LSDV126 gene based molecular assays for specific detection and characterization of emerging Lumpy Skin Disease virus.

Lumpy skin disease (LSD) is a highly infectious and economically important viral disease, which is currently emerging in the Indian subcontinent. LSD is caused by Lumpy Skin Disease Virus (LSDV) under the genus Capripoxvirus and the family Poxviridae. Since its first incursion in India in the year 2019, the virus is rapidly disseminating through different means like direct contact, fomites and mainly by blood-feeding insects. As the disease has never been reported from India or neighbouring countries, there is a lack of planning and preparatory measures in terms of diagnostics and vaccines to control the disease. In the absence of any homologous vaccine, a live attenuated heterologous goat pox vaccine (Uttarkashi strain) is now being widely used in the country for the prevention of LSDV infection. Use of live attenuated goat pox virus vaccine necessitates the availability of an assay which could specifically detect and differentiate LSDV from goat pox virus. In this study, nucleotide sequences of LSDV126 gene encoding extracellular enveloped virus protein of circulating LSDV and goat pox virus were determined and analyzed. Deletion of 27 nt tandem repeats was observed in LSDV in comparison to goat pox and LSDV vaccine viruses. The deletion region was targeted for designing primers specific to LSDV, but not goat pox virus. A novel isothermal polymerase spiral reaction (PSR) was optimized as pen side diagnostic for prompt and sensitive detection of genomic DNA of LSDV. The assay was found to be highly sensitive and specific when compared to the real-time PCR. The assay was found to be specifically detecting only LSDV but not the goat pox virus. The limit of detection was identified as 9 × 10-6 ng of positive DNA. The assay will provide a point of care tool that will be a boon for the successful control of LSD in India.

Isolation of Reticuloendotheliosis Virus from Chorio-allantoic Membrane of SPF Chicken Eggs inoculated with Fowl Pox Virus.

Fowl Pox Viruses (FPV) infect chickens and turkeys giving rise to pock lesions on various body parts like combs, wattles, legs, shanks, eyes, mouth etc. The birds, affected with FPV, also show anemia and ruffled appearance which are clinical symptoms of Reticuloendotheliosis. Interestingly, the field strains of FPV are integrated with the provirus of Reticuloendotheliosis Virus (REV). Due to this integration, the infected birds, upon replication of FPV, give rise to free REV virions, causing severe immunosuppression and anemia. Pox scabs, collected from the infected birds, not only show positive PCR results upon performing FPV-specific 4b core protein gene PCR but also show positive results for the PCR of REV-specific env gene and FPV-REV 5'LTR junction. Homogenized suspension of the pock lesions, upon inoculating to the Chorio-allantoic Membrane (CAM) of 10 days old specific pathogen-free embryonated chicken eggs, produces characteristic pock lesions in serial passages. But the lesions also harbor REV mRNA or free virion, which can be identified by performing REV-specific env gene PCR using REV RNA from FPV-infected CAMs. The study suggests successful replication and availability of REV mRNA and free virion alongside the FPV virus, although the CAM is an ill-suited medium for any retroviral (like REV) growth and replication.

Genetic studies of terminal regions of vaccine and field isolates of capripoxviruses.

Sheeppox and goatpox are two of the most important diseases associated with significant economic loss and impact on animal trade. In spite of the use of vaccines, outbreaks are being reported on several occasions. Therefore, deciphering the host specificity and virulence of sheeppox virus (SPPV) and goatpox virus (GTPV) is important in developing effective vaccines. It is opined that genes located in the terminal regions play a major role in determining host range and/or virulence. In the present study, nine isolates (6 GTPV and 3 SPPV; included both vaccine and virulent viruses) were genetically characterized by targeting 11 genes (7 host-range and 4 virulence genes) which are located in the terminal regions of capripoxviruses. In the genetic analyses, it was observed that there are several nucleotide and amino acid signatures which are specific for either SPPV or GTPV. However, surprisingly, none of the 11 genes could be able to differentiate the vaccine and field viruses of GTPV and SPPV. Our study indicates that the genes of the terminal regions may have a role in determining the host-specificity but the involvemet in determinatin of virulence/attenuation is not certain at least for the isolates used in the current study. Therefore, it is likely that some other genes located in terminal/central regions may also play a role in determination of virulence and pathogenesis which needs to be confirmed by whole-genome sequencing of several vaccine and virulent viruses.

Isolation and Characterization of Bluetongue Virus Recovered from Blood Samples by Immunoaffinity Purification.

An immunoaffinity chromatography (IAC) method was optimized for the selective capture of bluetongue virus (BTV) from blood samples and isolation of the virus in cell culture. The antibody against BTV core particles (lacking the outer capsid proteins VP2 and VP5) was used for the optimization of IAC technique. The antibody against BTV core particle was conjugated with Protein A-virus complex and the complex was dissociated using elution buffer (4 M MgCl2 with 75 mM HEPES, pH 6.5). The optimized IAC method specifically purified the BTV without capturing other commonly infecting small ruminant's viruses like gaotpox virus (GTPV), sheeppox virus (SPPV), Peste des petits ruminants virus (PPRV) and Foot and mouth disease virus (FMDV). The blood samples (n = 22), positive for BTV antigen in sandwich-ELISA were attempted for virus isolation in the BHK-21 cell using the optimized IAC method. A total of seven BTV were isolated by selective capturing of the virion particles. The isolated viruses were characterized by RNA-PAGE, sequence analysis and serum neutralization test (SNT). Electropherotypic analysis of viral dsRNA in the RNA-PAGE revealed the presence of ten dsRNA segments characteristic of BTV. Out of seven isolates, four isolates were identified as BTV-1 and three isolates were identified as BTV-16 based on nucleotide sequences of segment-2. Phylogenetic analysis of segment-2 nucleotide sequence segregated BTV-1 and BTV-16 isolates to monophyletic cluster at close proximity to other eastern topotype. In SNT, hyperimmune serum (HIS) against BTV-1 neutralized the four BTV-1 isolates up to a titer > 256 and HIS against BTV-16 neutralized the three BTV-16 isolates up to a titer > 128. The IAC technique will be useful for the selective capture of BTV from mixed infection (BTV with other small ruminant's viruses) and isolation from blood sample having low viral load by enrichment.

Genetic and phylogenetic analysis of the outer capsid protein genes of Indian isolates of bluetongue virus serotype-16.

AIM: The aim of the study was to characterize bluetongue virus serotype 16 (BTV-16), recently isolated from different states of India. The evolutionary relationship of newly isolated BTV-16 and previously reported Indian and global BTV-16 isolates were compared using molecular analysis. MATERIALS AND METHODS: In the present study, five (n=5) BTV-16 isolates were used to amplify gene segment-2 and segment-6 encoding the outer capsid proteins VP2 and VP5, respectively. The amplified products were purified and sequenced by the Sanger sequencing method. The phylogenetic relationship and nucleotide identity of all five BTV-16 isolates were compared with previously reported Indian and global BTV-16 isolates. Nucleotide sequence data were aligned using the CLUSTAL W algorithm implemented in the MegAlign of DNASTAR program package (MegAlign 5.00, DNASTAR Inc., Madison, USA). Phylogenetic analyses were carried out using MEGA version 6.0 software with the best nucleotide substitution model. RESULTS: Phylogenetic analysis based on the VP2 and VP5 encoding genes, segregates Indian BTV-16 isolates in a distinct cluster with proximity to the Eastern topotype. Indian isolates make a monophyletic cluster with Eastern topotypes with Western topotype BTV-16 (BTV-16/NIG/AJ586694) occupying a separate cluster. Indian isolates were found to share 91.5%-97.5% and 96.5%-98.9% identity at the nucleotide and deduced amino acid (aa) level, respectively, to the global BTV-16 isolates. There is a high degree of variation with the Nigerian isolate with 27.0-27.7% and 26.0-26.9% at the nucleotide and aa sequence level, respectively. These data suggest that Indian BTV-16 isolates might have evolved separately within the Eastern BTV topotype. CONCLUSION: Phylogenetic analyses and nucleotide identity of BTV-16 isolates at the VP2 and VP5 gene encoded level indicate that isolates used in the present study might have evolved from a common Eastern topotype ancestor. The data presented in this study will be helpful for future selection of reference strains in a serological and molecular epidemiology study.

A competitive ELISA for detection of group specific antibody to bluetongue virus using anti-core antibody.

Bluetongue virus (BTV) is transmitted by biting midges, which infects domestic and wild ruminants. In present study, a competitive enzyme-linked immunosorbent assay (C-ELISA) for the detection of serogroup-specific antibodies against VP7 protein of BTV has been developed. The assay measures the competition between a group specific antibody against core protein of BTV and a test serum to an optimized concentration of BTV recombinant-VP7 (r-VP7) antigen. Serum samples (n = 895) collected from small and large ruminants were used to optimize the C-ELISA. Percent inhibition (PI) values were used for estimation of the cut-off value for the C-ELISA. On receiver operator characteristic (ROC) analysis, different cut-off values along with their diagnostic sensitivity (DSn) and diagnostic specificity (DSp) were obtained. Among these, >50% PI value was accepted as cut-off at which DSn and Dsp was achieved as 97.6% and 98.0% respectively, at >95% confidence interval. Results show the present C-ELISA assay described to be sensitive, specific and reliable and could be adopted for serological investigation of small and large ruminants.

Purification of infective bluetongue virus particles by immuno-affinity chromatography using anti-core antibody.

An immuno-affinity chromatography technique for purification of infective bluetongue virus (BTV) has been descried using anti-core antibodies. BTV anti-core antibodies (prepared in guinea pig) were mixed with cell culture-grown BTV-1 and then the mixture was added to the cyanogens bromide-activated protein-A Sepharose column. Protein A binds to the antibody which in turn binds to the antigen (i.e. BTV). After thorough washing, antigen-antibody and antibody-protein A couplings were dissociated with 4M MgCl2, pH6.5. Antibody molecules were removed by dialysis and virus particles were concentrated by spin column ultrafiltration. Dialyzed and concentrated material was tested positive for BTV antigen by a sandwich ELISA and the infectivity of the chromatography-purified virus was demonstrated in cell culture. This method was applied for selective capture of BTV from a mixture of other viruses. As group-specific antibodies (against BTV core) were used to capture the virus, it is expected that virus of all BTV serotypes could be purified by this method. This method will be helpful for selective capture and enrichment of BTV from concurrently infected blood or tissue samples for efficient isolation in cell culture. Further, this method can be used for small scale purification of BTV avoiding ultracentrifugation.

Segment-2 sequencing and cross-neutralization studies confirm existence of a neutralization resistant VP2 phenotypic variant of bluetongue virus serotype 1 in India.

Segment-2 (seg-2) of a bluetongue virus seropype-1 (BTV-1) isolate WGV104/08/Ind of Indian origin was sequenced and its neutralization behavior was studied to understand the antigenic similarity and relationship with other BTV-1 isolates. Multiple alignments of the coding region of seg-2 of WGV104/08/Ind revealed 97.6-99.0% and 97.2-98.4% similarity with other Indian BTV-1 isolates at nucleotide and deduced amino acid sequence level respectively. Several conservative and non-conservative substitutions were observed on the deduced VP2 amino acid sequence of WGV104/08/Ind. Non-conservative substitution of Lys119Glu on the B-cell epitope and Arg330Gly on the neutralizing epitope of VP2 of this isolate was observed. Using isolate-specific heterologous hyperimmune serum (HIS) the phenotypic antigenic relationship (r) was determined between WGV104/08/Ind and other Indian BTV-1 isolates which ranged from 0.092 to 0.208. The relationship score ranged from 0.203 to 0.295 when neutralization behavior of other Indian BTV-1 isolates was studied with the HIS of WGV104/08/Ind. Antigenic similarity (R) between WGV104/08/Ind and other Indian BTV-1 isolates was estimated from a reciprocal cross-neutralization study and ranged from 14.70% to 24.80% indicating existence of major subtype antigenic divergence and neutralization resistant behavior of WGV104/08/Ind.

Bluetongue virus serotype-1 in goats in the Pithoragarh area of Uttarakahand, India.

This short communication reports the results of a bluetongue sero-surveillance conducted in the Pithoragarh hills of Uttarakhand in India during the autumn of 2011. Unclotted blood and serum samples were collected from 51 goats for detection of bluetongue virus (BTV) antigen and antibodies. Of the 51 collected samples, 18 (35%) were positive to an indirect ELISA and 33 (64%) resulted positive to a BTV ELISA antigen. From a strong antigen-positive blood sample, a BTV was isolated (named as PTG-13) on cell culture and was subsequently confirmed as BTV-1 by RT-PCR and partial sequencing of genome segment-2. The goat serum samples were found to contain high titer of neutralising antibodies against BTV-23, nonetheless the virus could not be isolated. Interestingly, no neutralizing antibodies were detected against PTG-13 or other BTV-1 isolate, which suggests that sampling was probably done before the development of neutralizing antibodies against PTG-13 virus in the host. Isolation of BTV-1 (PTG-13) and presence of BTV-23 neutralizing antibodies in serum samples indicate that goats were probably infected with BTV-1 and 23 in different periods.

Detection of fowl poxvirus integrated with reticuloendotheliosis virus sequences from an outbreak in backyard chickens in India.

Fowl poxvirus (FPV) infection was observed in unvaccinated backyard chickens. A total of 15 birds were affected in a flock of 37. Pock lesions were observed on the comb, eyelids, beak and wattles. The birds appeared sick with roughened feathers and stunted growth. No mortality was recorded. DNA was isolated from scabs and polymerase chain reaction (PCR) was performed to amplify the 4b core protein gene of FPV, the envelope (env) gene of reticuloendotheliosis virus (REV) and the region of FPV flanking REV 5´ long terminal repeat (LTR). Correct-size PCR products of 578 bp, 807 bp and 370 bp, respectively, were observed in agarose gel electrophoresis. Sequence analysis of these products suggests that the virus was an FPV with a genome containing an integrated near full-length REV provirus. Given the fact that REV has been associated with immunosuppression, its presence in the genome of FPV appears to play an important role in the pathogenesis of fowl pox and presumably prolongs persistence of FPV in bird populations. In the present case, fowl pox has been observed to have persisted for about three years in fowl that were reared in backyard systems in villages.

Isolation of bluetongue virus serotype 1 (BTV-1) from goats and its phylogenetic relationship to other BTV-1 isolates worldwide based on full-length sequence of genome segment-2.

Eight bluetongue viruses (BTV) were isolated in BHK-21 cell culture from blood of goats suffering from peste des petits ruminants. These viruses were identified as BTV serotype 1 (BTV-1) by RT-PCR using VP2-gene-based primers coupled with sequencing of the PCR products. All of the isolates showed similar genome migration profile in 8% polyacrylamide gel electrophoresis. The genome segment-2 (seg-2) of one isolate (MKD18/India/2008) was amplified piecemeal by overlapping PCR, and the products were sequenced to obtain full-length seg-2. Phylogenetic analysis based on the seg-2 sequence revealed that MKD18 is closely related to Australian BTV-1 isolates, with 86.3-86.8% nucleotide identity. Phylogenetic analysis based on the partial sequence of seg-2 (541 bp, nucleotides 1,304-1,844) showed that the Indian BTV-1 isolates, namely, MKD18, Avikanagar, Sirsa-3 and Chennai, are very closely related to each other, with more than 99.6% nucleotide identity. Although a high degree of similarity exists, the Indian BTV-1 isolates collected over the past 25 years should be studied to demonstrate the co-existence of different VP2 antigenic profiles.

Segment-2 sequence analysis and cross-neutralization studies on some Indian bluetongue viruses suggest isolates are VP2-variants of serotype 23.

Sequence analysis of segment 2 (seg-2) of three Indian bluetongue virus (BTV) isolates, Dehradun, Rahuri and Bangalore revealed 99% nucleotide identity amongst them and 96% with the reference BTV 23. Phylogenetic analysis grouped the isolates in 'nucleotype D'. The deduced amino acid (aa) sequence of the Bangalore isolate showed a high variability in a few places compared to other isolates. B-cell epitope analyses predicted an epitope that is present exclusively in the Bangalore isolate. Two-way cross serum neutralization confirmed that Bangalore isolate is antigenically different from the other two isolates. The results of this study suggest that these three isolates are VP2 variants of BTV 23. This signifies that non-cross-neutralizing variants of the same BTV serotype should be included in vaccine preparation.

A polyclonal antibody-based sandwich ELISA for the detection of bluetongue virus in cell culture and blood of sheep infected experimentally.

A polyclonal antibody-based sandwich ELISA (s-ELISA) was developed for the detection of bluetongue viruses (BTV) in cell culture lysates and blood samples of sheep infected experimentally. Rabbit antiserum to purified BTV particles and guineapig antiserum to core particles were used as capture antibody and detection antibody respectively. The assay has detected several of the BTV serotypes isolated in India so far. Other common viruses of small ruminants did not cross-react in the assay. The analytical sensitivity of the assay was estimated to be between 10(2.4) and 10(2.6)TCID(50)/ml with different serotypes of BTV. The sensitivity was compared with that of the reverse transcription polymerase chain reaction (RT-PCR) and the latter was found to be at least 100 times more sensitive. In the infected sheep, BTV antigen(s) was detected in blood as early as on 5-day post-infection (dpi) till 35 dpi. The assay may be useful for testing large number of samples in a very short time.

Surveillance of bluetongue virus antibody in goats using a recombinant VP7-based indirect ELISA in the coastal saline area of West Bengal, India.

The authors describe the serological surveillance of bluetongue virus (BTV) group-specific antibody in goats of the coastal saline (Sunderban) area of West Bengal, India. A recombinant viral protein 7 (rVP7)-based indirect enzyme-linked immunosorbent assay (ELISA) was used to detect the antibody in sera. The bacterially expressed rVP7 was purified by affinity chromatography. The diagnostic performance of the assay was assessed by comparing it to the commercially available previously validated competitive ELISA. Using the control and 1 202 test sera, the cut-off value, sensitivity and specificity as well as other performance characteristics e.g. the Youden index, efficiency, positive and negative predictive value and prevalence were estimated. Field-collected goat sera (n = 1 202) were tested and a serological prevalence rate of 47% was observed in the study area.

A sandwich ELISA for the detection of bluetongue virus in cell culture using antiserum against the recombinant VP7 protein.

A polyclonal antibody-based sandwich enzyme-linked immunosorbent assay (s-ELISA) was developed for the detection of bluetongue virus (BTV). The test used antiserum against BTV and antiserum against the bluetongue (BT) core protein. The antiserum against the virus was used as a capture antibody and the antiserum against the protein was used for detection. In this study, antiserum to recombinant viral protein 7 (rVP7) was used as a detection antibody in place of anti-core antiserum. The assay was used to detect the BT serotypes found in India, namely: 1, 2, 9, 15, 18 and 23. The modified sandwich assay was able to detect BTV serotypes in cell culture supernatants. The use of anti-rVP7 antiserum as the detection antibody avoids the tedious and expensive purification of BTV core particles.