MAB8744 Sigma-AldrichAnti-St. Louis Encephalitis Antibody, MSI-7, clone 6B6C-1

St. Louis encephalitis virus (SLEV) is a causative agent of encephalitis in humans in the Western hemisphere. SLEV is a positive-sense RNA virus that belongs to the Flavivirus genus, which includes West Nile encephalitis virus, Japanese encephalitis virus, Dengue virus and other medically important viruses. Recently, we isolated a SLEV strain from the brain of a horse with neurological signs in the countryside of Minas Gerais, Brazil. The SLEV isolation was confirmed by reverse-transcription RT-PCR and sequencing of the E protein gene. Virus identity was also confirmed by indirect immunofluorescence using commercial antibodies against SLEV. To characterize this newly isolated strain in vivo, serial passages in newborn mice were performed and led to hemorrhagic manifestations associated with recruitment of inflammatory cells into the central nervous system of newborns. In summary this is the first isolation of SLEV from a horse with neurological signs in Brazil.

Infection with dengue virus presents a broad clinical spectrum, which can range from asymptomatic cases to severe cases that are characterised by haemorrhagic syndrome and/or shock. The reason for such variability remains unknown. This work evaluated the in vitro permissiveness of mouse, rat, hamster and guinea pig macrophages to infection by dengue virus 2 (DENV2). The results established that macrophages derived from the BALB/c mouse strain showed higher permissiveness to DENV2 infection than macrophages from other rodent species, although all rodent species studied had the C820T mutation in the oligoadenylate synthetase 1b gene, indicating no relationship to the different in vitro susceptibilities of mouse cells at this locus. Other molecular mechanisms related to flavivirus susceptibility remain to be explored.

Superinfection exclusion is the ability of an established viral infection to interfere with a second viral infection. Using West Nile virus (WNV) as a model, we show that replicating replicons in BHK-21 cells suppress subsequent WNV infection. The WNV replicon also suppresses superinfections of other flaviviruses but not nonflaviviruses. Mode-of-action analysis indicates that the exclusion of WNV superinfection occurs at the step of RNA synthesis. The continuous culturing of WNV in the replicon-containing cells generated variants that could overcome the superinfection exclusion. The sequencing of the selected viruses revealed mutations in structural (prM S90R or envelope E138K) and nonstructural genes (NS4a K124R and peptide 2K V9M). Mutagenesis analysis showed that the mutations in structural genes nonselectively enhance viral infection in both naïve and replicon-containing BHK-21 cells; in contrast, the mutations in nonstructural genes more selectively enhance viral replication in the replicon-containing cells than in the naïve cells. Mechanistic analysis showed that the envelope mutation functions through the enhancement of virion attachment to BHK-21 cells, whereas the 2K mutation (and, to a lesser extent, the NS4a mutation) functions through the enhancement of viral RNA synthesis. Furthermore, we show that WNV superinfection exclusion is reversible by the treatment of the replicon cells with a flavivirus inhibitor. The preestablished replication of the replicon could be suppressed by infecting the cells with the 2K mutant WNV but not with the wild-type virus. These results suggest that WNV superinfection exclusion is a result of competition for intracellular host factors that are required for viral RNA synthesis.

The emergence of the West Nile virus (WNV) in the northeastern United States has drawn emphasis to the need for expanded arbovirus surveillance in Connecticut. Although the state of Connecticut began a comprehensive mosquito-screening program in 1997, only since 1999 have there been efforts to determine the prevalence of arboviruses in bird populations in this state. Herein, we report on our results of an arbovirus survey of 1,704 bird brains. Included in this report are the first known isolations of eastern equine encephalitis virus (EEEV) from crows and data on the geographic and temporal distribution of 1,092 WNV isolations from crow species. Moreover, these nine isolations of EEEV identify regions of Connecticut where the virus is rarely found. With the exception of WNV and EEEV, no other arboviruses were isolated or detected. Taken together, these data illustrate the distribution of avian borne EEEV and WNV in 2000 and support the need for ongoing avian arbovirus surveillance in Connecticut.

We have identified and characterized eight antigenic epitopes on the 53,000 dalton envelope (E) glycoprotein of Saint Louis encephalitis (SLE) virus by using monoclonal antibodies. One of these epitopes (E-1c) encoded for the type-specific biologic functions of hemagglutination (HA) and neutralization (N). Injection of 50 ng of anti-E-1c antibody protected the majority of mice from peripheral challenge with 100 i.p. LD50 of SLE virus. Similar levels of protection with antibodies specific for other epitopes usually required greater than or equal to 1000-fold additional antibody. Attempts to block N or protection at the E-1c antigenic domain by using antibody to several other SLE epitopes that strongly competed for the E-1c site were unsuccessful. Enhancement of protection was observed with mixtures of the more cross-reactive antibodies. The E-1c antibody was also effective in abrogating SLE virus replication until neural invasion occurred. On the basis of these findings, the topologic arrangement and function of the eight SLE E glycoprotein epitopes on the virion spike is proposed.