Bluetongue (BT) is an arthropod-borne viral disease mostly of sheep. Bluetongue virus (BTV) is a segmented double-stranded RNA virus belonging to the genus Orbivirus of family Reoviridae and is transmitted by midges belonging to Culicoides spp. The disease is endemic in the tropics and subtropics, and the incidence is high in southern India. Twenty-six serotypes of BTV have been reported worldwide. Although most of the serotypes have been reported in India, information regarding currently circulating serotypes is essential to develop control programs. Both serological assays and nucleic acid-based assays have been used for typing BTV. Segment 2, which codes for the outer capsid protein VP2, is the target for PCR-based typing; however, the VP2 sequence diversity among viruses belonging to the same serotype but isolated from different geographical areas makes it essential to develop geographical based reagents. In this study, reverse transcription PCR was developed based on sequences of Indian isolates of BTV (serotypes 1, 2, 9, 10, 12, 16, 21 and 23), and this was applied to type 52 isolates obtained during the last decade. It was found that multiple serotypes circulate, with involvement of more than one serotype infecting individual animals and herds over a period in a given area. Detection of circulating serotypes and estimation of herd immunity against different serotypes of BTV may provide important information for predicting the distribution of these serotypes and inclusion of serotypes in vaccines.
AimThe 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 MethodsA 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.ResultsThe 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.ConclusionReal-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.
Bluetongue (BT) is a Culicoides-borne disease caused by several serotypes of bluetongue virus (BTV). Similar to other insect-borne viral diseases, distribution of BT is limited to distribution of Culicoides species competent to transmit BTV. In the tropics, vector activity is almost year long, and hence, the disease is endemic, with the circulation of several serotypes of BTV, whereas in temperate areas, seasonal incursions of a limited number of serotypes of BTV from neighbouring tropical areas are observed. Although BTV is endemic in all the three major tropical regions (parts of Africa, America and Asia) of the world, the distribution of serotypes is not alike. Apart from serological diversity, geography-based diversity of BTV genome has been observed, and this is the basis for proposal of topotypes. However, evolution of these topotypes is not well understood. In this study, we report the isolation and characterization of several BTV-4 isolates from India. These isolates are distinct from BTV-4 isolates from other geographical regions. Analysis of available BTV seg-2 sequences indicated that the Australasian BTV-4 diverged from African viruses around 3,500 years ago, whereas the American viruses diverged relatively recently (1,684 CE). Unlike Australasia and America, BTV-4 strains of the Mediterranean area evolved through several independent incursions. We speculate that independent evolution of BTV in different geographical areas over long periods of time might have led to the diversity observed in the current virus population.
Aim: The current study was designed to understand the infection kinetics and antibody responses of major circulating serotypes of bluetongue virus (BTV) in India, i.e., BTV-4 and BTV-16 through experimental infection and superinfection of Deccani sheep, a popular breed of sheep found in the southern states of India. Materials and Methods: Experimental infection with 106 TCID50/ml BTV-4 was followed by superinfection with BTV-16 and vice versa. Along with observing for clinical signs and immunological responses in the experimentally infected sheep, the effect of infection of one specific serotype on the outcome of superinfection with a different serotype was also studied. Results: Certain interesting findings have been made in the course of experimental infection, such as prominent signs of infection in BTV-4 infection, mild or no clinical signs in BTV-16-infected and superinfected animals, and non-seroconversion of one of the BTV-16-superinfected animals. In addition, BTV was isolated from infected sheep in all the experimental conditions except BTV-16 superinfection. Furthermore, it was observed that immune response in the form of type-specific antibodies was slower with BTV-16 superinfection. Conclusion: Superinfection of a sheep with more than one serotype of BTV is a common phenomenon in BT endemic countries like India. Such situation was replicated in an experimental infection in the current study, and the findings to our knowledge are first of a kind and are likely to aid in unfolding the newer aspects of BTV pathogenesis and virulence.
India is enzootic for bluetongue (BT), a predominant disease of small ruminants. The most important task in the control of disease is rapid and sensitive detection of virus. The present study was undertaken to standardize immunofluorescence (IFT) and immunoperoxidase tests (IPT) employing BTV serogroup specific VP7 monoclonal antibodies (MAbs), polyclonal homologous, and polyclonal heterologous antisera against specific serotypes of BTV for detection of BTV antigen. Serial tenfold dilutions of BTV-9 were tested for limit of detection (LoD) of IFT, IPT, and molecular assays by using MAbs against VP7, homologous anti-BTV-9 serum, and heterologous anti-BTV-16 serum. LoD of IFT was found to be 101 TCID50/mL using MAbs against VP7, anti BTV-9 serum, and anti BTV-16 serum. LoD of IPT was found to be 101 TCID50/mL, 102 TCID50/mL, and 102 TCID50/mL using MAbs against VP7, anti BTV-9 serum and anti BTV-16 serum, respectively. LoD of RT-PCR was 101 TCID50/mL and that of real time PCR was 100 TCID50/mL. This standardized assay was then applied for BTV detection in BTV suspected field samples collected from BT outbreaks followed by confirmation with virus isolation and NS3 group specific PCR. The current study shows that IFT and IPT are specific tests for group specific BTV identification. For IFT, monoclonal and polyclonal (homologous and heterologous) source of antibodies had similar sensitivity in the ability of BTV detection; whereas the most sensitive mode of detection by IPT was with MAbs.
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