Design and testing of multiplex RT-PCR primers for the rapid detection of influenza A virus genomic segments: Application to equine influenza virus.

The avian influenza A virus causes respiratory infections in animal species. It can undergo genomic recombination with newly obtained genetic material through an interspecies transmission. However, the process is an unpredictable event, making it difficult to predict the emergence of a new pandemic virus and distinguish its origin, especially when the virus is the result of multiple infections. Therefore, identifying a novel influenza is entirely dependent on sequencing its whole genome. Occasionally, however, it can be time-consuming, costly, and labor-intensive when sequencing many influenza viruses. To compensate for the difficulty, we developed a rapid, cost-effective, and simple multiplex RT-PCR to identify the viral genomic segments. As an example to evaluate its performance, H3N8 equine influenza virus (EIV) was studied for the purpose. In developing this protocol to amplify the EIV eight-segments, a series of processes, including phylogenetic analysis based on different influenza hosts, in silico analyses to estimate primer specificity, coverage, and variation scores, and investigation of host-specific amino acids, were progressively conducted to reduce or eliminate the negative factors that might affect PCR amplification. Selectively, EIV specific primers were synthesized with dual priming oligonucleotides (DPO) system to increase primer specificity. As a result, 16 primer pairs were selected to screen the dominantly circulating H3N8 EIV 8 genome segments: PA (3), PB2 (1), PA (3), NP (3), NA8 (2), HA3 (1), NS (1), and M (2). The diagnostic performance of the primers was evaluated with eight sets composing of four segment combinations using viral samples from various influenza hosts. The PCR results suggest that the multiplex RT-PCR has a wide range of applications in detection and diagnosis of newly emerging EIVs. Further, the proposed procedures of designing multiplex primers are expected to be used for detecting other animal influenza A viruses.

Assessment of the proportion of under-reporting during the 2007 equine influenza outbreak in New South Wales, Australia.

During the 2007 equine influenza (EI) outbreak in Australia, there was no objective information about the possible under-reporting of cases by horse owners either so that they would avoid movement restrictions or because of their inability to detect infection. This investigation aimed to estimate the proportion of under-reporting during the outbreak based on the results of surveillance undertaken in conjunction with vaccination. The results provided improved estimates of morbidity during the outbreak and indicated the level of under-reporting likely to occur in future outbreaks of other infectious diseases in horses in Australia.

Multiplex immunoassays of equine virus based on fluorescent encoded magnetic composite nanoparticles.

A new detection format for multiplexed analysis based on fluorescent encoded magnetic composite nanoparticles is presented. Two kinds of virus were analyzed by this new method: equine influenza virus (EIV) and equine infectious anemia virus (EIAV). Firstly, EIV antigen and EIAV antigen were conjugated to two kinds of fluorescent encoded magnetic composite nanoparticles, while the green-emitting CdTe quantum dots (QDs) were attached to the antibody of EIV and EIAV. Then both green-emitting CdTe QD-labeled antibodies and antigens labeled with fluorescent encoded magnetic composite nanoparticles were used to form an immunoassay system for the detection of EIV and EIAV antigens. The method is time-saving and has higher sensitivity (1.3 ng mL(-1) for EIV antigens and 1.2 ng mL(-1) for EIAV antigens) than the conventional methods. A competitive immunoassay method based on this analysis system was used to detect EIV and EIAV antigens in spiked serum samples with satisfactory results.