The relationships between West Nile and Kunjin viruses.

Until recently, West Nile (WN) and Kunjin (KUN) viruses were classified as distinct types in the Flavivirus genus. However, genetic and antigenic studies on isolates of these two viruses indicate that the relationship between them is more complex. To better define this relationship, we performed sequence analyses on 32 isolates of KUN virus and 28 isolates of WN virus from different geographic areas, including a WN isolate from the recent outbreak in New York. Sequence comparisons showed that the KUN virus isolates from Australia were tightly grouped but that the WN virus isolates exhibited substantial divergence and could be differentiated into four distinct groups. KUN virus isolates from Australia were antigenically homologous and distinct from the WN isolates and a Malaysian KUN virus. Our results suggest that KUN and WN viruses comprise a group of closely related viruses that can be differentiated into subgroups on the basis of genetic and antigenic analyses.

Kunjin virus: an Australian variant of West Nile?

Kunjin (KUN) is a flavivirus in the Japanese encephalitis antigenic complex that was first isolated from Culex annulirostris mosquitoes captured in northern Australia in 1960. It is the etiological agent of a human disease characterized by febrile illness with rash or mild encephalitis and, occasionally, of a neurological disease in horses. KUN virus shares a similar epidemiology and ecology with the closely related Murray Valley encephalitis (MVE) virus, the major causative agent of arboviral encephalitis in Australia. Based on traditional antigenic methods, KUN was initially found to be similar to, but distinct from, reference strains of West Nile (WN) virus and designated as a new species. However, more recent phylogenic analyses have revealed that some strains of WN virus, including the isolates from New York, are more similar to KUN virus and form a separate lineage to other WN viruses. An unusual KUN isolate from Malaysia and the African virus Koutango appear to form additional lineages within the WN group of viruses. While these findings are in agreement with the Seventh Report of the International Committee for the Taxonomy of Viruses that designates KUN as a subtype of West Nile, they also suggest that the species should be further subdivided into additional subtypes.

Isolation of homologous arbovirus cultures from heterologous mixtures using limit dilution and virus-specific enzyme immunoassays.

Viral cultures were identified recently that contained both Kunjin virus and the closely related flavivirus West Nile. The observation that the KUN virus population grew more efficiently in a mosquito cell line (C6/36) while the WN population replicated more effectively in mammalian cells (Vero) allowed enrichment for either virus by culturing the mixture in the appropriate cell line. Limit dilution of the enriched virus preparations was then performed by infecting microtitre cultures with serial ten fold dilutions. Culture wells that contained a pure population of virus were then identified by immunostaining fixed cell monolayers with virus-specific monoclonal antibodies. Subsequent passage of the 'cloned' viruses in either C6/36 or Vero cells and analysis of the infected cultures by specific monoclonal antibody staining, PCR and nucleotide sequencing confirmed the identity of the virus and that in each case an homogeneous virus population had been obtained. This procedure is particularly useful for isolating virus populations from heterogeneous mixtures that fail to develop discrete plaques in infected cell monolayers.

Origin of the West Nile virus responsible for an outbreak of encephalitis in the northeastern United States.

In late summer 1999, an outbreak of human encephalitis occurred in the northeastern United States that was concurrent with extensive mortality in crows (Corvus species) as well as the deaths of several exotic birds at a zoological park in the same area. Complete genome sequencing of a flavivirus isolated from the brain of a dead Chilean flamingo (Phoenicopterus chilensis), together with partial sequence analysis of envelope glycoprotein (E-glycoprotein) genes amplified from several other species including mosquitoes and two fatal human cases, revealed that West Nile (WN) virus circulated in natural transmission cycles and was responsible for the human disease. Antigenic mapping with E-glycoprotein-specific monoclonal antibodies and E-glycoprotein phylogenetic analysis confirmed these viruses as WN. This North American WN virus was most closely related to a WN virus isolated from a dead goose in Israel in 1998.

Loss of dimerisation of the nonstructural protein NS1 of Kunjin virus delays viral replication and reduces virulence in mice, but still allows secretion of NS1.

The flavivirus nonstructural protein NS1 has been implicated in viral RNA replication, although its precise role has not been identified. In its native state NS1 exists as a heat labile homodimer that is thought to be required for NS1 function and secretion. However, we have recently identified a cDNA clone of KUN virus (FLSD) that replicates efficiently in cell culture but produces and secretes NS1 in monomeric form. Sequence analysis of the NS1 gene in FLSD revealed a single amino acid substitution (proline(250) to leucine) when compared with the parental KUN virus. When site-directed mutagenesis was used to substitute leucine(250) with proline in FLSD to produce the clone 250pro, dimerisation was fully restored. Furthermore, time course experiments revealed that 250pro replicated in Vero cells significantly faster than FLSD and produced 100-fold more infectious virus early (12-24 h) in infection. This correlated with our observations that FLSD required approximately 10-fold more infectious virus than 250pro to produce disease in weanling mice after intraperitoneal inoculation. Taken together our results indicate that mutation from proline to leucine at residue 250 in KUN NS1 ablates dimer formation, slows virus replication, and reduces virulence in mice.

Genetic stability among temporally and geographically diverse isolates of Barmah Forest virus.

An increase in the incidence of polyarthritis caused by Barmah Forest (BF) virus, and its recent emergence into Western Australia, prompted a study of the molecular epidemiology of this Australian mosquito-borne alphavirus. The nucleotide sequence of a 500-basepair region of the 3' end of the envelope (E2) gene of the prototype BF virus strain (BH2193) was compared with other members of the alphavirus genus, and to a panel of isolates of BF virus collected more for than 20 years from different geographic regions of Australia. The BF virus was shown to be genetically distinct from other members of the alphavirus genus. A high degree of sequence homology (98-100%) was found between the BF isolates, with no evidence of geographic or temporal divergence. This nucleotide homogeneity was similar to that observed with other Australian mosquito-borne viruses with avian vertebrate hosts, such as Sindbis, Murray Valley, and Kunjin viruses, but it contrasts to the heterogeneity reported for Ross River virus, an alphavirus with mammalian vertebrate hosts.