Clinicoepidemiological data suggest that type 2 diabetes is associated with increased risk of West Nile virus encephalitis (WNVE). However, no experimental studies have elucidated the role of diabetes in WNV neuropathogenesis. Herein, we employed the db/db mouse model to understand WNV immunopathogenesis in diabetics. Nine-week old C57BL/6 WT and db/db mice were inoculated with WNV and mortality, virus burden in the periphery and brain, and antiviral defense responses were analyzed. db/db mice were highly susceptible to WNV disease, exhibited increased tissue tropism and mortality than the wild-type mice, and were unable to clear the infection. Increased and sustained WNV replication was observed in the serum, peripheral tissues and brain of db/db mice, and heightened virus replication in the periphery was correlated with enhanced neuroinvasion and replication of WNV in the brain. WNV infection in db/db mice was associated with enhanced inflammatory response and compromised antiviral immune response characterized by delayed induction of IFN-α, and significantly reduced concentrations of WNV-specific IgM and IgG antibodies. The compromised immune response in db/db mice correlated with increased viremia. These data suggest that delayed immune response coupled with failure to clear the virus leads to increased mortality in db/db mice. In conclusion, this study provides unique mechanistic insight into the immunopathogenesis of WNVE observed in diabetics and can be used to develop therapeutics for the management of WNVE among diabetic patients.
Immunopathogenesis studies employing West Nile virus (WNV) mice model are important for the development of antivirals and vaccines against WNV. Since antibodies produced in mice early during WNV infection are essential for clearing virus from the periphery, it is important to detect early and persistent anti-WNV antibodies. ELISA and plaque reduction neutralization tests are traditionally used for detection of anti-WNV antibodies and WNV-neutralizing antibodies, respectively. Although these assays are sensitive and specific, they are expensive and time consuming. Microsphere immunoassays (MIA) are sensitive, specific, allow for high throughput, are cost effective, require less time to perform than other methods, and require low serum volumes. Several assay parameters such as serum heat-inactivation (HI) and dilution can alter WNV MIA sensitivity. We examined the effect of these parameters on WNV E-protein MIA (WNV E-MIA) for the enhanced detection of anti-WNV IgM and IgG antibodies. WNV E-MIA was conducted using serial dilutions of HI and non-HI (NHI) serum collected at various time points from mice inoculated with WNV. HI significantly enhanced detection of IgM and IgG antibodies as compared to NHI serum. WNV IgM and IgG antibodies in HI sera were detected earlier at day 3 and IgM antibodies persisted up to day 24 after infection. HI serum at 1∶20 dilution was found to be optimal for detection of both IgM and IgG antibodies as compared to higher-serum dilutions. Further, addition of exogenous complement to the HI serum decreased the WNV E-MIA sensitivity. These results suggest that serum-HI and optimal dilution enhance WNV E-MIA sensitivity by eliminating the complement interference, thereby detecting low-titer anti-WNV antibodies during early and late phases of infection. This improved MIA can also be readily employed for detection of low-titer antibodies for detection of other infectious agents and host proteins.
The recent outbreaks of Zika virus (ZIKV) infection in French Polynesia, the Caribbean, and the Americas have highlighted the severe neuropathological sequelae that such an infection may cause. The development of a safe, effective ZIKV vaccine is critical for several reasons: (i) the difficulty in diagnosing an active infection due to common nonspecific symptoms, (ii) the lack of a specific antiviral therapy, and (iii) the potentially devastating pathological effects of in utero infection. Moreover, a vaccine with an excellent safety profile, such as a nonreplicating, noninfectious vaccine, would be ideal for high-risk people (e.g., pregnant women, immunocompromised patients, and elderly individuals). This report describes the development of a recombinant subunit protein vaccine candidate derived from stably transformed insect cells expressing the ZIKV envelope protein in vitro, the primary antigen to which effective virus-neutralizing antibodies are engendered by immunized animals for several other flaviviruses; the vaccine candidate elicits effective virus-neutralizing antibodies against ZIKV and provides protection against ZIKV infection in mice.
dWe evaluated the FDA-cleared InBios dengue virus (DENV) IgM capture enzyme-linked immunosorbent assay (ELISA) for qualitative detection of anti-DENV IgM antibodies from 79 serum samples obtained from dengue virus-infected patients or suspected dengue cases. The agreement, sensitivity, and specificity of the InBios assay compared to the gold standard in-house DENV IgM capture ELISA were 94, 92, and 94%, respectively. We conclude that the InBios DENV IgM capture ELISA can be effectively used for rapid diagnosis of acute or recent DENV infection. Dengue virus (DENV) a mosquito-borne flavivirus, is a significant human pathogen of global importance (1). Dengue, an acute viral disease, is caused by any one of the four DENV serotypes, DENV-1, -2, -3, and -4 (2). Although most of the reported dengue cases in the United States are acquired by travelers or immigrants (3), autochthonous dengue fever outbreaks have occurred in Brownsville, TX (2005), and southern Florida (2009 to 2011) and Hawaii (2011) (4). To date, there is no vaccine or specific antiviral treatment for dengue virus infection in humans, and effective management of severe dengue virus disease can be augmented by rapid diagnosis during the acute stage of infection (5, 6).In the majority of DENV infections, immunoglobulin M (IgM) antibodies can be detected within 3 to 5 days following the onset of fever (7). In secondary DENV infection, IgM antibody titers are usually lower than those in primary DENV infection but follow similar kinetics (8). An ideal IgM serologic test should have sufficient sensitivity to detect low DENV IgM antibody titers and be specific enough to discriminate DENV infection in areas where multiple flaviviruses and other pathogens cocirculate (9). Several rapid diagnostic tests are commercially available for detection of anti-DENV IgM antibodies (9). Therefore, it is important to evaluate the performance characteristics of these kits in terms of sensitivity and specificity in order to ensure accurate and rapid diagnosis of dengue virus infection (5). Recently, the U.S. Food and Drug Administration (FDA) cleared the InBios DENV Detect IgM capture enzyme-linked immunosorbent assay (ELISA) (InBios International, Inc., Seattle, WA) for qualitative detection of anti-DENV IgM antibodies (4). This test can detect acute or recent DENV infections and can be used by public health laboratories for rapid confirmation of dengue cases during dengue outbreaks (4).(These research data are part of the master's thesis of M.N. submitted to the University of Hawaii.)In this study, we evaluated the InBios DENV IgM capture ELISA in comparison with the in-house DENV IgM antibody capture (MAC) ELISA using 79 well-characterized clinical serum samples collected from Hawaii, Vietnam, Niue, Singapore, and American Samoa, where dengue outbreaks have occurred in the past. Samples were coded and collected in compliance with the University of Hawaii Institutional Review Board guidelines (CHS 16857 and 16873). All serum samples were frozen at Ϫ70°C prior to assay.The I...
Zika Virus (ZIKV), a virus with no severe clinical symptoms or sequelae previously associated with human infection, became a public health threat following an epidemic in French Polynesia 2013–2014 that resulted in neurological complications associated with infection. Although no treatment currently exists, several vaccines using different platforms are in clinical development. These include nucleic acid vaccines based on the prM-E protein from the virus and purified formalin-inactivated ZIKV vaccines (ZPIV) which are in Phase 1/2 clinical trials. Using a recombinant subunit platform consisting of antigens produced in Drosophila melanogaster S2 cells, we have previously shown seroconversion and protection against viremia in an immunocompetent mouse model. Here we demonstrate the efficacy of our recombinant subunits in a non-human primate (NHP) viremia model. High neutralizing antibody titers were seen in all protected macaques and passive transfer demonstrated that plasma from these NHPs was sufficient to protect against viremia in mice subsequently infected with ZIKV. Taken together our data demonstrate the immunogenicity and protective efficacy of the recombinant subunit vaccine candidate in NHPs as well as highlight the importance of neutralizing antibodies in protection against ZIKV infection and their potential implication as a correlate of protection.
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