Mutagen resistance and mutation restriction of St. Louis encephalitis virus.

The error rate of the RNA-dependent RNA polymerase (RdRp) of RNA viruses is important in maintaining genetic diversity for viral adaptation and fitness. Numerous studies have shown that mutagen-resistant RNA virus variants display amino acid mutations in the RdRp and other replicase subunits, which in turn exhibit an altered fidelity phenotype affecting viral fitness, adaptability and pathogenicity. St. Louis encephalitis virus (SLEV), like its close relative West Nile virus, is a mosquito-borne flavivirus that has the ability to cause neuroinvasive disease in humans. Here, we describe the successful generation of multiple ribavirin-resistant populations containing a shared amino acid mutation in the SLEV RdRp (E416K). These E416K mutants also displayed resistance to the antiviral T-1106, an RNA mutagen similar to ribavirin. Structural modelling of the E416K polymerase mutation indicated its location in the pinky finger domain of the RdRp, distant from the active site. Deep sequencing of the E416K mutant revealed lower genetic diversity than wild-type SLEV after growth in both vertebrate and invertebrate cells. Phenotypic characterization showed that E416K mutants displayed similar or increased replication in mammalian cells, as well as modest attenuation in mosquito cells, consistent with previous work with West Nile virus high-fidelity variants. In addition, attenuation was limited to mosquito cells with a functional RNA interference response, suggesting an impaired capacity to escape RNA interference could contribute to attenuation of high-fidelity variants. Our results provide increased evidence that RNA mutagen resistance arises through modulation of the RdRp and give further insight into the consequences of altered fidelity of flaviviruses.

Improvement of the purification of Saint Louis encephalitis virus NS2B-NS3 recombinant protease expressed in Escherichia coli.

The NS2B-NS3 serine protease of Saint Louis Encephalitis virus (SLEV), a potential target for antiviral drug design, has been over-expressed as a recombinant His-tag protein in Escherichia coli for future structural determination. The production process resulted in a soluble protease with co-purification of DnaK, a bacterial molecular chaperone already described in E. coli protein expression. Two approaches were tested to remove this specific contaminant. The fusion protein bound to the purification resin was washed with MgATP plus soluble denatured E. coli proteins before elution, but this method proved to be poorly efficient due to a substantial loss of the targeted recombinant protease. After the immobilized metal affinity chromatography step, the use of gel permeation chromatography with addition of arginine in the mobile phase led to effective separation of the native viral protease from the DnaK aggregates. By this way, SLEV DeltaNS2B-NS3pro protease was purified as a functional protein with a purity greater than 90% suitable for crystallization attempts.

Unexpected altered specificity is responsible for St. Louis encephalitis virus recombinant protease autoproteolysis.

We report herein the study of the cleavage fragments generated by autoproteolysis of the St. Louis encephalitis virus recombinant protease. The cleavage sites leading to truncated forms were identified by microsequencing, which revealed an unexpected altered specificity of the recombinant proteinase towards unusual sequences.

Saint Louis encephalitis viral ribonucleic acid replication complex.

Pulse-labeled Saint Louis encephalitis viral ribonucleic acid (RNA) is found in the cytoplasm of infected cells associated with a membranous structure which sediments with an average value of 250S. The integrity of the complex is destroyed by detergents and ribonuclease; however, it is stable in ethylenediaminetetraacetic acid (EDTA) which differentiates this structure from cellular polyribosomes. With cultures in which cellular RNA was highly labeled prior to infection, ribosomal RNA could not be demonstrated in the complex isolated from EDTA-sucrose gradients. Single-stranded 43S and the 26S and 20S forms of viral RNA were found in the complex. Viral RNA polymerase activity in sucrose-gradient fractions sedimented in the same region as the fractions which contained the pulse-labeled viral RNA. The polymerase incorporated (3)H-guanosine triphosphate into acid-precipitable material in the absence of added template. It was also found that the replication complex contains viral-specific proteins.