Production of Venezuelan equine encephalitis virus in cells grown on artificial capillaries

Primary cell cultures, a continuous cell line, and a diploid cell line were grown on an artificial capillary system. The cells were subsequently infected with Venezuelan equine encephalitis virus, and viral replication was studied. Extracellular fluids harvested from this system contained high titers of virus and were relatively free of cell debris.     

A putative receptor for Venezuelan equine encephalitis virus from mosquito cells.

We have identified a cellular protein from a continuous mosquito cell line (C6/36) that appears to play a significant role in the attachment of Venezuelan equine encephalitis (VEE) virus to these cells. VEE virus bound to a 32-kDa polypeptide present in the C6/36 plasma membrane fraction, and binding to this polypeptide was dose dependent and saturable and competed with homologous and heterologous alphaviruses. These observations suggest that this polypeptide binds virus via a receptor-ligand interaction. The 32-kDa polypeptide was expressed on the surfaces of C6/36 cells, and monoclonal antibodies directed against either this cell polypeptide or the VEE virus E2 glycoprotein, which is thought to be the viral attachment protein, interfered with virus attachment. Collectively, these data provide evidence suggesting that the 32-kDa polypeptide serves as a receptor for VEE virus infection of cells. We have characterized this cell polypeptide as a laminin-binding protein on the basis of its ability to interact directly with laminin as well as its immunologic cross-reactivity with the high-affinity human laminin receptor.     

Production of Venezuelan equine encephalitis virus in cells grown on artificial capillaries.

Primary cell cultures, a continuous cell line, and a diploid cell line were grown on an artificial capillary system. The cells were subsequently infected with Venezuelan equine encephalitis virus, and viral replication was studied. Extracellular fluids harvested from this system contained high titers of virus and were relatively free of cell debris.     

Complete inactivation of Venezuelan equine encephalitis virus by 1,5-iodonaphthylazide

Hydrophobic alkylating compounds like 1,5-iodonaphthylazide (INA) partitions into biological membranes and accumulates selectively into the hydrophobic domain of the lipid bilayer. Upon irradiation with far UV light, INA binds selectively to transmembrane proteins in the viral envelope and renders them inactive. Such inactivation does not alter the ectodomains of the membrane proteins thus preserving the structural and conformational integrity of immunogens on the surface of the virus. In this study, we have used INA to inactivate Venezuelan equine encephalitis virus (VEEV). Treatment of VEEV with INA followed by irradiation with UV light resulted in complete inactivation of the virus. Immuno-fluorescence for VEEV and virus titration showed no virus replication in-vitro. Complete loss of infectivity was also achieved in mice infected with INA treated plus irradiated preparations of VEEV. No change in the structural integrity of VEEV particles were observed after treatment with INA plus irradiation as assessed by electron microscopy. This data suggest that such inactivation strategies can be used for developing vaccine candidates for VEEV and other enveloped viruses.     

Expression and self-assembly of norwalk virus capsid protein from venezuelan equine encephalitis virus replicons

The Norwalk virus (NV) capsid protein was expressed using Venezuelan equine encephalitis virus replicon particles (VRP-NV1). VRP-NV1 infection resulted in large numbers of recombinant NV-like particles that were primarily cell associated and were indistinguishable from NV particles produced from baculoviruses. Mutations located in the N-terminal and P1 domains of the NV capsid protein ablated capsid self-assembly in mammalian cells.     

Role of dendritic cell targeting in Venezuelan equine encephalitis virus pathogenesis

The initial steps of Venezuelan equine encephalitis virus (VEE) spread from inoculation in the skin to the draining lymph node have been characterized. By using green fluorescent protein and immunocytochemistry, dendritic cells in the draining lymph node were determined to be the primary target of VEE infection in the first 48 h following inoculation. VEE viral replicon particles, which can undergo only one round of infection, identified Langerhans cells to be the initial set of cells infected by VEE directly following inoculation. These cells are resident dendritic cells in the skin, which migrate to the draining lymph node following activation. A point mutation in the E2 glycoprotein gene of VEE that renders the virus avirulent and compromises its ability to spread beyond the draining lymph blocked the appearance of virally infected dendritic cells in the lymph node in vivo. A second-site suppressor mutation that restores viral spread to lymphoid tissues and partially restore virulence likewise restored the ability of VEE to infect dendritic cells in vivo.     

Specific in vitro lymphocyte transformation with Venezuelan equine encephalitis virus.

Specific lymphocyte transformation to viral antigen was detected in individuals vaccinated with live, attenuated Venezuelan equine encephalitis (VEE) virus vaccine, strain TC-83. Suspensions of purified, inactivated virus were used an antigen in 250-μ1 lymphocyte cultures, and under optimal conditions the assay demonstrated 10-fold greater incorporation of ¹⁴C-thymidine by lymphocytes from immune than from nonimmune people. The rise in lymphocyte transformation response occurred 1 week after vaccination. The magnitude and range of the lymphocyte transformation response to the VEE viral antigen were similar to the responses seen using antigens derived from five other microbial sources: Francisella tularensis, Coccidioides immitis, Mycobacterium tuberculosis, Streptococcus, and parainfluenza virus. Autologous plasma containing antibody exerts an inhibitory effect on cultures from immune individuals. The onset, magnitude of response, and specificity of this in vitro assay are correlated with the clinical and pathological events of VEE virus infection.     

Nuclear import and export of Venezuelan equine encephalitis virus nonstructural protein 2

Many RNA viruses, which replicate predominantly in the cytoplasm, have nuclear components that contribute to their life cycle or pathogenesis. We investigated the intracellular localization of the multifunctional nonstructural protein 2 (nsP2) in mammalian cells infected with Venezuelan equine encephalitis virus (VEE), an important, naturally emerging zoonotic alphavirus. VEE nsP2 localizes to both the cytoplasm and the nucleus of mammalian cells in the context of infection and also when expressed alone. Through the analysis of a series of enhanced green fluorescent protein fusions, a segment of nsP2 that completely localizes to the nucleus of mammalian cells was identified. Within this region, mutation of the putative nuclear localization signal (NLS) PGKMV diminished, but did not obliterate, the ability of the protein to localize to the nucleus, suggesting that this sequence contributes to the nuclear localization of VEE nsP2. Furthermore, VEE nsP2 specifically interacted with the nuclear import protein karyopherin-alpha1 but not with karyopherin-alpha2, -3, or -4, suggesting that karyopherin-alpha1 transports nsP2 to the nucleus during infection. Additionally, a novel nuclear export signal (NES) was identified, which included residues L526 and L528 of VEE nsP2. Leptomycin B treatment resulted in nuclear accumulation of nsP2, demonstrating that nuclear export of nsP2 is mediated via the CRM1 nuclear export pathway. Disruption of either the NLS or the NES in nsP2 compromised essential viral functions. Taken together, these results establish the bidirectional transport of nsP2 across the nuclear membrane, suggesting that a critical function of nsP2 during infection involves its shuttling between the cytoplasm and the nucleus.     

东部马脑脊髓炎病毒的分子生物学进展

东部马脑脊髓炎病毒属虫媒病毒,能引起人和马发生急性脑炎。东马病毒为单股正链RNA病毒,可分为南美型和北美型,包括两个开放读码框架,分别编码结构蛋白（E1,E2,E2,C,6K）和非结构蛋白（nsp1,nsp2,nsp3,nsp4)。其中E1/E2包膜糖蛋白以异二聚体的形式病毒颗粒外刺突。非结构蛋白主要能与负链RNA的合成,近来,随着研究深入,病毒受体越来越受到广泛关注。本介绍东部马脑脊髓炎病毒结构、进化、复制、组装等方面的分子生物学进展。     

A five-amino-acid deletion of the eastern equine encephalitis virus capsid protein attenuates replication in mammalian systems but not in mosquito cells

Eastern equine encephalitis virus (EEEV) is a human and veterinary pathogen that causes sporadic cases of fatal neurological disease. We previously demonstrated that the capsid protein of EEEV is a potent inhibitor of host cell gene expression and that this function maps to the amino terminus of the protein. We now identify amino acids 55 to 75, within the N terminus of the capsid, as critical for the inhibition of host cell gene expression. An analysis of stable EEEV replicons expressing mutant capsid proteins corroborated these mapping data. When deletions of 5 to 20 amino acids within this region of the capsid were introduced into infectious EEEV, the mutants exhibited delayed replication in Vero cells. However, the replication of the 5-amino-acid deletion mutant in C710 mosquito cells was not affected, suggesting that virus replication and assembly were affected in a cell-specific manner. Both 5- and 20-amino-acid deletion mutant viruses exhibited increased sensitivity to interferon (IFN) in cell culture and impaired replication and complete attenuation in mice. In summary, we have identified a region within the capsid protein of EEEV that contributes to the inhibition of host gene expression and to the protection of EEEV from the antiviral effects of IFNs. This region is also critical for EEEV pathogenesis.     

Recombinant sindbis/Venezuelan equine encephalitis virus is highly attenuated and immunogenic

Venezuelan equine encephalitis virus (VEEV) is an important, naturally emerging zoonotic virus. VEEV was a significant human and equine pathogen for much of the past century, and recent outbreaks in Venezuela and Colombia (1995), with about 100,000 human cases, indicate that this virus still poses a serious public health threat. The live attenuated TC-83 vaccine strain of VEEV was developed in the 1960s using a traditional approach of serial passaging in tissue culture of the virulent Trinidad donkey (TrD) strain. This vaccine presents several problems, including adverse, sometimes severe reactions in many human vaccinees. The TC-83 strain also retains residual murine virulence and is lethal for suckling mice after intracerebral (i.c.) or subcutaneous (s.c.) inoculation. To overcome these negative effects, we developed a recombinant, chimeric Sindbis/VEE virus (SIN-83) that is more highly attenuated. The genome of this virus encoded the replicative enzymes and the cis-acting RNA elements derived from Sindbis virus (SINV), one of the least human-pathogenic alphaviruses. The structural proteins were derived from VEEV TC-83. The SIN-83 virus, which contained an additional adaptive mutation in the nsP2 gene, replicated efficiently in common cell lines and did not cause detectable disease in adult or suckling mice after either i.c. or s.c. inoculation. However, SIN-83-vaccinated mice were efficiently protected against challenge with pathogenic strains of VEEV. Our findings suggest that the use of the SINV genome as a vector for expression of structural proteins derived from more pathogenic, encephalitic alphaviruses is a promising strategy for alphavirus vaccine development.     

Protective cytotoxic T-cell responses induced by venezuelan equine encephalitis virus replicons expressing Ebola virus proteins

Infection with Ebola virus causes a severe disease accompanied by high mortality rates, and there are no licensed vaccines or therapies available for human use. Filovirus vaccine research efforts still need to determine the roles of humoral and cell-mediated immune responses in protection from Ebola virus infection. Previous studies indicated that exposure to Ebola virus proteins expressed from packaged Venezuelan equine encephalitis virus replicons elicited protective immunity in mice and that antibody-mediated protection could only be demonstrated after vaccination against the glycoprotein. In this study, the murine CD8(+) T-cell responses to six Ebola virus proteins were examined. CD8(+) T cells specific for Ebola virus glycoprotein, nucleoprotein, and viral proteins (VP24, VP30, VP35, and VP40) were identified by intracellular cytokine assays using splenocytes from vaccinated mice. The cells were expanded by restimulation with peptides and demonstrated cytolytic activity. Adoptive transfer of the CD8(+) cytotoxic T cells protected filovirus na?ve mice from challenge with Ebola virus. These data support a role for CD8(+) cytotoxic T cells as part of a protective mechanism induced by vaccination against six Ebola virus proteins and provide additional evidence that cytotoxic T-cell responses can contribute to protection from filovirus infections.     

The role of the blood-brain barrier during Venezuelan equine encephalitis virus infection

Venezuelan equine encephalitis (VEE) virus is a mosquito-borne alphavirus associated with sporadic outbreaks in human and equid populations in the Western Hemisphere. After the bite of an infected mosquito, the virus initiates a biphasic disease: a peripheral phase with viral replication in lymphoid and myeloid tissues, followed by a neurotropic phase with infection of central nervous system (CNS) neurons, causing neuropathology and in some cases fatal encephalitis. The mechanisms allowing VEE virus to enter the CNS are currently poorly understood. Previous data have shown that the virus gains access to the CNS by infecting olfactory sensory neurons in the nasal mucosa of mice. However, at day 5 after inoculation, the infection of the brain is multifocal, indicating that virus particles are able to cross the blood-brain barrier (BBB). To better understand the role of the BBB during VEE virus infection, we used a well-characterized mouse model system. Using VEE virus replicon particles (VRP), we modeled the early events of neuroinvasion, showing that the replication of VRP in the nasal mucosa induced the opening of the BBB, allowing peripherally administered VRP to invade the brain. Peripheral VEE virus infection was characterized by a biphasic opening of the BBB. Further, inhibition of BBB opening resulted in a delayed viral neuroinvasion and pathogenesis. Overall, these results suggest that VEE virus initially enters the CNS through the olfactory pathways and initiates viral replication in the brain, which induces the opening of the BBB, allowing a second wave of invading virus from the periphery to enter the brain.