication. Aside from its localization in the membrane-bound replication complex, NS5 can be found free in the cytoplasm and for some flaviviruses in the nucleus of virus-infected cells. NS5 is phosphorylated which may potentially regulate NS5 function and trafficking. Recently, NS5 of a number of flaviviruses has been shown to interact with cellular pathways involved in the host immune response, suggesting that NS5 may play a role in viral pathogenesis. This chapter reviews recent advances in our understanding of the multifunctional roles played by NS5 in the virus lifecycle.

Biochemical characterization of the (nucleoside-2'O)-methyltransferase activity of dengue virus protein NS5 using purified capped RNA oligonucleotides (7Me)GpppAC(n) and GpppAC(n)

The flavivirus RNA genome contains a conserved cap-1 structure, (7Me)GpppA(2'OMe)G, at the 5' end. Two mRNA cap methyltransferase (MTase) activities involved in the formation of the cap, the (guanine-N7)- and the (nucleoside-2'O)-MTases (2'O-MTase), reside in a single domain of non-structural protein NS5 (NS5MTase). This study reports on the biochemical characterization of the 2'O-MTase activity of NS5MTase of dengue virus (NS5MTase(DV)) using purified, short, capped RNA substrates ((7Me)GpppAC(n) or GpppAC(n)). NS5MTase(DV) methylated both types of substrate exclusively at the 2'O position. The efficiency of 2'O-methylation did not depend on the methylation of the N7 position. Using (7Me)GpppAC(n) and GpppAC(n) substrates of increasing chain lengths, it was found that both NS5MTase(DV) 2'O activity and substrate binding increased before reaching a plateau at n=5. Thus, the cap and 6 nt might define the interface providing efficient binding of enzyme and substrate. K(m) values for (7Me)GpppAC(5) and the co-substrate S-adenosyl-L-methionine (AdoMet) were determined (0.39 and 3.26 microM, respectively). As reported for other AdoMet-dependent RNA and DNA MTases, the 2'O-MTase activity of NS5MTase(DV) showed a low turnover of 3.25x10(-4) s(-1). Finally, an inhibition assay was set up and tested on GTP and AdoMet analogues as putative inhibitors of NS5MTase(DV), which confirmed efficient inhibition by the reaction product S-adenosyl-homocysteine (IC(50) 0.34 microM) and sinefungin (IC(50) 0.63 microM), demonstrating that the assay is sufficiently sensitive to conduct inhibitor screening and characterization assays.

Flavivirus NS5 associates with host-cell proteins zonula occludens-1 (ZO-1) and regulating synaptic membrane exocytosis-2 (RIMS2) via an internal PDZ binding mechanism

Dengue virus (DENV) and tick-borne encephalitis virus (TBEV) are flaviviruses, which can cause lethal hemorrhagic fever and encephalitis, respectively. Here, we demonstrate that the TBEV-NS5 and DENV-NS5 proteins use an internal binding mechanism to target human PDZ proteins. TBEV-NS5 has high affinity to regulating synaptic membrane exocytosis-2 (RIMS2) and Scribble, whereas DENV-NS5 binds primarily to the tight junction protein zonula occludens-1 (ZO-1). Targeting of TBEV-NS5 to the plasma membrane is stabilised by ZO-1; however, DENV-NS5 co-localises with ZO-1 in the nucleus. These interactions have potential important roles in the ability of flaviviruses to manipulate cell proliferation, junction permeability and the interferon pathways.

Binding of 2'-amino-2'-deoxycytidine-5'-triphosphate to norovirus polymerase induces rearrangement of the active site

Crystal structures of a genogroup II.4 human norovirus polymerase bound to an RNA primer-template duplex and the substrate analogue 2'-amino-2'-deoxycytidine-5'-triphosphate have been determined to 1.8 A resolution. The alteration of the substrate-binding site that is required to accommodate the 2'-amino group leads to a rearrangement of the polymerase active site and a disruption of the coordination shells of the active-site metal ions. The mode of binding seen for 2'-amino-2'-deoxycytidine-5'-triphosphate suggests a novel molecular mechanism of inhibition that may be exploited for the design of inhibitors targeting viral RNA polymerases.

Architects of assembly: roles of Flaviviridae non-structural proteins in virion morphogenesis

Viruses of the Flaviviridae family, including hepatitis C, dengue and bovine viral diarrhoea, are responsible for considerable morbidity and mortality worldwide. Recent advances in our understanding of virion assembly have uncovered commonalities among distantly related members of this family. We discuss the emerging hypothesis that physical virion components are not alone in forming the infectious particle, but that non-structural proteins are intimately involved in orchestrating morphogenesis. Pinpointing the roles of Flaviviridae proteins in virion production could reveal new avenues for antiviral therapeutics.

Flaviviral methyltransferase/RNA interaction: structural basis for enzyme inhibition

Flaviviruses are the causative agents of severe diseases such as Dengue or Yellow fever. The replicative machinery used by the virus is based on few enzymes including a methyltransferase, located in the N-terminal domain of the NS5 protein. Flaviviral methyltransferases are involved in the last two steps of the mRNA capping process, transferring a methyl group from S-adenosyl-L-methionine onto the N7 position of the cap guanine (guanine-N7 methyltransferase) and the ribose 2'O position of the first nucleotide following the cap guanine (nucleoside-2'O methyltransferase). The RNA capping process is crucial for mRNA stability, protein synthesis and virus replication. Such an essential function makes methyltransferases attractive targets for the design of antiviral drugs. In this context, starting from the crystal structure of Wesselsbron flavivirus methyltransferase, we elaborated a mechanistic model describing protein/RNA interaction during N7 methyl transfer. Next we used an in silico docking procedure to identify commercially available compounds that would display high affinity for the methyltransferase active site. The best candidates selected were tested in vitro to assay their effective inhibition on 2'O and N7 methyltransferase activities on Wesselsbron and Dengue virus (Dv) methyltransferases. The results of such combined computational and experimental screening approach led to the identification of a high-potency inhibitor.

Genomic epidemiology of a dengue virus epidemic in urban Singapore

Dengue is one of the most important emerging diseases of humans, with no preventative vaccines or antiviral cures available at present. Although one-third of the world's population live at risk of infection, little is known about the pattern and dynamics of dengue virus (DENV) within outbreak situations. By exploiting genomic data from an intensively studied major outbreak, we are able to describe the molecular epidemiology of DENV at a uniquely fine-scaled temporal and spatial resolution. Two DENV serotypes (DENV-1 and DENV-3), and multiple component genotypes, spread concurrently and with similar epidemiological and evolutionary profiles during the initial outbreak phase of a major dengue epidemic that took place in Singapore during 2005. Although DENV-1 and DENV-3 differed in viremia and clinical outcome, there was no evidence for adaptive evolution before, during, or after the outbreak, indicating that ecological or immunological rather than virological factors were the key determinants of epidemic dynamics.

Novel Therapeutics Against West Nile Virus

No effective therapy is currently available for clinical treatment of flavivirus infections. Recent advances in the structural and molecular biology of flaviviruses have provided new opportunities for the development of antiviral therapies. This chapter summarizes the current status of West Nile virus (WNV) therapeutics. First, strategies for identifying and characterizing small molecular inhibitors are reviewed. These strategies include structure-based rational design, biochemical enzyme-based screening, and reverse genetic system-based screening. Second, known WNV inhibitors are summarized. Both small and macromolecular inhibitors have been identified to inhibit WNV. The macromolecular inhibitors include WNV antibodies, interferon, and nucleic acid-based agents (i.e., antisense oligomer and siRNA). Since the antibody-based therapy is reviewed elsewhere in this book, this chapter emphasizes the nonantibody macromolecular and small molecular inhibitors. Finally, new potential antiviral targets and issues related to WNV therapeutics are discussed.