Ann R. Hunt

Chimeric Dengue Type 2 (Vaccine Strain PDK-53)/Dengue Type 1 Virus as a Potential Candidate Dengue Type 1 Virus Vaccine

ABSTRACT We constructed chimeric dengue type 2/type 1 (DEN-2/DEN-1) viruses containing the nonstructural genes of DEN-2 16681 virus or its vaccine derivative, strain PDK-53, and the structural genes (encoding capsid protein, premembrane protein, and envelope glycoprotein) of DEN-1 16007 virus or its vaccine derivative, strain PDK-13. We previously reported that attenuation markers of DEN-2 PDK-53 virus were encoded by genetic loci located outside the structural gene region of the PDK-53 virus genome. Chimeric viruses containing the nonstructural genes of DEN-2 PDK-53 virus and the structural genes of the parental DEN-1 16007 virus retained the attenuation markers of small plaque size and temperature sensitivity in LLC-MK2 cells, less efficient replication in C6/36 cells, and attenuation for mice. These chimeric viruses elicited higher mouse neutralizing antibody titers against DEN-1 virus than did the candidate DEN-1 PDK-13 vaccine virus or chimeric DEN-2/DEN-1 viruses containing the structural genes of the PDK-13 virus. Mutations in the envelope protein of DEN-1 PDK-13 virus affected in vitro phenotype and immunogenicity in mice. The current PDK-13 vaccine is the least efficient of the four Mahidol candidate DEN virus vaccines in human trials. The chimeric DEN-2/DEN-1 virus might be a potential DEN-1 virus vaccine candidate. This study indicated that the infectious clones derived from the candidate DEN-2 PDK-53 vaccine are promising attenuated vectors for development of chimeric flavivirus vaccines.

A Single Intramuscular Injection of Recombinant Plasmid DNA Induces Protective Immunity and Prevents Japanese Encephalitis in Mice

ABSTRACT Plasmid vectors containing Japanese encephalitis virus (JEV) premembrane (prM) and envelope (E) genes were constructed that expressed prM and E proteins under the control of a cytomegalovirus immediate-early gene promoter. COS-1 cells transformed with this plasmid vector (JE-4B clone) secreted JEV-specific extracellular particles (EPs) into the culture media. Groups of outbred ICR mice were given one or two doses of recombinant plasmid DNA or two doses of the commercial vaccine JEVAX. All mice that received one or two doses of DNA vaccine maintained JEV-specific antibodies 18 months after initial immunization. JEVAX induced 100% seroconversion in 3-week-old mice; however, none of the 3-day-old mice had enzyme-linked immunosorbent assay titers higher than 1:400. Female mice immunized with this DNA vaccine developed plaque reduction neutralization antibody titers of between 1:20 and 1:160 and provided 45 to 100% passive protection to their progeny following intraperitoneal challenge with 5,000 PFU of virulent JEV strain SA14. Seven-week-old adult mice that had received a single dose of JEV DNA vaccine when 3 days of age were completely protected from a 50,000-PFU JEV intraperitoneal challenge. These results demonstrate that a recombinant plasmid DNA which produced JEV EPs in vitro is an effective vaccine.

Synthetic peptides derived from the deduced amino acid sequence of the E-glycoprotein of Murray Valley encephalitis virus elicit antiviral antibody

We used computer analysis to study hydrophilicity, homology, surface accessibility, molecular flexibility, and secondary structure of the deduced amino acid sequence of the flavivirus envelope (E)-glycoprotein. Using the results, we modified the E-glycoprotein antigenic structure proposed by Nowak and Wengler (1987, Virology, 156, 127-137). Our model predicts considerable overlaps in the previously defined domains. We have prepared 11 synthetic peptides from the deduced amino acid sequence of the E-glycoprotein of Murray Valley encephalitis (MVE) virus and analyzed their immunogenicity. Peptides derived from the redefined R1 and R2 domains elicit antiviral antibody. Nine of these peptides are recognized by polyclonal antiviral antibodies; however, none are consistently recognized by monoclonal antibodies. Peptides derived from the R1 domain demonstrate MVE virus specificity, and 1 peptide elicited low-level virus neutralizing antibody. Spatial overlap of the domains was defined by competitive binding assays between antipeptide antisera and radioactive monoclonal antibodies. These results indicate that synthetic peptides aid in defining flavivirus antigenic structure, and may serve as possible type-specific diagnostic reagents.

A recombinant particulate antigen of Japanese encephalitis virus produced in stably-transformed cells is an effective noninfectious antigen and subunit immunogen

A COS-1 cell line, stably transformed by a plasmid encoding the premembrane and envelope glycoproteins of Japanese encephalitis virus, produced a noninfectious recombinant antigen expressed as extracellular particles. Extracellular particles purified by equilibrium density centrifugation in sucrose gradients followed by electron microscopy were characterized as spherical particles with an average diameter of approximately 30 nm and a buoyant density of 1.15 g/cc. Purified extracellular particles were shown by western blot to contain premembrane, membrane and envelope proteins. The gradient-purified particles exhibited hemagglutination activity at the same pH optimum (6.6) as Japanese encephalitis virus. Recombinant antigen from cell culture fluid was concentrated by precipitation with polyethylene glycol and evaluated for immunogenicity in 8-10-week-old ICR mice. Groups of five mice received only one immunization of recombinant antigen with or without Freunds incomplete adjuvant. Mice immunized with recombinant antigen plus Freunds incomplete adjuvant elicited the highest anti-viral titers as determined by both enzyme-linked immunosorbent assay (ELISA) and plaque-reduction neutralization tests. The polyethylene glycol-concentrated recombinant antigen was also evaluated for use in IgM antibody-capture ELISA and indirect IgG ELISA. The IgM-capture ELISA results using recombinant antigen correlated well with the results of a similar test using Japanese encephalitis virus-infected mouse brain antigen for the analysis of serum samples from patients with symptoms of acute encephalitis. Similar IgG titers were observed in an indirect ELISA comparing recombinant antigen and purified Japanese encephalitis virus as plate-bound antigens. Based on these studies, this entirely safe, easily produced antigen that expresses authentic Japanese encephalitis virus envelope glycoprotein would provide an excellent alternative to standard viral antigens used in various ELISA formats.

Flavivirus DNA Vaccines

Abstract: The use of DNA‐based vaccines is a novel and promising immunization approach for the development of flavivirus vaccines. This approach has been attempted in vaccine development for various virus species, including St. Louis encephalitis, Russian spring‐summer encephalitis, Central European encephalitis, dengue serotypes 1 and 2, Murray Valley encephalitis, Japanese encephalitis, and West Nile viruses. However, very little is known about the factors affecting its efficacy. Recently, we demonstrated that a single intramuscular immunization of DNA vaccine of Japanese encephalitis and West Nile viruses protected mice and horses from virus challenge. Administration of these recombinant plasmid vectors resulted in endogenous expression and secretion of extracellular virus‐like particles that correlated well with the induction of protective immunity. These results provided evidence that the virus‐like particles composed of premembrane/membrane and envelope proteins are essential for eliciting immune responses similar to those induced by live, attenuated virus vaccines. The biosynthesis and protein processing of premembrane/membrane and envelope proteins that preserve the native conformation and glycosylation profiles identical to virion proteins could be determined by the effectiveness of the transmembrane signal sequence located at the amino‐terminus of premembrane protein. The use of DNA vaccines in multivalent and/or combination vaccines designed to immunize against multiple flaviviruses is also a promising area of development.

Detection of West Nile virus antigen in mosquitoes and avian tissues by a monoclonal antibody-based capture enzyme immunoassay.

ABSTRACT An antigen capture immunoassay to detect West Nile (WN) virus antigen in infected mosquitoes and avian tissues has been developed. With this assay purified WN virus was detected at a concentration of 32 pg/0.1 ml, and antigen in infected suckling mouse brain and laboratory-infected mosquito pools could be detected when the WN virus titer was 102.1 to 103.7 PFU/0.1 ml. In a blindly coded set of field-collected mosquito pools (n = 100), this assay detected WN virus antigen in 12 of 18 (66.7%) TaqMan-positive pools, whereas traditional reverse transcriptase PCR detected 10 of 18 (55.5%) positive pools. A sample set of 73 organ homogenates from naturally infected American crows was also examined by WN virus antigen capture immunoassay and TaqMan for the presence of WN virus. The antigen capture assay detected antigen in 30 of 34 (88.2%) TaqMan-positive tissues. Based upon a TaqMan-generated standard curve of infectious WN virus, the limit of detection in the antigen capture assay for avian tissue homogenates was approximately 103 PFU/0.1 ml. The recommended WN virus antigen capture protocol, which includes a capture assay followed by a confirmatory inhibition assay used to retest presumptive positive samples, could distinguish between the closely related WN and St. Louis encephalitis viruses in virus-infected mosquito pools and avian tissues. Therefore, this immunoassay demonstrates adequate sensitivity and specificity for surveillance of WN virus activity in mosquito vectors and avian hosts, and, in addition, it is easy to perform and relatively inexpensive compared with the TaqMan assay.

Biochemical and biological characteristics of epitopes on the E1 glycoprotein of western equine encephalitis virus

Antigenic determinants identified by monoclonal antibodies (Mabs) on the E1 glycoprotein of western equine encephalitis (WEE) virus have been characterized by their serological activity, requirements for secondary structure, expression on the mature virion, and their role in protecting animals from WEE virus challenge. On the basis of a cross-reactivity enzyme-linked immunosorbent assay (ELISA) and hemagglutination inhibition assay, eight antigenic determinants (epitopes) on the E1 glycoprotein have been identified, ranging in reactivity from WEE-specific to alphavirus group reactive. No neutralization of virus infectivity was demonstrable with any of the Mabs. An alphavirus group-reactive hemagglutination (HA) site, a WEE complex-reactive HA site, and a WEE virus-specific HA site were identified. Spatial arrangement of these epitopes was determined by a competitive binding ELISA. Four competition groups defining three distinct antigenic domains were identified. Antibodies directed against four E1 epitopes were capable of precipitating the E1/E2 heterodimer from infected cells or purified virus disrupted with nonionic detergents. These same antibodies precipitated only E1 in the presence of 0.1% SDS. That E1 conformation was important was shown by the inability of antibodies specific for seven of the epitopes to bind to virus denatured in 0.5% SDS. As determined by equilibrium gradient analysis of virus-antibody mixtures, four epitopes were found to be fully accessible on the mature virion, three epitopes were inaccessible, and one epitope was partially accessible to antibody binding. Antibodies specific for three epitopes were able to passively protect mice from WEE virus challenge.

In vitro mechanisms of monoclonal antibody neutralization of alphaviruses

We have previously identified at least eight epitopes on the E2 glycoprotein of Venezuelan equine encephalomyelitis (VEE) virus vaccine strain TC-83 by using monoclonal antibodies (MAbs). Several of these antibodies identified a critical neutralization (N) domain in competitive binding assays. Passive transfer of these MAbs protected animals from a lethal virus challenge. Using radioactive, purified virus as a marker, we have demonstrated that antibody-mediated virus N, preattachment, can be effected by one of three mechanisms. Interaction of antibody can block virus attachment to susceptible Vero or human embryonic lung cells. The MAbs that were most efficient at blocking attachment were those that defined epitopes spatially proximal to the E2c epitope. The E2c MAbs were, however, the most efficient antibodies for neutralizing virus postattachment. Other E2 MAbs were unable to efficiently block virus attachment to cells; however, resulting replication as monitored by plaque assay or intracellular viral RNA synthesis could not be detected. One novel MAb that defined the E2f epitope appeared to enhance virus attachment to Vero cells, but not BHK-21 or LLC-MK2 cells, by stabilizing virus-cell interaction. This antibody did, however, efficiently neutralize virus infectivity. Once virus had attached to cells, the ability of most MAbs to neutralize infectivity was diminished, except for E2c MAbs. On a molar basis antibody Fab fragments were less efficient than intact antibody at blocking virus attachment.

Antigenic structure of the Murray Valley encephalitis virus E glycoprotein.

To complement our battery of St Louis encephalitis (SLE) virus monoclonal antibodies (MAbs), we isolated and characterized MAbs reactive with another member of the SLE virus serocomplex, Murray Valley encephalitis (MVE) virus. From 40 fusion products, we isolated 10 stable hybridomas. The combination of SLE and MVE virus MAbs defined eight epitopes on the MVE envelope (E) glycoprotein. Six of these epitopes (E-1a, E-1c, E-1d, E-3, E-4a, E-4b) were identical to those previously demonstrated on SLE virus. Two new epitopes (E-5 and E-6) were also identified. As with SLE virus, the MVE E-1c epitope elicited the most potent virus-neutralizing and protective MAb. Unlike SLE virus, however, one of the cross-reactive epitopes (E-5) elicited neutralizing antibody and protected animals from MVE virus challenge. These results indicate that, while the antigenic domains on viruses within the SLE virus serocomplex are quite similar, epitopes involved in virus neutralization or protection from virus challenge may vary and can be topologically distinct.

Contribution of Disulfide Bridging to Epitope Expression of the Dengue Type 2 Virus Envelope Glycoprotein

ABSTRACT The individual contributions of each of the six conserved disulfide (SS) bonds in the dengue 2 virus envelope (E) glycoprotein (strain 16681) to epitope expression was determined by measuring the reactivities of a panel of well-defined monoclonal antibodies (MAbs) with LLC-MK2 cells that had been transiently transformed with plasmid vectors expressing E proteins that were mutant in their SS bonds. Three domain I (DI) epitopes (C1, C3, and C4) were affected by elimination of any SS bond and were essentially the only epitopes affected by elimination of the amino-proximal SS1 formed between Cys 3 and Cys 30. The remaining DI epitope (C2) was sensitive to only SS3-bond (Cys 74-Cys 105) and SS6-bond (Cys 302-Cys 333) elimination. Of the four DII epitopes examined, reactivities of three anti-epitope MAbs (A1, A2, and A5) were reduced by elimination of SS2 (Cys 61-Cys 121), SS3, SS4 (Cys 94-Cys 116), SS5 (Cys 185-Cys 285), or SS6. The other DII epitope examined (A3) was sensitive only to SS2- and SS3-bond elimination. The three DIII epitopes tested (B2, B3, and B4) were most sensitive to elimination of SS6. The flavivirus group epitope (A1) was less sensitive to elimination of SS3 and SS6. This result may indicate that the region proximal to the E-protein fusion motif (amino acids 98 to 110) may have important linear components. If this observation can be confirmed, peptide mimics from this region of E protein might be able to interfere with flavivirus replication.