Genetic characterization of bluetongue virus serotype 9 isolates from India.

Recent incursions of bluetongue virus (BTV) into previously naive geographical areas have emphasised the need to better understand virus movement and epidemiology. Several bluetongue virus (BTV) serotypes are known to exist in India, and some serotype viruses have been isolated. However, the complete genome of not a single isolate is available to date. We report the complete genome sequence of one, and partial sequences of three other Indian isolates of BTV-9. Evolutionary relationships with segment-2 and -6 sequences of BTV isolates around the world, deduced using four different phylogenetic analyses and a similarity programme, show that BTV-9 (Eastern), BTV-9 (Western), and BTV-5 form a triad of equidistant, genetically distinct groups of viruses. The Indian BTV-9 isolates were closely related to Mediterranean and European BTV-9 isolates (Eastern topotype) based on segment-2 and -6 sequences. By contrast, segment-5 analyses clustered the Indian BTV-9 isolates with South African BTV-3 reference strain (98% identity), which belongs to one of the Western types. These results have implications on BTV origin and movement, genotyping, serotyping, and vaccine design.

Standardization and application of real-time polymerase chain reaction for rapid detection of bluetongue virus.

AIM: The present study was designed to standardize real-time polymerase chain reaction (PCR) for detecting the bluetongue virus from blood samples of sheep collected during outbreaks of bluetongue disease in the year 2014 in Andhra Pradesh and Telangana states of India. MATERIALS AND METHODS: A 10-fold serial dilution of Plasmid PUC59 with bluetongue virus (BTV) NS3 insert was used to plot the standard curve. BHK-21 and KC cells were used for in vitro propagation of virus BTV-9 at a TCID50/ml of 105 ml and RNA was isolated by the Trizol method. Both reverse transcription-PCR and real-time PCR using TaqMan probe were carried out with RNA extracted from virus-spiked culture medium and blood to compare the sensitivity by means of finding out the limit of detection (LoD). The results were verified by inoculating the detected and undetected dilutions onto cell cultures with further cytological (cytopathic effect) and molecular confirmation (by BTV-NS1 group-specific PCR). The standardized technique was then applied to field samples (blood) for detecting BTV. RESULTS: The slope of the standard curve obtained was -3.23, and the efficiency was 103%. The LoD with RT-PCR was 8.269E×103 number of copies of plasmid, whereas it was 13 with real-time PCR for plasmid dilutions. Similarly, LoD was determined for virus-spiked culture medium, and blood with both the types of PCR and the values were 103 TCID 50/ml and 104 TCID 50/ml with RT-PCR and 10° TCID 50/ml and 102 TCID 50/ml with real-time PCR, respectively. The standardized technique was applied to blood samples collected from BTV suspected animals; 10 among 20 samples were found positive with Cq values ranging from 27 to 39. The Cq value exhibiting samples were further processed in cell cultures and were confirmed to be BT positive. Likewise, Cq undetected samples on processing in cell cultures turned out to be BTV negative. CONCLUSION: Real-time PCR was found to be a very sensitive as well as reliable method to detect BTV present in different types of samples, including blood samples collected from BTV-infected sheep, compared to RT-PCR. The LoD of BTV is likely influenced by sample type, possibly by the interference by the other components present in the sample.