Nucleolar protein B23 interacts with Japanese encephalitis virus core protein and participates in viral replication

Japanese encephalitis virus (JEV) core protein is detected not only in the cytoplasm but also in the nucleoli of infected cells. We previously showed that a mutant JEV lacking the nucleolar localization of the core protein impaired viral replication in mammalian cells. In this study, we identified a nucleolar phosphoprotein B23 as a protein binding with the core protein of JEV but not with that of dengue virus. The region binding with JEV core protein was mapped to amino acid residues 38 to 77 of B23. Upon JEV infection, some fraction of B23 was translocated from the nucleoli to the cytoplasm, and cytoplasmic B23 was colocalized with the core protein of wild-type JEV but not with that of the mutant JEV. Furthermore, overexpression of dominant negatives of B23 reduced JEV replication. These results suggest that B23 plays an important role in the intracellular localization of the core protein and replication of JEV.     

Processing of capsid protein by cathepsin L plays a crucial role in replication of Japanese encephalitis virus in neural and macrophage cells

The flavivirus capsid protein not only is a component of nucleocapsids but also plays a role in viral replication. In this study, we found a small capsid protein in cells infected with Japanese encephalitis virus (JEV) but not in the viral particles. The small capsid protein was shown to be generated by processing with host cysteine protease cathepsin L. An in vitro cleavage assay revealed that cathepsin L cleaves the capsid protein between amino acid residues Lys(18) and Arg(19), which are well conserved among the mosquito-borne flaviviruses. A mutant JEV resistant to the cleavage of the capsid protein by cathepsin L was generated from an infectious cDNA clone of JEV by introducing a substitution in the cleavage site. The mutant JEV exhibited growth kinetics similar to those of the wild-type JEV in monkey (Vero), mosquito (C6/36), and porcine (PK15) cell lines, whereas replication of the mutant JEV in mouse macrophage (RAW264.7) and neuroblastoma (N18) cells was impaired. Furthermore, the neurovirulence and neuroinvasiveness of the mutant JEV to mice were lower than those of the wild-type JEV. These results suggest that the processing of the JEV capsid protein by cathepsin L plays a crucial role in the replication of JEV in neural and macrophage cells, which leads to the pathogenesis of JEV infection.     

Recombinant Measles AIK-C Vaccine Strain Expressing the prM-E Antigen of Japanese Encephalitis Virus

An inactivated Japanese encephalitis virus (JEV) vaccine, which induces neutralizing antibodies, has been used for many years in Japan. In the present study, the JEV prM-E protein gene was cloned, inserted at the P/M junction of measles AIK-C cDNA, and an infectious virus was recovered. The JEV E protein was expressed in B95a cells infected with the recombinant virus. Cotton rats were inoculated with recombinant virus. Measles PA antibodies were detected three weeks after immunization. Neutralizing antibodies against JEV developed one week after inoculation, and EIA antibodies were detected three weeks after immunization. The measles AIK-C-based recombinant virus simultaneously induced measles and JEV immune responses, and may be a candidate for infant vaccines. Therefore, the present strategy of recombinant viruses based on a measles vaccine vector would be applicable to the platform for vaccine development.     

Stationary and microcarrier cell culture processes for propagating Japanese encephalitis virus

Inactivated mouse-brain-derived vaccines for Japanese encephalitis virus (JEV) have been used for many years. Recently, attempts have been made to employ cultured Vero cells to replace mouse brain tissues for developing cell-culture-derived vaccines that will be more suitable for worldwide usage. In this study, JEV replication processes in Vero and BHK cells and between stationary and microcarrier culture systems were investigated. Our results demonstrated that a stationary Vero cell culture system produced higher viral titers of JEV, including the Beijin-1 vaccine strain and the attenuated strain CH2195LA, than microcarrier culture did. BHK cells showed less significant differences in their replication kinetics between stationary and microcarrier cultures. Reducing serum concentration during infection led to an overall decrease of JEV production in Vero cells but an increase in BHK cells. By establishing a complete serum-free Vero cell culture, the microcarrier system resulted in a more than 4-log lowered yield compared to that of the stationary culture for JEV production. Thus, the stationary culture is the most efficient system for JEV production from cultured Vero cells.     

Heterogeneous nuclear ribonucleoprotein A2 participates in the replication of Japanese encephalitis virus through an interaction with viral proteins and RNA

Japanese encephalitis virus (JEV) is a mosquito-borne flavivirus that is kept in a zoonotic transmission cycle between pigs and mosquitoes. JEV causes infection of the central nervous system with a high mortality rate in dead-end hosts, including humans. Many studies have suggested that the flavivirus core protein is not only a component of nucleocapsids but also an important pathogenic determinant. In this study, we identified heterogeneous nuclear ribonucleoprotein A2 (hnRNP A2) as a binding partner of the JEV core protein by pulldown purification and mass spectrometry. Reciprocal coimmunoprecipitation analyses in transfected and infected cells confirmed a specific interaction between the JEV core protein and hnRNP A2. Expression of the JEV core protein induced cytoplasmic retention of hnRNP A2 in JEV subgenomic replicon cells. Small interfering RNA (siRNA)-mediated knockdown of hnRNP A2 resulted in a 90% reduction of viral RNA replication in cells infected with JEV, and the reduction was cancelled by the expression of an siRNA-resistant hnRNP A2 mutant. In addition to the core protein, hnRNP A2 also associated with JEV nonstructural protein 5, which has both methyltransferase and RNA-dependent RNA polymerase activities, and with the 5'-untranslated region of the negative-sense JEV RNA. During one-step growth, synthesis of both positive- and negative-strand JEV RNAs was delayed by the knockdown of hnRNP A2. These results suggest that hnRNP A2 plays an important role in the replication of JEV RNA through the interaction with viral proteins and RNA.     

Japanese Encephalitis Virus Core Protein Inhibits Stress Granule Formation through an Interaction with Caprin-1 and Facilitates Viral Propagation

Stress granules (SGs) are cytoplasmic foci composed of stalled translation preinitiation complexes induced by environmental stress stimuli, including viral infection. Since viral propagation completely depends on the host translational machinery, many viruses have evolved to circumvent the induction of SGs or co-opt SG components. In this study, we found that expression of Japanese encephalitis virus (JEV) core protein inhibits SG formation. Caprin-1 was identified as a binding partner of the core protein by an affinity capture mass spectrometry analysis. Alanine scanning mutagenesis revealed that Lys⁹⁷ and Arg⁹⁸ in the α-helix of the JEV core protein play a crucial role in the interaction with Caprin-1. In cells infected with a mutant JEV in which Lys⁹⁷ and Arg⁹⁸ were replaced with alanines in the core protein, the inhibition of SG formation was abrogated, and viral propagation was impaired. Furthermore, the mutant JEV exhibited attenuated virulence in mice. These results suggest that the JEV core protein circumvents translational shutoff by inhibiting SG formation through an interaction with Caprin-1 and facilitates viral propagation in vitro and in vivo.     

Cytoplasmic Translocation of Polypyrimidine Tract-Binding Protein and Its Binding to Viral RNA during Japanese Encephalitis Virus Infection Inhibits Virus Replication

Japanese encephalitis virus (JEV) has a single-stranded, positive-sense RNA genome containing a single open reading frame flanked by the 5′- and 3′-non-coding regions (NCRs). The virus genome replicates via a negative-sense RNA intermediate. The NCRs and their complementary sequences in the negative-sense RNA are the sites for assembly of the RNA replicase complex thereby regulating the RNA synthesis and virus replication. In this study, we show that the 55-kDa polypyrimidine tract-binding protein (PTB) interacts in vitro with both the 5′-NCR of the positive-sense genomic RNA - 5NCR(+), and its complementary sequence in the negative-sense replication intermediate RNA - 3NCR(-). The interaction of viral RNA with PTB was validated in infected cells by JEV RNA co-immunoprecipitation and JEV RNA-PTB colocalization experiments. Interestingly, we observed phosphorylation-coupled translocation of nuclear PTB to cytoplasmic foci that co-localized with JEV RNA early during JEV infection. Our studies employing the PTB silencing and over-expression in cultured cells established an inhibitory role of PTB in JEV replication. Using RNA-protein binding assay we show that PTB competitively inhibits association of JEV 3NCR(-) RNA with viral RNA-dependent RNA polymerase (NS5 protein), an event required for the synthesis of the plus-sense genomic RNA. cAMP is known to promote the Protein kinase A (PKA)-mediated PTB phosphorylation. We show that cells treated with a cAMP analogue had an enhanced level of phosphorylated PTB in the cytoplasm and a significantly suppressed JEV replication. Data presented here show a novel, cAMP-induced, PTB-mediated, innate host response that could effectively suppress JEV replication in mammalian cells.     

Reproduction of Japanese encephalitis virus in human glioma cells, 118MGC: inhibitory effect of host factor(s)

Japanese encephalitis viruses (JEV) were well propagated in human glioma cells, 118MGC until the first 24 hrs after virus infection. However, after 24 hrs, virus growth rate was quickly reduced. This unusual pattern of virus growth was different from the cases in others cells, e.g. IMR-32, Vero and C6/36 cells. The fact that actinomycin-D retained the high yields of JEV in 118MGC cells suggests that some suppressing factors against JEV replication are produced in MGC cells. Interestingly, culture fluids of 118MGC cells indicated inhibitory effect to JEV reproduction, but other culture fluids from several cell lines had no effect. This inhibitory effect of the MGC-culture fluids was lost by heat-treatment at 60 C. In addition, the infectivity of JEV was rapidly decreased by the incubation with MGC-culture fluids. These findings suggest that 118MGC cells produce and secret some inhibitory factors against JEV replication.     

Inhibitory effect of RNAi on Japanese encephalitis virus replication in vitro and in vivo

Flaviviruses include many insect-mediated small viruses and still cause serious problems in the world. In humans, JEV can cause acute meningioencephalomyelitis, resulting in fatality rates of 5 to 40%. RNA-interference (RNAi) as an antiviral mechanism was originally discovered in plants and then found in the specific suppression of gene expression of other organisms such as Caenorhabditis elegans, Drosophila and vertebrates. As JEV is an RNA virus, RNAi could be a reasonable approach for therapeutic purposes to use against Japanese encephalitis. In this study, we examined the effect of RNAi on JEV replication. Viral reproduction in Vero cells was decreased to 7.2% and 39.0% of control by the transfection of small interference RNAs, JCR and JN3R at 250 n M, respectively. Under the transfection of 5 microg/ml pJRi which produces stem-loop RNAi, viral reproduction was decreased to about 10% of control. Western blot analysis indicated that RNAi inhibited the translation level. We used pJRi in the animal experiment. After the inoculation of viruses at 5 x 10(3) PFU, pJRi at 1.0 and 5.0 microg/g was injected into mice i.p. JEV-infected control mice (n=5) died within 15 days. pJRi (1.0 or 5.0 microg/g)-medicated mice survived 40 or 80% at 15 days. The data clearly indicate that pJRi has highly potent inhibitory activity against JEV replication in vivo. The results in vivo and in vitro provide evidence that JEV replication was efficiently inhibited by RNAi and RNAis could be used as an antiviral drug against JEV infection.     

Reovirus sigmaNS protein is required for nucleation of viral assembly complexes and formation of viral inclusions

Progeny virions of mammalian reoviruses are assembled in the cytoplasm of infected cells at discrete sites termed viral inclusions. Studies of temperature-sensitive (ts) mutant viruses indicate that nonstructural protein sigmaNS and core protein mu2 are required for synthesis of double-stranded (ds) RNA, a process that occurs at sites of viral assembly. We used confocal immunofluorescence microscopy and ts mutant reoviruses to define the roles of sigmaNS and mu2 in viral inclusion formation. In cells infected with wild-type (wt) reovirus, sigmaNS and mu2 colocalize to large, perinuclear structures that correspond to viral inclusions. In cells infected at a nonpermissive temperature with sigmaNS-mutant virus tsE320, sigmaNS is distributed diffusely in the cytoplasm and mu2 is contained in small, punctate foci that do not resemble viral inclusions. In cells infected at a nonpermissive temperature with mu2-mutant virus tsH11.2, mu2 is distributed diffusely in the cytoplasm and the nucleus. However, sigmaNS localizes to discrete structures in the cytoplasm that contain other viral proteins and are morphologically indistinguishable from viral inclusions seen in cells infected with wt reovirus. Examination of cells infected with wt reovirus over a time course demonstrates that sigmaNS precedes mu2 in localization to viral inclusions. These findings suggest that viral RNA-protein complexes containing sigmaNS nucleate sites of viral replication to which other viral proteins, including mu2, are recruited to commence dsRNA synthesis.     

Impaired Japanese encephalitis virus replication in p62/SQSTM1 deficient mouse embryonic fibroblasts

The role of the autophagy adaptor protein p62/SQSTM1 in Japanese encephalitis virus (JEV) replication in mouse embryonic fibroblasts (MEFs) was investigated. Amounts of JEV RNA and E protein were significantly smaller in p62‐deficient cells than wild‐type cells at 24 hr post‐infection (p.i.). JEV RNA quantitation and viral plaque assays showed significant reductions in viral titers in p62‐deficient cell culture fluid. Our results indicate that JEV replication is impaired in p62‐deficient MEFs, suggesting that p62 positively regulates JEV replication in host cells.     

Interaction of calpactin light chain (S100A10/p11) and a viral NS protein is essential for intracellular trafficking of nonenveloped bluetongue virus

Bluetongue virus (BTV), a member of the Reoviridae family, is an insect-borne animal pathogen. Virus release from infected cells is predominantly by cell lysis, but some BTV particles are also released from the plasma membrane. The nonstructural protein NS3 has been implicated in this process. Using alternate initiator methionine residues, NS3 is expressed as a full-length protein and as a truncated variant that lacks the initial 13 residues, which, by yeast-two hybrid analyses, have been shown to interact with a cellular trafficking protein S100A10/p11. To understand the physiological significance of this interaction in virus-infected cells, we have used reverse genetics to investigate the roles of NS3 and NS3A in virus replication and localization in both mammalian and insect vector-derived cells. A virus expressing NS3 but not NS3A was able to propagate in and release from mammalian cells efficiently. However, growth of a mutant virus expressing only NS3A was severely attenuated, although protein expression, replication, double-stranded RNA (dsRNA) synthesis, and particle assembly in the cytoplasm were observed. Two of three single-amino-acid substitutions in the N-terminal 13 residues of NS3 showed phenotypically similar effects. Pulldown assay and confocal microscopy demonstrated a lack of interaction between NS3 and S100A10/p11 in mutants with poor replication. The role of NS3/NS3A was also assessed in insect cells where virus grew, albeit with a reduced titer. Notably, however, while wild-type particles were found within cytoplasmic vesicles in insect cells, mutant viruses were scattered throughout the cytoplasm and not confined to vesicles. These results provide support for a role for the extreme amino terminus of NS3 in the late stages of virus growth in mammalian cells, plausibly in egress. However, both NS3 and NS3A were required for efficient BTV growth in insect cells.     

Glyceraldehyde-3-phosphate dehydrogenase (GAPDH) interaction with 3' ends of Japanese encephalitis virus RNA and colocalization with the viral NS5 protein

Replication of the Japanese encephalitis virus (JEV) genome depends on host factors for successfully completing their life cycles; to do this, host factors have been recruited and/or relocated to the site of viral replication. Glyceraldehyde-3-phosphate dehydrogenase (GAPDH), a cellular metabolic protein, was found to colocalize with viral RNA-dependent RNA polymerase (NS5) in JEV-infected cells. Subcellular fractionation further indicated that GAPDH remained relatively constant in the cytosol, while increasing at 12 to 24 hours postinfection (hpi) and decreasing at 36 hpi in the nuclear fraction of infected cells. In contrast, the redistribution patterns of GAPDH were not observed in the uninfected cells. Co-immunoprecipitation of GAPDH and JEV NS5 protein revealed no direct protein-protein interaction; instead, GAPDH binds to the 3'' termini of plus- and minus-strand RNAs of JEV by electrophoretic mobility shift assays. Accordingly, GAPDH binds to the minus strand more efficiently than to the plus strand of JEV RNAs. This study highlights the findings that infection of JEV changes subcellular localization of GAPDH suggesting that this metabolic enzyme may play a role in JEV replication.     

Mosquito cells infected with Japanese encephalitis virus release slowly-sedimenting hemagglutinin particles in association with intracellular formation of smooth membrane structures

Arthropod-borne flaviviruses can grow in both arthropod and mammalian cells. Virion morphogenesis, though well studied in mammalian cells, is still unclear in arthropod cells. Here, we compared a mosquito cell line C6/36 and a mammalian cell line Vero in extracellular virus particles and intracellular ultrastructures triggered by infection with Japanese encephalitis virus (JEV). Sedimentation analyses of virion and slowly-sedimenting hemagglutinin (SHA) particles released by infection with the Nakayama strain revealed that C6/36 cells produced higher envelope (E) antigen levels in the SHA than the virion fraction in contrast to Vero cells that showed the opposite pattern. Specific infectivities per ng of E were similar in both cells, whereas specific hemagglutinating activities in the SHA fraction were lower in C6/36 than Vero cells. The precursor membrane protein was less efficiently cleaved to the membrane protein in SHA particles released from C6/36 than Vero cells. Ultrastructural studies showed more remarkable production of smooth membrane structures (SMSs) in C6/36 than in Vero cells. The differences in sedimentation patterns of extracellular virus particles between Nakayama-infected C6/36 and Vero cells were consistently observed in 5 other strains (Beijing P1, Beijing P3, JaTH-160, KE-093 and JaGAr-O1), except for KE-093-infected C6/36 cells which exhibited the Vero-type sedimentation profile under conditions of open cultivation. By electron microscopy, the production of SMSs from KE-093-infected C6/36 cells under open conditions was markedly less than that under closed conditions where the cells exhibited the C6/36-type sedimentation profile. Thus, intracellular SMS formations were associated with extracellular SHA production in JEV-infected mosquito cells.     

The UL20 gene of herpes simplex virus 1 encodes a function necessary for viral egress.

A recombinant virus from which the start codon and 53% of the UL20 open reading frame had been deleted was constructed and characterized. We report the following: (i) The UL20- mutant formed small plaques in 143 tk- cells but failed to form plaques in Vero cells. Virus yields were approximately 10- to 100-fold lower than those of wild-type virus in all cell lines tested. (ii) Electron microscopic examination of Vero cells infected with the UL20- mutant revealed that enveloped and unenveloped capsids accumulated in the cytoplasm, possibly in the space between the inner and outer lamellae of the nuclear membrane, and that virtually no virus was present in the extracellular space. (iii) Glycoproteins B, C, D, E, H, and I recovered from lysates of cells infected with the UL20- mutant could not be differentiated from those present in lysates of cells infected with the wild-type parent virus with respect to the electrophoretic mobility of mature and precursor forms. (iv) Repair of the deleted sequences restored the wild-type phenotype. (v) The gene product of the UL20 gene was shown to be associated with cellular membranes and to possess characteristics of integral membrane proteins. We conclude that the UL20 gene encodes an integral membrane protein with a hitherto unrecognized function in that it enables the transit of virions to the extracellular space. The function of the UL20 gene product is complemented by some cell lines but not by Vero cells. The vesicles which serve to transport virions may have an origin different from those associated with transport of normal cellular proteins.     

转瓶培养与生物反应器微载体培养乙脑病毒的比较

分别用15L转瓶与15L生物反应器微载体(2.5g/L CytodexⅢ)系统培养Vero细胞并接种乙型脑炎病毒(简称乙脑病毒)。转瓶培养Vero细胞7~8d,细胞数最高能达到8×108;当单层细胞长至3.0~4.5×108时接种乙脑病毒,病毒滴度能达到6.5~6.98 lg PFU/ml,并能够连续收获4~5次;采用微载体系统培养Vero细胞,细胞密度最高能达到170×108;当单层细胞长至60~70×108时接种乙脑病毒,病毒滴度能达到7~7.5 lg PFU/ml,并能够连续收获13~15次。两种方式培养的乙脑病毒收获液分别经灭活、浓缩、柱层析纯化后制备Vero细胞乙脑纯化疫苗,各项检定指标均符合《中国药典》的相关要求。     

Characterization of homologous defective interfering RNA during persistent infection of Vero cells with Japanese encephalitis virus

It has been suggested that defective interfering (DI) RNA contributes to the persistence of Japanese en-cephalitis virus (JEV). In this study, we characterized molecular and biological aspects of the DI RNA and its relation to viral persistence. We identified a homolo-gous DI virus intimately associated with JEV persis-tence in Vero cells. The production of DI RNA during undiluted serial passages of JEV coincided with the appearance of cells refractory to acute infection with JEV. We also established a Vero cell clone with a per-sistent JEV infection in which the DI RNA co-replicated efficiently at the expense of helper virus. The infectious virus yield of the clone fluctuated dur-ing its growth depending upon the amount of DI RNA accumulated in the previous replication cycle. Identifi-cation of the corresponding negative-sense RNA of the DI RNA indicated that the DI RNA functioned as a replication unit. Most of the DI RNA molecules re-tained their open reading frames despite a large dele-tion, encompassing most of the prM, the entire E, and the 5' half of the NS1 gene. Taken together, these ob-servations suggest that the generation of homologous DI RNA during successive JEV acute infections in Vero cells probably participates actively in persistent JEV infection.     

A single N-linked glycosylation site in the Japanese encephalitis virus prM protein is critical for cell type-specific prM protein biogenesis, virus particle release, and pathogenicity in mice

The prM protein of Japanese encephalitis virus (JEV) contains a single potential N-linked glycosylation site, N¹⁵-X¹⁶-T¹⁷, which is highly conserved among JEV strains and closely related flaviviruses. To investigate the role of this site in JEV replication and pathogenesis, we manipulated the RNA genome by using infectious JEV cDNA to generate three prM mutants (N15A, T17A, and N15A/T17A) with alanine substiting for N¹⁵ and/or T¹⁷ and one mutant with silent point mutations introduced into the nucleotide sequences corresponding to all three residues in the glycosylation site. An analysis of these mutants in the presence or absence of endoglycosidases confirmed the addition of oligosaccharides to this potential glycosylation site. The loss of prM N glycosylation, without significantly altering the intracellular levels of viral RNA and proteins, led to an ≈20-fold reduction in the production of extracellular virions, which had protein compositions and infectivities nearly identical to those of wild-type virions; this reduction occurred at the stage of virus release, rather than assembly. This release defect was correlated with small-plaque morphology and an N-glycosylation-dependent delay in viral growth. A more conservative mutation, N15Q, had the same effect as N15A. One of the four prM mutants, N15A/T17A, showed an additional defect in virus growth in mosquito C6/36 cells but not human neuroblastoma SH-SY5Y or hamster BHK-21 cells. This cell type dependence was attributed to abnormal N-glycosylation-independent biogenesis of prM. In mice, the elimination of prM N glycosylation resulted in a drastic decrease in virulence after peripheral inoculation. Overall, our findings indicate that this highly conserved N-glycosylation motif in prM is crucial for multiple stages of JEV biology: prM biogenesis, virus release, and pathogenesis.