Higher replication potential of West Nile virus governs apoptosis induction in human neuroblastoma cells.

The extent of neuronal cell damage caused by West Nile virus (WNV) infection governs the disease severity ranging from mild, febrile illness to fatal encephalitis. Availability of naturally occurring genetic variants is helpful to study viral factors governing differential pathogenesis. During WNV infection, apoptosis serves as a virulence determinant positively contributing to viral pathogenesis. We investigated the levels of apoptosis induced by a low neurovirulent WNV lineage 5 strain 804994 and a high neurovirulent lineage 1 strain 68856 in human neuroblastoma cells, IMR-32. Our investigations clearly show the correlation between higher multiplication capacities of 68856 with higher levels of cytopathology induced by apoptosis. We observed activation of both the extrinsic and intrinsic apoptotic pathways during WNV infection. Infection with higher neurovirulent strain resulted in higher upregulation of pro-apoptotic proteins including death receptors (DR), adaptor protein, BH3-only regulatory proteins and higher cleavage of initiator caspases of both pathways. These results suggest that the virulence of a WNV strain may correlate with its higher replication fitness and ability to cause more cellular damage.

Development and characterization of reverse genetics system for the Indian West Nile virus lineage 1 strain 68856.

Our previous studies on West Nile virus (WNV) strains isolated from human patients in India suggested substantial variation at the genetic level reflecting their variable pathogenesis. This study describes the development of reverse genetics system for a neurovirulent WNV isolate 68856 and its characterization. Full length viral cDNA was cloned into bacterial artificial chromosome (BAC) under the transcription control of T7 promoter. The RNA transcripts obtained by in vitro transcription were infectious in mammalian cells upon transfection. Cytopathic effect caused by synthetic RNA transcripts in mammalian cells, detection of cell associated viral protein after transfection and recovery of genetic markers in the progeny virus genome marked the successful development of reverse genetics system for WNV. Replication potential and plaque morphology of newly expressed virus along with its antigenic cross reactivity with the parental virus suggests synthesis of biologically identical replicative virus. Comparative neuropathogenesis studies in murine model indicated that the three genetic changes occurred in the recombinant virus during in vitro transcription has no impact on viral pathogenesis. The stable infectious cDNA clone generated from the neurovirulent Indian WNV strain will serve as a valuable experimental tool to study the viral factors contributing towards pathogenesis, host-virus interaction and immune evasion.