Specific diagnostic method for St. Louis encephalitis virus using a non-structural protein as the antigen.

St. Louis encephalitis virus (SLEV) is a mosquito-borne re-emerging flavivirus in Argentina. It is currently necessary to develop specific serological tests that can efficiently discriminate the flaviviruses that circulate in our country. The immunoassays to diagnose SLEV lack specificity because they are based on the detection of structural viral proteins and the human immunoglobulins produced during infection against these proteins cross-react with other flaviviruses. Here, we describe an enzyme-immunoassay designed to detect human IgG antibodies specific to the viral non-structural protein NS5. The results indicate that NS5 is a promising antigen useful to discriminate SLEV from other circulating flaviviruses.

Production of recombinant NS1 protein and its possible use in encephalitic flavivirus differential diagnosis.

Saint Louis encephalitis virus (SLEV) and West Nile virus (WNV) are two of the major causes of arboviral encephalitis in the Americas. The co-circulation of related flaviviruses in the Americas and prior vaccination against flaviviruses pose problems to the diagnostic specificity of serological assays due to the development of cross-reactive antibodies. An accurate diagnosis method capable of differentiating these related viruses is needed. NS1 is a glycosylated, nonstructural protein, of about 46 kDa which has a highly conserved structure. Anti-NS1 antibodies can be detected within 4-8 days after the initial exposure and NS1 is the least cross-reactive of the flaviviral antigens. This study was aimed to generate SLEV and WNV NS1 recombinants proteins for the development of a flavivirus diagnostic test. Local Argentinian isolates were used as the source of NS1 gene cloning, expression, and purification. The protein was expressed in Escherichia coli as inclusion bodies and further purified by metal-chelating affinity chromatography (IMAC) under denaturing conditions. Human sera from SLEV and WNV positive cases showed reactivity to the recombinant NS1 proteins by western blot. The unfolded NS1 proteins were also used as immunogens. The polyclonal antibodies elicited in immunized mice recognized the two recombinant proteins with differential reactivity.

A rapid method to produce high yields of purified rotavirus particles.

A rapid purification method of rotavirus particles to high yield retaining the double shelled structure of infectious virus is described. Group A rotavirus (UK strain) was concentrated through a cushion of colloidal silica (rho=1.10 g/cm(3)) or by precipitating with polyethylene glycol 8000. After concentration, infectious rotavirus was cleared from host cell proteins by density equilibrium centrifugation in gradients of colloidal silica using near vertical rotors. Characterisation of purified virus assessed by electron microscopy and poliacrylamide gel electrophoresis (PAGE) revealed the typical wheel shape structure of rotavirus particles and the presence of the 11 segments of dsRNA arranged in the 4-2-3-2 pattern. Presence of rotavirus structural proteins including VP6, VP4 and VP7 from the outer shell, was demonstrated by SDS-PAGE and Western blot using polyclonal and VP6-specific monoclonal antibodies. This method achieved a approximately 1500 fold purification, which retained approximately 80% infectivity depending on the concentration protocol used, while yielding 160 microg of viral protein per each litre of infected cell culture medium. The time required for the isopycnic centrifugation was only 25 min and the entire completion of the method required 3.5 h. The method is simple technically and applicable to the purification of large as well as minute amounts of virus.