Development and validation of a universal S-segment-based real-time RT-PCR assay for the detection of Simbu serogroup viruses.

Simbu serogroup viruses induce acute clinical diseases and abnormal courses of pregnancies in livestock. In Israel, two members of this serogroup, namely Akabane virus (AKAV) and Shuni virus (SHUV), were recently detected and, in Europe, Schmallenberg virus (SBV) poses a threat to ruminants. To address this emerging problem, a universal S-segment-based real-time RT-PCR assay (Uni-S) for the detection of Simbu serogroup viruses was established, which, additionally, enabled species identification of the detected viruses by subsequent sequencing. The newly developed probe-based PCR system enabled reliable detection of a comprehensive panel of Simbu viruses. Furthermore, several SBV isolates and German field samples were tested by the new Uni-S system in comparison to a SBV-specific real-time RT-PCR and both assays exhibited equally high levels of sensitivities. Finally, co-circulation of AKAV and SHUV in Israel was confirmed by analyzing field samples using the Uni-S assay followed by sequence analysis of the positive samples. To validate the test specificity, blood and tissue samples from animals negative for Simbu viruses, preparations of genetically related viruses and additional ruminant pathogens were examined and all were found to be negative. In conclusion, the new assay enabled sensitive and rapid universal molecular detection of Simbu viruses and is expected to serve as a valuable method for infection diagnosis, especially in regions where several Simbu serogroup members circulate.

Clinical syndromes associated with the circulation of multiple serotypes of bluetongue virus in dairy cattle in Israel.

From 2008 to 2011, seven distinct bluetongue virus (BTV) serotypes (BTV-2, BTV-4, BTV-5, BTV-8, BTV-15, BTV-16 and BTV-24) have been identified to be circulating in diseased sheep and cattle in Israel. This paper describes the array of clinical manifestations caused by BTV in cattle in Israel. Each set of clinical manifestations has been categorised as a syndrome and six distinct clinical syndromes have been observed in dairy cattle: 'footrot-like syndrome', 'sore nose syndrome', 'subcutaneous emphysema syndrome', 'red/rough udder syndrome', 'bluetongue/epizootic haemorrhagic disease systemic syndrome' and 'maladjustment syndrome'.

Variability of NS1 proteins among H9N2 avian influenza viruses isolated in Israel during 2000-2009.

The main aims of the present study were to characterize NS1 protein from H9N2 avian influenza viruses (AIVs) isolated in Israel and to investigate the possibility to use NS1-based indirect ELISA. To achieve these purposes, the non-structural gene (NS1) of 79 AIVs of the H9N2 subtype isolated in Israel in 2000-2009 was sequenced and genetically analyzed. The phylogenetic analysis demonstrated that four distinct introductions of H9N2 occurred in Israel during this period. Analysis of the inferred amino acid sequences of the NS1 proteins showed high, about 10%, differences between viruses of the 3rd and 4th introductions. Antibodies against NS1 protein in immune sera were tested by means of indirect ELISA using recombinant NS1 as antigen. Immune sera were obtained from experimentally H9N2-infected chicken after infection on 4, 7, 10, 14, and 21 days. All sera from chickens experimentally infected with 3rd- or 4th-introduction AIV contained anti-NS1 antibodies that were detected by enzyme-linked immunosorbent assay (NS1-ELISA) even though the recombinant NS1 used as antigen for NS1-ELISA differed significantly in its amino acid sequences from the NS1 protein of AIV that caused infection in experimental birds. These findings indicate that the sites of the NS1 protein by which viruses belonging to 3rd and 4th introduction are out of antigenic epitope positions were responsible for the results of NS1-based iELISA.

Avian influenza virus H9N2 survival at different temperatures and pHs.

The H9N2 avian influenza virus (AIV) subtype has become endemic in Israel since its introduction in 2000. The disease has been economically damaging to the commercial poultry industry, in part because of the synergistic pathology of coinfection with other viral and/or bacterial pathogens. Avian influenza virus viability in the environment depends on the cumulative effects of chemical and physical factors, such as humidity, temperature, pH, salinity, and organic compounds, as well as differences in the virus itself. We sought to analyze the viability of AIV H9N2 strains at three temperatures (37, 20, and 4 C) and at 2 pHs (5.0 and 7.0). Our findings indicated that at 37 C AIV H9N2 isolate 1525 (subgroup IV) survived for a period of time 18 times shorter at 20 C, and 70 times shorter period at 4 C, as measured by a decrease in titer. In addition, the virus was sensitive to a lower pH (pH 5.0) with no detectable virus after 1 wk incubation at 20 C as compared to virus at pH 7.0, which was viable for at least 3 wk at that temperature. The temperature sensitivity of the virus corresponds to the occurrence of H9N2 outbreaks during the winter, and lower pH can greatly affect the viability of the virus.