Awadh Bihari Pandey

Cell-mediated immune response and cross-protective efficacy of binary ethylenimine-inactivated bluetongue virus serotype-1 vaccine in sheep

Bluetongue is a serious hemorrhagic disease of sheep, cattle and other ruminants causing economic losses worldwide. Recent invasion of multiple bluetongue virus serotypes (BTV) in various countries warrants immediate development of efficacious vaccine that targets more than one serotype. In the present study, the cross-protective efficacy of binary ethylenimine (BEI)-inactivated BTV-1 vaccine was evaluated in Indian native sheep against virulent heterologous BTV-23 serotype challenge. BTV-1 vaccination induced significant cell-mediated immunity (CMI) as determined by lymphoproliferative responses, and increased CD8 T cell, IL-2 and IFN-gamma responses. Both naïve and immunized sheep also showed increased CD4 T cell, IL-12 and IFN-alpha responses. Collectively, these data suggested that inactivated BTV-1 vaccine induced appreciable CMI and greatly reduced the severity of heterologous BTV-23 infection.

Immune responses and protective efficacy of binary ethylenimine (BEI)-inactivated bluetongue virus vaccines in sheep

Abbreviations: Al(OH)3, aluminium hydroxide; BEI, binary ethylenimine; BTV, bluetongue virus; CMI, cellmediated immune response; CPE, cytopathic effect; CRI, clinical reaction index; d.p.i., days post inoculation; DTH, delayed-type hypersensitivity; EHDV, epizootic haemorrhagic disease virus of deer; FIA, Freund’s incomplete adjuvant; PBS, phosphate-buffered saline; pfu, plaque-forming unit; PHA, phytohaemagglutinin; RBC, red blood cell

Frequency of group A rotavirus with mixed G and P genotypes in bovines: predominance of G3 genotype and its emergence in combination with G8/G10 types

The present study describes the genotypic distribution of rotaviruses (RVs) in an Indian bovine population with unexpectedly higher proportions of G3 alone or in combination of G8/G10. PCR-genotyping confirmed that 39.4% (13/33) of the prevalent RVs were the G3 type while 60.6% (20/33) were dual G3G10 or G3G8 types. P typing revealed that 93.9% (31/33) of the samples were P[11] while 6.1% (2/33) possessed a dual P[1]P[11] type. Sequence analysis of the VP7 gene from G3 strains viz. B-46, 0970, and BR-133 showed that these strains had sequence identities of 90.5% to 100% with other bovine G3 strains. The highest identity (98.9% to 100%) was observed with RUBV3 bovine G3 strains from eastern India. The G3 strains (B-46, 0970, and BR-133) showed 97.5% to 98.8% sequence homologies with the Indian equine RV strain Erv-80. Phylogenetic analysis demonstrated that G3 strains clustered with bovine RUBV3 and J-63, and equine Erv-80 G3. Overall, these results confirmed that the incidence of infection by RVs with the G3 genotype and mixed genotypes in the bovine population was higher than previously predicted. This finding reinforces the importance of constantly monitoring circulating viral strains with the G3 genotype in future surveillance studies.

Apoptosis and immuno-suppression in sheep infected with bluetongue virus serotype-23.

The role of apoptosis in pathogenesis of bluetongue (BT) has been suggested from various in vitro studies. However, to date, no clear data are available regarding BTV-induced apoptosis and its consequences in natural host, sheep. In the present study, bluetongue virus (BTV)-induced apoptosis was studied in sheep blood and splenic mononuclear cells by analyzing annexin(+)-propidium iodide(-) early apoptotic cells, DNA ladder pattern, and caspase-3 gene expression. The onset of apoptosis and lymphocyte depletion in viraemic phase and IFN-alpha response indicated the involvement of BTV and IFN-alpha in the pathogenesis of BT. The development of Pasteurella pneumonia in 4 of 7 infected sheep during the experiment pointed to possible BTV-induced immuno-suppression and predisposition to secondary microbial infections. These results have significant implications not only in understanding immuno-pathological consequences but also in studying interactions of BTV with host cells.

Development of loop-mediated isothermal amplification assay for specific and rapid detection of camelpox virus in clinical samples

In this study, development of loop-mediated isothermal amplification (LAMP) assay based on ankyrin repeat protein gene (C18L) for specific and rapid detection of camelpox virus (CMLV) was carried out. The assay was optimized using viral genomic DNA (gDNA) extracted from density gradient purified CMLV and standard control recombinant DNA plasmid containing the target, which resulted in reliable amplification at 62°C for 60 min. The amplified LAMP product was identified by agarose gel electrophoresis and subsequent direct visualization under UV light or observation by naked-eye for the presence of turbidity and color change following the addition of SYBR Green I dye and hydroxy naphthol blue (HNB). The analytical specificity of LAMP and conventional PCR assays was evaluated using other related poxviruses namely buffalopox, goatpox, sheeppox, and orf viruses, which revealed only a specific amplification of CMLV. The LAMP assay was 10-fold more sensitive than the conventional PCR. Further, the assay was evaluated with DNA extracted from the cell culture isolates of CMLV (n=11) and clinical samples (n=23). These results proved that the developed LAMP is a simple, specific, sensitive, rapid and economical diagnostic tool for detection of CMLV from clinical materials.

Enhanced proinflammatory cytokine activity during experimental bluetongue virus-1 infection in Indian native sheep.

Bluetongue disease has been causing variable morbidity and mortality in sheep in India and other countries of the world. The experimental infection with Indian BTV-1 strain induced mild to sub-acute infection in native sheep. There were low induction of IL-12, IFN-γ and TNF-α cytokine mRNA expressions determined by real time RT-PCR in draining lymph nodes (DLN), spleen, and PBMCs during the initial stages of infection (8 days post inoculation, DPI) and higher around 15 DPI. The reduced pro-inflammatory cytokine (IFN-γ and TNF-α) responses during the initial stage of infection (8 DPI) was also accompanied by similarly decreased T-cell populations and overt clinical symptoms. Later up regulation of these cytokines and substantial increase in the proportion of CD8(+) T-cells occurred with reduction of clinical signs and disappearance of BTV-1 antigen from tissues as determined by immunohistochemistry and RT-PCR. Thus there is definite involvement of pro-inflammatory cytokines and CD8(+) T cell activity in disease induced by BTV-1 strain.

Comparative sequence analysis of poxvirus A32 gene encoded ATPase protein and carboxyl terminal heterogeneity of Indian orf viruses

Thirteen orf virus (ORFV) isolates from natural outbreaks in sheep and goats belonging to different geographical regions of India were analysed on the basis of ORF108 (a homologue of poxviral A32 gene), which is known to encode for ATPase and involved in virion DNA packaging. Comparative sequence analysis of ATPase proteins revealed highly conserved N-terminal region with five different motifs [Walker A, Walker B, A32L specific motifs (III and IV) and a novel AYDG (motif-V)] among all poxviruses and divergent carboxyl terminus with either single or double RGD sequences among all Indian ORFV isolates. A homology model and secondary structure predictions of N-terminal region of ORFV A32 revealed that most of the poxviruses including ORFV ATPase protein belong to a distinct clade of the HerA/FtsK super family of DNA packaging proteins. Despite differences in host cell specificity and poxvirus infections among animals, DNA packaging motor domain of poxviruses presumed to share remarkable similarities as indicated by the presence of conserved ATPase motifs in the present investigation. The study also indicated the circulation of heterogeneous strains of ORFV in India and possibilities of differentiation of ORFV strains based on C-terminal heterogeneity.

Molecular characterization of peste-des-petits ruminants virus (PPRV) isolated from an outbreak in the Indo-Bangladesh border of Tripura state of North-East India

Peste-des-petits- ruminants (PPR) is a highly contagious and devastating disease of goats and sheep. Although India is endemic for PPR, Tripura, a state in North East India has never been reported confirmed PPR outbreaks. Recently, an outbreak of PPR occurred in non-descript goats at the Sabroom town of Tripura state in North-East India in June, 2013. The causative agent, PPR virus (PPRV) was confirmed by sandwich ELISA, virus isolation and N gene based RT-PCR and sequencing. The sequence and phylogenetic analysis confirmed the involvement of lineage IV PPR virus in the outbreak. The outbreak viruses from Tripura state were clustered mainly with circulating viruses from Bangladesh, India, China, Pakistan, Tajikistan, Dubai and Kurdistan. However, the nucleotide sequence homology ranged from 99.2 to 99.6% with the PPR strains circulating in Bangladesh during 2011 and 2012 whereas 95.5-98% homology has been observed with the viruses from India and other countries. These findings suggest the transboundary circulation of PPR virus between India and Bangladesh border, which warrant immediate vaccination across the international border to create an immune belt.

Cytokines Expression Profile and Kinetics of Peste des petits ruminants Virus Antigen and Antibody in Infected and Vaccinated Goats

The present study deals with the co-ordination of cytokine (IL-4 and IFN-γ) expression and kinetics of peste des petits ruminants (PPR) virus antigen and antibody in PPRV infected and vaccinated goats. The infected animals exhibited mixed cytokine (both TH1 and TH2) responses in the initial phase of the disease. The infected and dead goats had increased IFN-γ response before their death; while IL-4 remained at the base level. The cytokine expression in recovered animals was almost similar to that of vaccinated ones, where a unique biphasic response of IL-4 expression was observed with an up-regulation of IFN-γ on 7th days post vaccination (dpv). Analysis of PPR virus antigen and antibody kinetics in different components of blood from infected and vaccinated animals revealed that the PPR virus antigen load was highest in plasma followed by serum and blood of the infected animals, whereas vaccinated animals showed only marginal positivity on 9th dpv. The antibody titer was high in serum followed by plasma and blood in both vaccinated and infected animals. Therefore, it is inferred that the presence of antigen and antibody were significant with the expression of cytokine, and that a decreased response of IL-4 was noticed during intermediate phase of the disease i.e., 7 to 12th days post infection (dpi). This indicates the ability to mount a functional TH2 response after 14th dpi could be a critical determinant in deciding the survival of the PPR infected animal.

TaqMan hydrolysis probe based real time PCR for detection and quantitation of camelpox virus in skin scabs

The study describes the development of TaqMan hydrolysis probe based real time PCR (rt-PCR) assay targeting the ankyrin repeat protein (C18L) gene sequences for the detection and quantitation of camelpox virus (CMLV) nucleic acid and its comparison with established conventional and SYBR green rt-PCR assays. The assay was specific with an efficiency of 99.4%. The analytical sensitivity was 4 × 10¹ and 0.35 in terms of copy number and picogram of virus genomic DNA, respectively. The assay was linear with an acceptable intra (0.9-2.83% and 0.9-2.3%) and inter-assay (0.46-2.3% and 0.9-3.3) variations, when standard plasmid DNA and genomic DNA from purified CMLV respectively were tested. The assay was rapid, specific and sensitive as that of SYBR green and 1000 times more sensitive than the conventional PCR. It is suitable for the detection of CMLV nucleic acid directly from clinical samples. Further, the assay was evaluated using cell culture adapted CMLV isolates (n=11) and clinical samples (n=23) from camels and humans suspected of camelpox. This is an improved technique over conventional and SYBR green rt-PCR methods for the detection and quantitation of CMLV from skin scabs.