Conserved amino acids within the N-terminus of the West Nile virus NS4A protein contribute to virus replication, protein stability and membrane proliferation.

The West Nile virus strain Kunjin virus (WNVKUN) NS4A protein is a multifunctional protein involved in many aspects of the virus life-cycle and is a major component of the WNVKUN replication complex (RC). Previously we identified a conserved region in the C-terminus of NS4A regulating proteolytic processing and RC assembly, and now investigate key conserved residues in the N-terminus of NS4A and their contribution to WNVKUN replication. Mutation of P13 completely ablated replication, whereas, mutation of P48 and D49, near the first transmembrane helix, and G66 within the helix, showed variable defects in replication, virion secretion and membrane proliferation. Intriguingly, the P48 and G66 NS4A mutants resulted in specific proteasome depletion of NS4A that could in part be rescued with a proteasome inhibitor. Our results suggest that the N-terminus of NS4A contributes to correct folding and stability, essential for facilitating the essential roles of NS4A during replication.

A conserved peptide in West Nile virus NS4A protein contributes to proteolytic processing and is essential for replication.

The West Nile virus strain Kunjin virus (WNV(KUN)) NS4A protein is a multifunctional protein involved in membrane proliferation, stimulation of cellular pathways, and evasion of host defense and is a major component of the WNV(KUN) RNA replication complex. We identified a highly conserved region ((120)P-E-P-E(123)) upstream of the viral protease dibasic cleavage site and investigated whether this motif was required for WNV(KUN) replication. Single point mutations to alanine and a PEPE deletion mutation were created in a full-length infectious WNV(KUN) molecular clone. All mutations drastically impaired viral replication and virion production, except that of the P122A mutant, which was slightly attenuated. These mutations were subsequently transferred to a WNV(KUN) replicon to specifically assess effects on RNA replication alone. Again, all mutants, except P122A, showed severely reduced negative-sense RNA production as well as decreased viral protein production. Correspondingly, immunofluorescence analyses showed a lack of double-stranded RNA (dsRNA) labeling and a dispersed localization of the WNV(KUN) proteins, suggesting that replication complex formation was additionally impaired. Attempts to rescue replication via conservative mutants largely failed except for substitution of Asp at E121, suggesting that a negative charge at this residue is equally important. Analysis of viral protein processing suggested that cleavage of the 2K peptide from NS4A did not occur with the mutant constructs. These observations imply that the combined effects of proline and negatively charged residues within the PEPE peptide are essential to promote the cleavage of 2K from NS4A, which is a prerequisite for efficient WNV replication.