Analysis of Newcastle disease virus quasispecies and factors affecting the emergence of virulent virus.

Genome sequence analysis of a number of avirulent field isolates of Newcastle disease virus revealed the presence of viruses (within their quasispecies) that contained virulent F0 sequences. Detection of these virulent sequences below the ~1% level, using standard cloning and sequence analysis, proved difficult, and thus a more sensitive reverse-transcription real-time PCR procedure was developed to detect both virulent and avirulent NDV F0 sequences. Reverse-transcription real-time PCR analysis of the quasispecies of a number of Newcastle disease virus field isolates, revealed variable ratios (approximately 1:4-1:4,000) of virulent to avirulent viral F0 sequences. Since the ratios of these sequences generally remained constant in the quasispecies population during replication, factors that could affect the balance of virulent to avirulent sequences during viral infection of birds were investigated. It was shown both in vitro and in vivo that virulent virus present in the quasispecies did not emerge from the "avirulent background" unless a direct selection pressure was placed on the quasispecies, either by growth conditions or by transient immunosuppression. The effect of a prior infection of the host by infectious bronchitis virus or infectious bursal disease virus on the subsequent emergence of virulent Newcastle disease virus was examined.

Sequence variation in the Newcastle disease virus genome.

Full-length genome sequences of five virulent and five avirulent strains of Newcastle disease virus isolated between 1998 and 2002 in Victoria and New South Wales, Australia were determined. Comparisons between these strains revealed that coding sequence variability in the haemagglutinin-neuraminidase (HN), matrix (M) and phosphoprotein (P) gene sequences appeared to be more variable than in the fusion (F), nucleocapsid (N) and RNA dependent-RNA replicase (L) genes. Sequence analysis of a number of other isolates made during the recent virulent NDV outbreaks, also identified the presence of a number of variants with altered F gene cleavage sites, which resulted in altered biological properties of those viruses. Quasispecies analysis of a number of field isolates indicated the presence of virulent virus in one particular isolate. Gene sequence analysis of the progenitor virus isolated in 1998 showed very little sequence variation when compared to that of a progenitor-like virus isolated in 2001, demonstrating that in the field, viral genome sequence variation appears to be biologically restricted to that of a consensus sequence.

Characterisation of an Australian bat lyssavirus variant isolated from an insectivorous bat.

In 1996 a variant lyssavirus was isolated from an insectivorous bat (yellow bellied, sheath tail bat-Saccolaimus flaviventris) in Australia. The nucleocapsid protein (N), matrix protein (M), phosphoprotein (P), glycoprotein (G) and polymerase (L) genes of the Australian bat lyssavirus (ABL) insectivorous isolate were compared with that previously described from a frugivorous bat (Pteropus sp.), and showed sequence divergence at both the nucleotide and amino acid sequence level of 20% and 4-12%, respectively. Comparison of deduced protein sequences of ABL isolates from Pteropus and insectivorous bats, showed that viral isolates were homologous and varied by only a few percent. However, these viruses separated into two distinct clades; those isolated from Pteropus or those from Saccolaimus flaviventris bats, when comparisons were made at the nucleotide level. Nucleoprotein sequence comparisons also showed insectivorous isolates to be of the same putative genotype (genotype 7) as that isolated from frugivorous bats. Immediately after the isolation of ABL from an insectivorous bat, the first human case of ABL infection was identified. PCR and sequence analysis done on cerebrospinal fluid, brain and virus isolated from fresh brain tissue of this human case, was consistent with this infection originating from an insectivorous bat. Monoclonal antibody profiling studies of the virus isolated from the human brain tissues supported this conclusion. Sequence comparisons done on the nucleocapsid (N) gene of insectivorous or frugivorous bats showed no geographic associations between isolates but did delineate between the variants of ABL in Australia.

A simple approach for preparing real-time PCR positive reaction controls for rare or emerging viruses.

BACKGROUND: Laboratories often have difficulties obtaining positive control material for polymerase chain reaction (PCR) diagnosis of rare or emerging viruses. This is particularly problematic during outbreaks caused by emerging infectious diseases, when delays can impede the public health response. OBJECTIVES: The aim of this study was to develop a simple approach for preparing real-time PCR positive reaction controls for rare or emerging viruses. STUDY DESIGN: We describe a universal method for preparing PCR positive reaction controls (Uni-Control), which uses two synthetic control oligonucleotides and irrelevant viral nucleic acid as an initiator template. In this study, we prepared Uni-Controls for novel influenza A(H1N1) and human metapneumovirus (HMPV) RT-PCR assays. Parainfluenza type 2 virus RNA and equine herpes virus DNA were used as initiator templates. RESULTS: Using the Uni-Controls, characteristic sigmoidal real-time PCR amplification curves were observed in the influenza A(H1N1) and HMPV RT-PCR assays. Comparable cycle threshold values were observed in both assays when using the same concentration of the initiator template. CONCLUSIONS: The Uni-Control method for preparing real-time PCR positive reaction controls provides an interim measure by which real-time PCR assays can be rapidly introduced for rare or emerging viruses in the absence of wild-type control material. The system is versatile and we propose can readily be adapted to almost any viral template.

Detection of novel influenza A(H1N1) virus by real-time RT-PCR.

Accurate and rapid diagnosis of novel influenza A(H1N1) infection is critical for minimising further spread through timely implementation of antiviral treatment and other public health based measures. In this study we developed two TaqMan-based reverse transcription PCR (RT-PCR) methods for the detection of novel influenza A(H1N1) virus targeting the haemagglutinin and neuraminidase genes. The assays were validated using 152 clinical respiratory samples, including 61 Influenza A positive samples, collected in Queenland, Australia during the years 2008 to 2009 and a further 12 seasonal H1N1 and H3N2 influenza A isolates collected from years 2000 to 2002. A wildtype swine H1N1 isolate was also tested. RNA from an influenza A(H1N1) virus isolate (Auckland, 2009) was used as a positive control. Overall, the results showed that the RT-PCR methods were suitable for sensitive and specific detection of novel influenza A(H1N1) RNA in human samples.