Yellow fever virus infection in human hepatocyte cells triggers an imbalance in redox homeostasis with increased reactive oxygen species production, oxidative stress, and decreased antioxidant enzymes

Yellow fever (YF) presents a wide spectrum of severity, with clinical manifestations in humans ranging from febrile and self-limited to fatal cases. Although YF is an old disease for which an effective and safe vaccine exists, little is known about the viral- and host-specific mechanisms that contribute to liver pathology. Several studies have demonstrated that oxidative stress triggered by viral infections contributes to pathogenesis. We evaluated whether yellow fever virus (YFV), when infecting human hepatocytes cells, could trigger an imbalance in redox homeostasis, culminating in oxidative stress. YFV infection resulted in a significant increase in reactive oxygen species (ROS) levels from 2 to 4 days post infection (dpi). When measuring oxidative parameters at 4 dpi, YFV infection caused oxidative damage to lipids, proteins, and DNA, evidenced by an increase in lipid peroxidation/8-isoprostane, carbonyl protein, and 8-hydroxy-2'-deoxyguanosine, respectively. Furthermore, there was a significant reduction in the activity of the antioxidant enzymes superoxide dismutase (SOD) and glutathione peroxidase (GPx), in addition to a reduction in the ratio of reduced to oxidized glutathione (GSH/GSSG), indicating a pro-oxidant environment. However, no changes were observed in the enzymatic activity of the enzyme catalase (CAT) or in the gene expression of SOD isoforms (1/2/3), CAT, or GPx. Therefore, our results show that YFV infection generates an imbalance in redox homeostasis, with the overproduction of ROS and depletion of antioxidant enzymes, which induces oxidative damage to cellular constituents. Moreover, as it has been demonstrated that oxidative stress is a conspicuous event in YFV infection, therapeutic strategies based on antioxidant biopharmaceuticals may be new targets for the treatment of YF.

Specialized cis-Acting RNA Elements Balance Genome Cyclization to Ensure Efficient Replication of Yellow Fever Virus

Genome cyclization is essential for viral RNA (vRNA) replication of the vertebrate-infecting flaviviruses, and yet its regulatory mechanisms are not fully understood. Yellow fever virus (YFV) is a notorious pathogenic flavivirus. Here, we demonstrated that a group of cis-acting RNA elements in YFV balance genome cyclization to govern efficient vRNA replication. It was shown that the downstream of the 5'-cyclization sequence hairpin (DCS-HP) is conserved in the YFV clade and is important for efficient YFV propagation. By using two different replicon systems, we found that the function of the DCS-HP is determined primarily by its secondary structure and, to a lesser extent, by its base-pair composition. By combining in vitro RNA binding and chemical probing assays, we found that the DCS-HP orchestrates the balance of genome cyclization through two different mechanisms, as follows: the DCS-HP assists the correct folding of the 5' end in a linear vRNA to promote genome cyclization, and it also limits the overstabilization of the circular form through a potential crowding effect, which is influenced by the size and shape of the DCS-HP structure. We also provided evidence that an A-rich sequence downstream of the DCS-HP enhances vRNA replication and contributes to the regulation of genome cyclization. Interestingly, diversified regulatory mechanisms of genome cyclization, involving both the downstream of the 5'-cyclization sequence (CS) and the upstream of the 3'-CS elements, were identified among different subgroups of the mosquito-borne flaviviruses. In summary, our work highlighted how YFV precisely controls the balance of genome cyclization to ensure viral replication. IMPORTANCE Yellow fever virus (YFV), the prototype of the Flavivirus genus, can cause devastating yellow fever disease. Although it is preventable by vaccination, there are still tens of thousands of yellow fever cases per year, and no approved antiviral medicine is available. However, the understandings about the regulatory mechanisms of YFV replication are obscure. In this study, by a combination of bioinformatics, reverse genetics, and biochemical approaches, it was shown that the downstream of the 5'-cyclization sequence hairpin (DCS-HP) promotes efficient YFV replication by modulating the conformational balance of viral RNA. Interestingly, we found specialized combinations for the downstream of the 5'-cyclization sequence (CS) and upstream of the 3'-CS elements in different groups of the mosquito-borne flaviviruses. Moreover, possible evolutionary relationships among the various downstream of the 5'-CS elements were implied. This work highlighted the complexity of RNA-based regulatory mechanisms in the flaviviruses and will facilitate the design of RNA structure-targeted antiviral therapies.

Fluorescent tagging the NS1 protein in yellow fever virus: Replication-capable viruses which produce the secretory GFP-NS1 fusion protein

Yellow fever virus, the prototype in the genus Flavivirus, was used to develop viruses in which the nonstructural protein NS1 is genetically fused to GFP in the context of viruses capable of autonomous replication. The GFP-tagging of NS1 at the amino-terminus appeared possible despite the presence of a small and functionally important domain at the NS1's amino-terminus which can be distorted by such fusing. GFP-tagged NS1 viruses were rescued from DNA-launched molecular clones. The initially produced GFP-tagged NS1 virus was capable of only poor replication. Sequential passages of the virus in cell cultures resulted in the appearance of mutations in GFP, NS4A, NS4B and NS5. The mutations which change amino acid sequences of GFP, NS4A and NS5 have the adaptive effect on the replication of GFP-tagged NS1 viruses. The pattern of GFP-fluorescence indicates that the GFP-NS1 fusion protein is produced into the endoplasmic reticulum. The intracellular GFP-NS1 fusion protein colocalizes with dsRNA. The discovered forms of extracellular GFP-NS1 possibly include tetramers and hexamers.

Retinoic Acid Inducible Gene I and Protein Kinase R, but Not Stress Granules, Mediate the Proinflammatory Response to Yellow Fever Virus

Yellow fever virus (YFV) is an RNA virus primarily targeting the liver. Severe YF cases are responsible for hemorrhagic fever, plausibly precipitated by excessive proinflammatory cytokine response. Pathogen recognition receptors (PRRs), such as the cytoplasmic retinoic acid inducible gene I (RIG-I)-like receptors (RLRs), and the viral RNA sensor protein kinase R (PKR), are known to initiate a proinflammatory response upon recognition of viral genomes. Here, we sought to reveal the main determinants responsible for the acute cytokine expression occurring in human hepatocytes following YFV infection. Using a RIG-I-defective human hepatoma cell line, we found that RIG-I largely contributes to cytokine secretion upon YFV infection. In infected RIG-I-proficient hepatoma cells, RIG-I was localized in stress granules. These granules are large aggregates of stalled translation preinitiation complexes known to concentrate RLRs and PKR and are so far recognized as hubs orchestrating RNA virus sensing. Stable knockdown of PKR in hepatoma cells revealed that PKR contributes to both stress granule formation and cytokine induction upon YFV infection. However, stress granule disruption did not affect the cytokine response to YFV infection, as assessed by small interfering RNA (siRNA)-knockdown-mediated inhibition of stress granule assembly. Finally, no viral RNA was detected in stress granules using a fluorescence in situ hybridization approach coupled with immunofluorescence. Our findings suggest that both RIG-I and PKR mediate proinflammatory cytokine induction in YFV-infected hepatocytes, in a stress granule-independent manner. Therefore, by showing the uncoupling of the cytokine response from the stress granule formation, our model challenges the current view in which stress granules are required for the mounting of the acute antiviral response.IMPORTANCE Yellow fever is a mosquito-borne acute hemorrhagic disease caused by yellow fever virus (YFV). The mechanisms responsible for its pathogenesis remain largely unknown, although increased inflammation has been linked to worsened outcome. YFV targets the liver, where it primarily infects hepatocytes. We found that two RNA-sensing proteins, RIG-I and PKR, participate in the induction of proinflammatory mediators in human hepatocytes infected with YFV. We show that YFV infection promotes the formation of cytoplasmic structures, termed stress granules, in a PKR- but not RIG-I-dependent manner. While stress granules were previously postulated to be essential platforms for immune activation, we found that they are not required for the production of proinflammatory mediators upon YFV infection. Collectively, our work uncovered molecular events triggered by the replication of YFV, which could prove instrumental in clarifying the pathogenesis of the disease, with possible repercussions for disease management.

Production of pseudoinfectious yellow fever virus with a two-component genome

Application of genetically modified, deficient-in-replication flaviviruses that are incapable of developing productive, spreading infection is a promising means of designing safe and effective vaccines. Here we describe a two-component genome yellow fever virus (YFV) replication system in which each of the genomes encodes complete sets of nonstructural proteins that form the replication complex but expresses either only capsid or prM/E instead of the entire structural polyprotein. Upon delivery to the same cell, these genomes produce together all of the viral structural proteins, and cells release a combination of virions with both types of genomes packaged into separate particles. In tissue culture, this modified YFV can be further passaged at an escalating scale by using a high multiplicity of infection (MOI). However, at a low MOI, only one of the genomes is delivered into the cells, and infection cannot spread. The replicating prM/E-encoding genome produces extracellular E protein in the form of secreted subviral particles that are known to be an effective immunogen. The presented strategy of developing viruses defective in replication might be applied to other flaviviruses, and these two-component genome viruses can be useful for diagnostic or vaccine applications, including the delivery and expression of heterologous genes. In addition, the achieved separation of the capsid-coding sequence and the cyclization signal in the YFV genome provides a new means for studying the mechanism of the flavivirus packaging process.

Selection of an optimal RNA transfection reagent and comparison to electroporation for the delivery of viral RNA

The initiation of viral RNA replication by the transfection of viral RNA is an integral tool in dissecting the life cycles, susceptibility, and pathogenesis of numerous RNA viruses. Many different transfection methods deliver viral RNA into mammalian cells, including DEAE-dextran and lipid-based reagents, but electroporation is one of the most popular methods. Unfortunately, electroporation suffers from many limitations, including high cell death, serum-free transfection conditions, and requires many cells and relatively large amounts of RNA. To optimize and facilitate the introduction of viral RNAs into mammalian cells, different commercially available RNA transfection reagents were compared for their ability to deliver yellow fever virus (YFV) and hepatitis C virus (HCV) RNA replicons into Huh7 cells. The performance of the commercial transfection reagents was also compared directly to electroporation. When properly optimized, certain reagents were superior to electroporation, with much less cell death, less RNA required and increased transfection efficiency. The factors associated with high efficiency transfection, and the advantage of being able to deliver RNA in the presence of serum are discussed.

Functional requirements of the yellow fever virus capsid protein

Although it is known that the flavivirus capsid protein is essential for genome packaging and formation of infectious particles, the minimal requirements of the dimeric capsid protein for virus assembly/disassembly have not been characterized. By use of a trans-packaging system that involved packaging a yellow fever virus (YFV) replicon into pseudo-infectious particles by supplying the YFV structural proteins using a Sindbis virus helper construct, the functional elements within the YFV capsid protein (YFC) were characterized. Various N- and C-terminal truncations, internal deletions, and point mutations of YFC were analyzed for their ability to package the YFV replicon. Consistent with previous reports on the tick-borne encephalitis virus capsid protein, YFC demonstrates remarkable functional flexibility. Nearly 40 residues of YFC could be removed from the N terminus while the ability to package replicon RNA was retained. Additionally, YFC containing a deletion of approximately 27 residues of the C terminus, including a complete deletion of C-terminal helix 4, was functional. Internal deletions encompassing the internal hydrophobic sequence in YFC were, in general, tolerated to a lesser extent. Site-directed mutagenesis of helix 4 residues predicted to be involved in intermonomeric interactions were also analyzed, and although single mutations did not affect packaging, a YFC with the double mutation of leucine 81 and valine 88 was nonfunctional. The effects of mutations in YFC on the viability of YFV infection were also analyzed, and these results were similar to those obtained using the replicon packaging system, thus underscoring the flexibility of YFC with respect to the requirements for its functioning.

Role of the yellow fever virus structural protein genes in viral dissemination from the Aedes aegypti mosquito midgut

Live-attenuated virus vaccines are key components in controlling arboviral diseases, but they must not disseminate in or be transmitted by mosquito vectors. Although the cycles in which many mosquito-borne viruses are transmitted are well understood, the role of viral genetics in these processes has not been fully elucidated. Yellow fever virus (YFV) is an important arbovirus and the prototype member of the family Flaviviridae. Here, YFV was used in Aedes aegypti mosquitoes as a model to investigate the genetic basis of infection and dissemination in mosquitoes. Viruses derived from infectious clones and chimeric viruses with defined sequential manipulations were used to investigate the influence of specific sequences within the membrane and envelope structural protein genes on dissemination of virus from the mosquito midgut. Substitution of domain III of the envelope protein from a midgut-restricted YFV into a wild-type YFV resulted in a marked decrease in virus dissemination, suggesting an important role for domain III in this process. However, synergism between elements within the flavivirus structural and non-structural protein genes may be necessary for efficient virus escape from the mosquito midgut.

Host-cell interaction of attenuated and wild-type strains of yellow fever virus can be differentiated at early stages of hepatocyte infection

Yellow fever (YF) virus is currently found in tropical Africa and South America, and is responsible for a febrile to severe illness characterized by organ failure and shock. The attenuated YF 17D strain, used in YF vaccine, was derived from the wild-type strain Asibi. Although studies have been done on genetic markers of YF virulence, differentiation of the two strains in terms of host-cell interaction during infection remains elusive. As YF wild-type strains are hepatotropic, we chose a hepatic cell line (HepG2) to study YF virus-host cell interaction. HepG2 cells rapidly produced high titres of infectious viral particles for 17D and Asibi YF strains. However, HepG2 cells were more susceptible to the attenuated 17D virus infection, and only this virus strain induced early apoptosis in these cells. Molecular markers specific for the 17D virus were identified by microarray analysis and confirmed by quantitative RT-PCR analysis. As early as 1h postinfection, three genes, (IEX-1, IRF-1, DEC-1) all implicated in apoptosis pathways, were upregulated. Later in infection (48 h) two other genes (HSP70-1A and 1B), expressed in cases of cellular stress, were highly upregulated in 17D-infected HepG2 cells. The early specific upregulation of these cellular genes in HepG2 cells may be considered markers of the 17D virus. This study on the YF attenuated strain gives a new approach to the analysis of the factors involved in virus attenuation.

Live attenuated yellow fever 17D infects human DCs and allows for presentation of endogenous and recombinant T cell epitopes

The yellow fever (YF) 17D vaccine is one of the most successful live attenuated vaccines available. A single immunization induces both long-lasting neutralizing antibody and YF-specific T cell responses. Surprisingly, the mechanism for this robust immunity has not been addressed. In light of several recent reports suggesting flavivirus interaction with dendritic cells (DCs), we investigated the mechanism of YF17D interaction with DCs and the importance of this interaction in generating T cell immunity. Our results show that YF17D can infect immature and mature human DCs. Viral entry is Ca²⁺ dependent, but it is independent of DC-SIGN as well as multiple integrins expressed on the DC surface. Similar to infection of cell lines, YF infection of immature DCs is cytopathic. Although infection itself does not induce DC maturation in vitro, TNF-α–induced maturation protects DCs from YF-induced cytopathogenicity. Furthermore, we show that DCs infected with YF17D or YF17D carrying a recombinant epitope can process and present antigens for CD8⁺ T cell stimulation. These findings offer insight into the immunologic mechanisms associated with the highly capable YF17D vaccine that may guide effective vaccine design.

Exchanging the yellow fever virus envelope proteins with Modoc virus prM and E proteins results in a chimeric virus that is neuroinvasive in SCID mice

A chimeric flavivirus infectious cDNA was constructed by exchanging the premembrane (prM) and envelope (E) genes of the yellow fever virus vaccine strain 17D (YF17D) with the corresponding genes of Modoc virus (MOD). This latter virus belongs to the cluster of the "not-known vector" flaviviruses and is, unlike YF17D, neuroinvasive in SCID mice. Replication of in vitro-transcribed RNA from this chimeric flavivirus was shown by [(3)H]uridine labeling and RNA analysis. Expression of the MOD prM and E proteins was monitored by radioimmunoprecipitation and revealed that the MOD proteins were correctly and efficiently produced from the chimeric precursor protein. The MOD E protein was shown to be N-linked glycosylated, whereas prM, as predicted from the genome sequence, did not contain N-linked carbohydrates. In Vero cells, the chimeric virus replicated with a similar efficiency as the parental viruses, although it formed smaller plaques than YF17D and MOD. In SCID mice that had been infected intraperitoneally with the chimeric virus, the viral load increased steadily until death. The MOD/YF virus, like MOD from which it had acquired the prM and E structural proteins, but unlike YF, proved neuroinvasive in SCID mice. Animals developed neurological symptoms about 15 days after inoculation and died shortly thereafter. The distribution of MOD/YF RNA in the brain of infected mice was similar to that observed in MOD-infected mice. The observations provide compelling evidence that the determinants of neuroinvasiveness of flaviviruses are entirely located in the envelope proteins prM and E.

Flavivirus capsid is a dimeric alpha-helical protein

The capsid proteins of two flaviviruses, yellow fever virus and dengue virus, were expressed in Escherichia coli and purified to near homogeneity suitable for biochemical characterization and structure determination by nuclear magnetic resonance. The oligomeric properties of the capsid protein in solution were investigated. In the absence of nucleic acid, both proteins were predominantly dimeric in solution. Further analysis of both proteins with far-UV circular dichroism spectroscopy indicated that they were largely alpha-helical. The secondary structure elements of the dengue virus capsid were determined by chemical shift indexing of the sequence-specific backbone resonance assignments. The dengue virus capsid protein devoid of its C-terminal signal sequence was found to be composed of four alpha helices. The longest alpha helix, 20 residues, is located at the C terminus and has an amphipathic character. In contrast, the N terminus was found to be unstructured and could be removed without disrupting the structural integrity of the protein.

Yellow fever virus 17D envelope and NS3 proteins are major targets of the antiviral T cell response in mice

The yellow fever virus 17D vaccine strain is one of the most effective and safe vaccines available. The immune response after immunization is characterized by long-lasting high titers of neutralizing antibodies. Here, we have initiated a characterization of YFV-17D-specific cellular immune responses. This study makes three points. First, we have identified two CD8 T cell epitopes and one CD4 T cell epitope. An H-2Kb-restricted dominant epitope was mapped in the NS3 protein, whereas the viral envelope protein harbored an H-2Db-restricted subdominant epitope and the I-Ab-restricted CD4 T cell epitope. Second, illustrating the concept of immunodomination, we found that after abrogation of the dominant response in H-2Kb knockout mice, the frequencies of T cells recognizing the subdominant Db-restricted epitope increased dramatically. Finally, the H-2Db-restricted epitope lacks the canonical Asn anchor residue at position 5, indicating that epitopes may be missed by strict application of the H-2Db-binding motif. Identification of these T cell epitopes will facilitate studies on the cellular immunity against YFV-based expression or immunization vectors.

Single mutation in the flavivirus envelope protein hinge region increases neurovirulence for mice and monkeys but decreases viscerotropism for monkeys: relevance to development and safety testing of live, attenuated vaccines

A chimeric yellow fever (YF) virus/Japanese encephalitis (JE) virus vaccine (ChimeriVax-JE) was constructed by insertion of the prM-E genes from the attenuated JE virus SA14-14-2 vaccine strain into a full-length cDNA clone of YF 17D virus. Passage in fetal rhesus lung (FRhL) cells led to the emergence of a small-plaque virus containing a single Met-->Lys amino acid mutation at E279, reverting this residue from the SA14-14-2 to the wild-type amino acid. A similar virus was also constructed by site-directed mutagenesis (J. Arroyo, F. Guirakhoo, S. Fenner, Z.-X. Zhang, T. P. Monath, and T. J. Chambers, J. Virol. 75:934-942, 2001). The E279 mutation is located in a beta-sheet in the hinge region of the E protein that is responsible for a pH-dependent conformational change during virus penetration from the endosome into the cytoplasm of the infected cell. In independent transfection-passage studies with FRhL or Vero cells, mutations appeared most frequently in hinge 4 (bounded by amino acids E266 to E284), reflecting genomic instability in this functionally important region. The E279 reversion caused a significant increase in neurovirulence as determined by the 50% lethal dose and survival distribution in suckling mice and by histopathology in rhesus monkeys. Based on sensitivity and comparability of results with those for monkeys, the suckling mouse is an appropriate host for safety testing of flavivirus vaccine candidates for neurotropism. After intracerebral inoculation, the E279 Lys virus was restricted with respect to extraneural replication in monkeys, as viremia and antibody levels (markers of viscerotropism) were significantly reduced compared to those for the E279 Met virus. These results are consistent with the observation that empirically derived vaccines developed by mouse brain passage of dengue and YF viruses have increased neurovirulence for mice but reduced viscerotropism for humans.

Heparan sulfate-mediated binding of infectious dengue virus type 2 and yellow fever virus

Dengue virus type 2 and Yellow fever virus are arthropod-borne flaviviruses causing hemorrhagic fever in humans. Identification of virus receptors is important in understanding flavivirus pathogenesis. The aim of this work was to study the role of cellular heparan sulfate in the adsorption of infectious Yellow fever and Dengue type 2 viruses. Virus attachment was assessed by adsorbing virus to cells, washing unbound virus away, releasing cell-bound virus by freezing/thawing, and then titrating the released infectious virus. Treatment of cells by heparin-lyase, desulfation of cellular heparan sulfate, or treatment of the virus with heparin inhibited cell binding of both viruses. Heparin also inhibited Yellow fever virus infection by 97%. Using infectious virus, the present work shows the importance of heparan sulfate in binding and infection of these two flaviviruses.

Molecular basis for attenuation of neurovirulence of a yellow fever Virus/Japanese encephalitis virus chimera vaccine (ChimeriVax-JE)

A yellow fever virus (YFV)/Japanese encephalitis virus (JEV) chimera in which the structural proteins prM and E of YFV 17D are replaced with those of the JEV SA14-14-2 vaccine strain is under evaluation as a candidate vaccine against Japanese encephalitis. The chimera (YFV/JEV SA14-14-2, or ChimeriVax-JE) is less neurovirulent than is YFV 17D vaccine in mouse and nonhuman primate models (F. Guirakhoo et al., Virology 257:363-372, 1999; T. P. Monath et al., Vaccine 17:1869-1882, 1999). Attenuation depends on the presence of the JEV SA14-14-2 E protein, as shown by the high neurovirulence of an analogous YFV/JEV Nakayama chimera derived from the wild JEV Nakayama strain (T. J. Chambers, A. Nestorowicz, P. W. Mason, and C. M. Rice, J. Virol. 73:3095-3101, 1999). Ten amino acid differences exist between the E proteins of ChimeriVax-JE and the YFV/JEV Nakayama virus, four of which are predicted to be neurovirulence determinants based on various sequence comparisons. To identify residues that are involved in attenuation, a series of intratypic YFV/JEV chimeras containing either single or multiple amino acid substitutions were engineered and tested for mouse neurovirulence. Reversions in at least three distinct clusters were required to restore the neurovirulence typical of the YFV/JEV Nakayama virus. Different combinations of cluster-specific reversions could confer neurovirulence; however, residue 138 of the E protein (E(138)) exhibited a dominant effect. No single amino acid reversion produced a phenotype significantly different from that of the ChimeriVax-JE parent. Together with the known genetic stability of the virus during prolonged cell culture and mouse brain passage, these findings support the candidacy of this experimental vaccine as a novel live-attenuated viral vaccine against Japanese encephalitis.

Yellow fever virus NS2B-NS3 protease: charged-to-alanine mutagenesis and deletion analysis define regions important for protease complex formation and function

Charged-to-alanine substitutions and deletions within the yellow fever virus NS2B-NS3(181) protease were analyzed for effects on protease function. During cell-free translation of NS2B-3(181) polyproteins, mutations at three charge clusters markedly impaired cis cleavage activity: a single N-terminal cluster in the conserved domain of NS2B (residues ELKK(52-55)) and two in NS3 (ED(21-22), and residue H(47)). These mutations inhibited other protease-dependent cleavages of a transiently expressed nonstructural polyprotein, although differential effects occurred. NS2B and NS3(181) proteins harboring these mutations were impaired in their ability to associate for trans cleavage activity. N-terminal deletions in NS3 also implicated residues ED(21-22) in the association with NS2B. Deletions within NS2B revealed that the conserved domain alone provided minimal cofactor activity, with optimal function requiring both flanking hydrophobic regions. NS2B-3(181)- and NS3(181)-green fluorescent protein fusion proteins were used to determine the intracellular distribution of the protease complex. The former localized in membrane-based vesicular structures, whereas the latter localized poorly. The data suggest that NS2B-NS3 complex formation requires charge interactions involving the N-terminus of the conserved domain of NS2B and 22 N-terminal residues of NS3. A role for the putative transmembrane regions of NS2B in targeting of NS3 to intracellular membranes is also suggested.

Interaction of yellow fever virus French neurotropic vaccine strain with monkey brain: characterization of monkey brain membrane receptor escape variants

Binding of yellow fever virus wild-type strains Asibi and French viscerotropic virus and vaccine strains 17D and FNV to monkey brain and monkey liver cell membrane receptor preparations (MRPs) was investigated. Only FNV bound to monkey brain MRPs, while French viscerotropic virus, Asibi, and FNV all bound to monkey liver MRPs. Four monkey brain and two mouse brain MRP escape (MRP(R)) variants of FNV were selected at pH 7.6 and 6.0. Three monkey brain MRP(R) variants selected at pH 7.6 each had only one amino acid substitution in the envelope (E) protein in domain II (E-237, E-260, or E274) and were significantly attenuated in mice following intracerebral inoculation. Two of the variants were tested in monkeys and retained parental neurotropism following intracerebral inoculation at the dose tested. We speculate that this region of domain II is involved in binding of FNV E protein to monkey brain and is, in part, responsible for the enhanced neurotropism of FNV for monkeys. A monkey brain MRP(R) variant selected at pH 6.0 and two mouse brain MRP(R) variants selected at pH 7.6 were less attenuated in mice, and each had an amino acid substitution in the transmembrane region of the E protein (E-457 or E-458).

Mutagenesis of the yellow fever virus NS2B/3 cleavage site: determinants of cleavage site specificity and effects on polyprotein processing and viral replication

The determinants of cleavage site specificity of the yellow fever virus (YF) NS3 proteinase for its 2B/3 cleavage site have been studied by using site-directed mutagenesis. Mutations at residues within the GARR decreases S sequence were tested for effects on cis cleavage of an NS2B-3(181) polyprotein during cell-free translation. At the P1 position, only the conservative substitution R-->K exhibited significant levels of cleavage. Conservative and nonconservative substitutions were tolerated at the P1' and P2 positions, resulting in intermediate levels of cleavage. Substitutions at the P3 and P4 positions had no effects on cleavage efficiency in the cell-free assay. Processing at other dibasic sites was studied by using transient expression of a sig2A-5(356) polyprotein. Cleavage at the 2B/3 site was not required for processing at downstream sites. However, increased accumulation of high-molecular-weight viral polyproteins was generally observed for mutations which reduced cleavage efficiency at the 2B/3 site. Several mutations were also tested for their effects on viral replication. Virus was not recovered from substitutions which blocked or substantially reduced cleavage in the cell-free assay, suggesting that efficient cleavage at the 2B/3 site is required for flavivirus replication.

NS2B-3 proteinase-mediated processing in the yellow fever virus structural region: in vitro and in vivo studies

Several of the cleavages required to generate the mature nonstructural proteins from the flaviviral polyprotein are known to be mediated by a complex consisting of NS2B and a serine proteinase domain located in the N-terminal one-third of NS3. These cleavages typically occur after two basic residues followed by a short side chain residue. Cleavage at a similar dibasic site in the structural region is believed to produce the C terminus of the virion capsid protein. To study this cleavage, we developed a cell-free trans cleavage assay for yellow fever virus (YF)-specific proteolytic activity by using a substrate spanning the C protein dibasic site. Cleavage at the predicted site was observed when the substrate was incubated with detergent-solubilized lysates from YF-infected BHK cells. NS2B and the NS3 proteinase domain were the only YF-specific proteins required for this cleavage. Cell fractionation studies demonstrated that the YF-specific proteolytic activity was membrane associated and that activity could be detected only after detergent solubilization. Previous cell-free studies led to a hypothesis that processing in the C-prM region involves (i) translation of C followed by translocation and core glycosylation of prM by using an internal signal sequence, (ii) signalase cleavage to produce a membrane-anchored form of the C protein (anchC) and the N terminus of prM, and (iii) NS2B-3-mediated cleavage at the anchC dibasic site to produce the C terminus of the virion C protein. However, the results of in vivo transient-expression studies do not support this temporal cleavage order. Rather, expression of a YF polyprotein extending from C through the N-terminal one-third of NS3 revealed that C-prM processing, but not translocation, was dependent on an active NS2B-3 proteinase. This suggests that signalase-mediated cleavage in the lumen of the endoplasmic reticulum may be dependent on prior cleavage at the anchC dibasic site. Possible pathways for processing in the C-prM region are outlined and discussed.

Mutagenesis of the yellow fever virus NS2A/2B cleavage site: effects on proteolytic processing, viral replication, and evidence for alternative processing of the NS2A protein

The yellow fever virus NS2B-3 proteinase mediates cleavages within the nonstructural region at a consensus sequence defined by G/ARR decreases S/G and also at an alternative site within the NS4A region. To determine the importance of specific residues within the consensus sequence for cleavage at the 2A/2B site, amino acid substitutions were introduced at each of the P4, P3, P2, P1, and P1' positions and the effects on proteolytic processing of a sig2A-5(356) polyprotein were examined using a vaccinia virus-T7 transient expression system. At the P1 and P1' positions, only the conservative substitutions P1:R-->K and P1':S-->G allowed efficient cleavage, suggesting that basic and small aliphatic amino acids are preferred at the P1 and P1' positions, respectively. At the P2 position, a preference for a basic amino acid was observed. In contrast, the P3 and P4 positions tolerated nonconservative substitutions and at P4 both enhancement and reduction in cleavage efficiency was observed. Evidence for cleavage at an alternative site within NS2A, defined by the sequence QK decreases T (NS2A residues 189-191) was obtained. Cleavage at this site, designated at NS2A alpha, is dependent upon an active NS2B-3 proteinase. To examine the effects of reduced cleavage efficiency at the 2A/2B and NS2A alpha cleavage sites on viral replication, mutations at each or both of these sites were incorporated into a full-length YF-17D cDNA template. RNA transcripts containing mutations which abolish cleavage were noninfectious whereas virus was recovered from several clones with mutations allowing partial cleavage at 2A/2B. However, some of these mutants exhibited a small plaque phenotype as well as reductions in RNA-specific infectivity and virus yield.

Mutagenesis of the yellow fever virus NS2B protein: effects on proteolytic processing, NS2B-NS3 complex formation, and viral replication

To study the role of specific regions of the yellow fever virus NS2B protein in proteolytic processing and association with the NS3 proteinase domain, a series of mutations were created in the hydrophobic regions and in a central conserved hydrophilic region proposed as a domain important for NS2B function. The effects of these mutations on cis cleavage at the 2B/3 cleavage site and on processing at other consensus cleavage sites for the NS3 proteinase in the nonstructural region were then characterized by cell-free translation and transient expression in BHK cells. Association between NS2B and the NS3 proteinase domain and the effects of mutations on complex formation were investigated by nondenaturing immunoprecipitation of these proteins expressed in infected cells, by cell-free translation, or by recombinant vaccinia viruses. Mutations within the hydrophobic regions had subtle effects on proteolytic processing, whereas mutations within the conserved domain dramatically reduced cleavage efficiency or abolished all cleavages. The conserved domain of NS2B is also implicated in formation of an NS2B-NS3 complex on the basis of the ability of mutations in this region to eliminate both association of these two proteins and trans-cleavage activity. In addition, mutations which either eliminated proteolytic processing or had no apparent effect on processing were found to abolish recovery of infectious virus following RNA transfection. These results suggest that the conserved region of NS2B is a domain essential for the function of the NS3 proteinase. Hydrophobic regions of NS2B whose structural integrity may not be essential for proteolytic processing may have additional functions during viral replication.

Cleavage at a novel site in the NS4A region by the yellow fever virus NS2B-3 proteinase is a prerequisite for processing at the downstream 4A/4B signalase site

Flavivirus proteins are produced by co- and posttranslational proteolytic processing of a large polyprotein by both host- and virus-encoded proteinases. The viral serine proteinase, which consists of NS2B and NS3, is responsible for cleavage of at least four dibasic sites (2A/2B, 2B/3, 3/4A, and 4B/5) in the nonstructural region. Since the amino acid sequence preceding NS4B shares characteristics with signal peptides used for translocation of nascent polypeptides into the lumen of the endoplasmic reticulum, it has been proposed that cleavage at the 4A/4B site is mediated by a cellular signal peptidase. In this report, cell-free translation and in vivo transient expression assays were used to study processing in the NS4 region of the yellow fever virus polyprotein. With a construct which contained NS4B preceded by 17 residues constituting the putative signal peptide (sig4B), membrane-dependent cleavage at the 4A/4B site was demonstrated in vitro. Surprisingly, processing of NS4A-4B was not observed in cell-free translation studies, and in vivo expression of several yellow fever virus polyproteins revealed that the 4A/4B cleavage occurred only during coexpression of NS2B and the proteinase domain of NS3. Examination of mutant derivatives of the NS3 proteinase domain demonstrated that cleavage at the 4A/4B site correlated with expression of an active NS2B-3 proteinase. From these results, we propose a model in which the signalase cleavage generating the N terminus of NS4B requires a prior NS2B-3 proteinase-mediated cleavage at a novel site (called the 4A/2K site) which is conserved among flaviviruses and located 23 residues upstream of the signalase site. In support of this model, mutations at the 4A/4B signalase site did not eliminate processing in the NS4 region. In contrast, substitutions at the 4A/2K site, which were engineered to block NS2B-3 proteinase-mediated cleavage, eliminated signalase cleavage at the 4A/4B site. In addition, the size of the 3(502)-4A product generated by trans processing of a truncated polyprotein, 3(502)-5(356), was consistent with cleavage at the 4A/2K site rather than at the downstream 4A/4B signalase site.

Mutagenesis of conserved residues at the yellow fever virus 3/4A and 4B/5 dibasic cleavage sites: effects on cleavage efficiency and polyprotein processing

Flavivirus proteins are produced by co- and post-translational proteolytic processing of a large polyprotein using both host- and virus-encoded enzymes. The flavivirus serine proteinase, which consists of NS2B and NS3, is responsible for cleavages of at least four dibasic sites in the nonstructural region. In this study, a number of substitutions for the conserved amino acids flanking the 3/4A and 4B/5 dibasic cleavage sites [Arg(P2)-Arg(P1) decreases Gly(P1')] were examined for their effects on yellow fever virus (YF) polyprotein processing. The substrate for these studies was a truncated YF polyprotein, called sig2A-5(356), which consists of a signal sequence fused to NS2A and extending through the first 356 amino acids of NS5. At the P1' position (Gly) of the 4B/5 site, only Ser and Ala were allowed while six other substitutions abolished cleavage. Substitutions of the 4B/5 P1 Arg residue with Lys, Gln, Asn, or His were tolerated while replacement with Glu eliminated cleavage. The 4B/5 P2 position (Arg) was found to be tolerant of substitutions with polar or hydrophobic residues which allowed varying degrees of partial cleavage. Previous studies have shown that cleavage at the 3/4A site is incomplete in YF-infected cells and that the cleavage efficiency at this site is significantly less for the sig2A-5(356) polyprotein. Replacement of the 3/4A P1 Arg residue with noncharged polar or hydrophobic residues reduced the cleavage efficiency, whereas substitutions with Glu or Pro abolished cleavage. Studies with polyproteins containing one or both of the 3/4A and 4B/5 cleavage sites blocked indicate that there is not an obligatory processing order for cleavages generating the N termini of YF NS4A, NS4B, and NS5.

Heterogeneity in envelope protein sequence and N-linked glycosylation among yellow fever virus vaccine strains

We have compared the deduced envelope (E) protein sequences of two biologically well-characterized yellow fever (YF) virus vaccine strains. The 17DD strain has been produced in Brazil for more than 50 years and used to successfully vaccinate millions of people worldwide. The 17D-213 is a candidate vaccine strain produced in tissue culture which has previously passed the monkey neurovirulence assay for testing human YF vaccines. Nucleotide sequence analysis of polymerase chain reaction-amplified cDNA revealed a number of mutations which were strain- and substrain-specific. A major difference of 17DD and 17D-213 as compared to 17D-204 and Asibi was the existence of a potential N-linked glycosylation site located at amino acid residues 153 and 151 of 17DD and 17D-213, respectively. These acceptor sites are apparently utilized for the addition of high-mannose carbohydrate chains as shown by endoglycosidase analyses of immunoprecipitated E proteins. Glycosylated E protein is also used to assemble YF vaccine virions. This work and eventual complete nucleotide sequence analysis of both vaccine strains should help to define possible changes involved in YF virus attenuation and allow their biological importance to be determined using a recently developed system for generating YF virus from cDNA. In addition, these data provide an estimate on the extent of genetic variability among YF 17D seeds and vaccines.

Processing of the yellow fever virus nonstructural polyprotein: a catalytically active NS3 proteinase domain and NS2B are required for cleavages at dibasic sites

The vaccinia virus-T7 transient expression system was used to further examine the role of the NS3 proteinase in processing of the yellow fever (YF) virus nonstructural polyprotein in BHK cells. YF virus-specific polyproteins and cleavage products were identified by immunoprecipitation with region-specific antisera, by size, and by comparison with authentic YF virus polypeptides. A YF virus polyprotein initiating with a signal sequence derived from the E protein fused to the N terminus of NS2A and extending through the N-terminal 356 amino acids of NS5 exhibited processing at the 2A-2B, 2B-3, 3-4A, 4A-4B, and 4B-5 cleavage sites. Similar results were obtained with polyproteins whose N termini began within NS2A (position 110) or with NS2B. When the NS3 proteinase domain was inactivated by replacing the proposed catalytic Ser-138 with Ala, processing at all sites was abolished. The results suggest that an active NS3 proteinase domain is necessary for cleavage at the diabasic nonstructural cleavage sites and that cleavage at the proposed 4A-4B signalase site requires prior cleavage at the 4B-5 site. Cleavages were not observed with a polyprotein whose N terminus began with NS3, but cleavage at the 4B-5 site could be restored by supplying the the NS2B protein in trans. Several experimental results suggested that trans cleavage at the 4B-5 site requires association of NS2B and the NS3 proteinase domain. Coexpression of different proteinases and catalytically inactive polyprotein substrates revealed that trans cleavage at the 2B-3 and 4B-5 sites was relatively efficient when compared with trans cleavage at the 2A-2B and 3-4A sites.

Glycosylation and secretion of yellow fever virus nonstructural protein NS1

The flavivirus genome codes for structural and nonstructural proteins which are produced from a common polyprotein precursor by proteolytic processing. The nonstructural protein NS1 is hypothesized to be involved in virus assembly and maturation as well as in protective immunity. This paper describes the synthesis of several forms of yellow fever (YF) virus NS1 protein during virus cultivation in vitro. These include cell-associated and secreted NS1 forms, the major difference among these being their N-linked glycosylation status. High-mannose and complex (or hybrid)-type moieties were identified on YF NS1 by analysis with endoglycosidases of known specificity. These studies are the basis for a systematic approach to determining the role of NS1 in the virus cycle and possibly in pathogenesis.

Production of yellow fever virus proteins in infected cells: identification of discrete polyprotein species and analysis of cleavage kinetics using region-specific polyclonal antisera

Flavivirus proteins are produced by translation of a single long open reading frame and a complex series of cotranslational and post-translational proteolytic cleavages. To study these processing events in yellow fever virus (YF)-infected cells, polyclonal antisera recognizing C, prM, E, NS1, NS2B, NS3, NS4B, and NS5 were generated using peptide and fusion protein immunogens. Evidence suggests that production of the structural protein precursors involves rapid cotranslational processing consistent with signalase cleavages. The synthesis of the NS1 glycoprotein involves cleavage of polyprotein precursors (t1/2 approximately 10 minutes) which probably contain portions of the NS2A gene product. Endoglycosidase F treatment or labeling in the presence of tunicamycin suggests that YF prM and NS1 each have two N-linked oligosaccharides. NS2B is produced without any identifiable precursors or associated polyprotein species. Processing of the NS3-4-5 region is complex and occurs rapidly. A series of polyproteins can be detected whose molecular weights correlate with the cleavage sites defined by available N-terminal amino acid sequence data. However, convincing precursor-product relationships between these polyproteins and the mature NS3 and NS5 proteins could not be demonstrated. In contrast, NS4B appears to be produced by cleavage of a discrete precursor believed to be NS4AB. N-terminal sequence data for the putative NS4AB product has tentatively defined the NS3-4A cleavage site. A scheme for in vivo processing of the YF polyprotein is presented and discussed.

The 15 amino acid residues preceding the amino terminus of the envelope protein in the yellow fever virus polyprotein precursor act as a signal peptide

The 15 amino acids which precede the sequence of the envelope (E) protein in the yellow fever virus (YFV) polyprotein precursor have been proposed to function as a signal peptide for the E protein (P. Desprès A. Cahour, C. Wychowski, M. Girard and M. Bouloy; Ann. Inst. Pasteur/Virol., 139, 59-67, 1988). To confirm this hypothesis, recombinant SV40 genomes were constructed in which the sequence of the E protein, or that of the poliovirus VP0 capsid polypeptide were placed immediately downstream of and in frame with the sequence of the putative signal peptide, under the control of the late SV40 promoter. The E protein expressed by the hybrid virus SV-E was recognized by two neutralizing monoclonal antibodies directed against the YFV envelope protein. In this construct, the E protein was deleted of its C-terminal transmembrane zone. Therefore, as expected, the protein appeared to be efficiently transported along the exocytic pathway and excreted into the cell culture medium. In addition, when the putative signal peptide was fused in frame with poliovirus polypeptide VP0, the expressed chimeric polypeptide was targeted to the endoplasmic reticulum where it underwent glycosylation.

Processing of yellow fever virus polyprotein: role of cellular proteases in maturation of the structural proteins

The yellow fever virus (YFV) cDNA segment coding for the part of the precursor polyprotein generating the structural proteins C (capsid), prM (precursor to the membrane protein M), and E (envelope) was expressed in vitro by using the T7 promoter-polymerase transcription system coupled to translation in rabbit reticulocyte lysates. A polypeptide of the expected molecular weight was observed to accumulate in the assay and was processed into proteins C, prM, and E only when dog pancreas microsomal membranes were added to the translation system. Proteins prM and E were translocated inside the endoplasmic reticulum, where prM underwent glycosylation. Regions essential for translocation of these proteins were localized to the 18- and 15-amino-acid C-terminal hydrophobic regions of proteins C and prM, respectively. Translocation of protein prM appeared to be less efficient than that of protein E. Maturation of these proteins followed different kinetics, indicating that the prM signal is probably cleaved off more slowly. A polypeptide composed of proteins C and prM, similar to the NVx polypeptide described in yellow fever virus-infected cells, was also produced in the in vitro system in the presence of membranes. No mature protein M was detected, suggesting that the cleavage of prM to M is a late processing event mediated by a protease different from endoplasmic reticulum signalases.

Immunoblotting reveals differences in the accumulation of envelope protein by wild-type and vaccine strains of yellow fever virus

Seventeen strains of yellow fever virus were compared by immunoblotting using polyclonal and monoclonal antibodies. Strains originating in South America were readily distinguishable from African strains on the basis of differences in the envelope protein. The 17D vaccine strain and strains derived from it differed radically from the parent Asibi and other wild-type strains in that cells infected with 17D did not accumulate intact envelope protein. We suggest that failure to accumulate the major viral surface protein is due to its increased susceptibility to breakdown and that this property may be a contributing factor in the attenuation of the vaccine strains.