Genetic trans-complementation of L-protease fails to rescue the infectious foot-and-mouth disease virus from the Lbpro defective genome.

Outbreaks of the foot-and-mouth disease (FMD) have major economic impact on the global livestock industry by affecting the animal health and product safety. L-protease, a non-structural protein of FMDV, is a papain-like cysteine proteinase involved in viral protein processing as well as cleavage of host proteins for promoting the virus growth. FMDV synthesizes two forms of leader proteinase, Lpro (Labpro and Lbpro), where the deletion of Labpro is lethal and Lbpro deletion is reported to be attenuated. Defective replicons have been used by trans-complementing the deleted gene to produce one time replicating virus; thus, the bio-safety procedure can be compromised in the production units. Attempts are made to rescue of ΔLbproFMDV Asia1 virus by co-expressing the Lbpro protein carried in pcDNA plasmid. Mutant FMDV cDNA, pAsia-ΔLbpro, was constructed by PCR mediated mutagenesis using inverse primers. Transfection of BHK-21 cells with in-vitro transcribed RNA from the constructs failed to produce an infective mutant FMDV. Genetic trans-complementation of the Lbpro, which was done by co-transfecting the pcDNALbpro plasmid DNA along with the pAsia-ΔLbpro RNA in BHK-21 cells also failed to produce viable virus. Expression experiments of reporter genes and indirect immune-fluorescence confirmed the production of the viral proteins in wild type FMDV pAsiaWT; however, it was absent in the pAsia-ΔLbpro indicating that the leaderless virus was unable to produce infectious progeny and infect the cells. Failure to produce virus either by Lbpro deleted mutant clone or by genetic complementation suggests little chance of reversion of the disabled virus with large deletions of FMDV genome.

Expression of F1L, a vaccinia virus H3L transmembrane protein analogue of orf virus, and its successful purification as a diagnostic antigen.

Orf or contagious ecthyma is a highly contagious, zoonotic, and economically important global viral disease of small ruminants and is endemic in India. Vaccination of susceptible goats/sheep along with suitable recombinant protein-based serological assay will be useful in the control of the infection. In this study, the full-length and truncated versions of F1L encoding gene (ORF 059) of orf virus were cloned into pFasBac HT A vector, transformed in DH10Bac cells, and expressed in insect cells. The full-length and truncated recombinant F1L proteins were expressed as a 6 × histidine-tagged fusion protein for ease of purification by Ni-NTA affinity chromatography under denaturing conditions. A protein with ~ 40 kDa and ~ 35 kDa for full-length and truncated F1L protein, respectively, were expressed and confirmed by SDS-PAGE and western blot. The protein reactivity evaluated by western blot analysis and indirect ELISA using ORFV hyperimmune serum was also found to be reactive. The results of the present study showed that the purified recombinant F1L protein can be used as a diagnostic antigen in sero-surveillance of ORFV infection in small ruminants. To the best of authors' knowledge, this is the first report on the expression of ORFV F1L in insect cells using a baculovirus vector and its successful purification to use as the potential diagnostic antigen in ELISA.

Genetic analysis of two viroceptor genes of orf virus.

In the present study, we analyzed the chemokine-binding protein (CBP) and the GM-CSF/IL-2 inhibition factor (GIF) of orf virus (ORFV) isolates of sheep and goat origin from different geographical regions of India. Both are immunomodulatory proteins known for their unique strategy of establishing short-term immunity and re-infection in their host. The GIF gene is highly conserved, whereas the CBP gene is highly variable. Both the proteins have conserved potential N-glycosylation sites. The GIF protein contains the "WDPWV" motif responsible for receptor activation. In addition, the SUSHI/short consensus repeats (SCR) domain is reported for the first time in ORFV. Both proteins could potentially be used as immunotherapeutic agents in inflammatory diseases related to the overexpression of specific cytokines.

Long-term protective immunity to goatpox in goats after a single immunization with a live attenuated goatpox vaccine.

In this study, the duration of immunity following a single-dose vaccination using an attenuated live goatpox vaccine (GTPV/Uttarkashi/1978 strain) was evaluated in goatpox-seronegative goats for 52 months. Long-term immunity was evaluated by clinical protection upon virulent virus challenge and serum neutralization assay applied to serum samples. The rise in the level of GTPV-specific antibodies was found to reach a maximum at 21 days post-vaccination, and these antibodies were maintained for 1 to 2 years after immunization, with a steady decline. Upon virulent virus challenge at 12, 24, 42, and 52 months post-vaccination, protection in all the vaccinated animals was evident (100%), whereas, the control animals developed severe clinical disease. This is the first time that the long-term immunity of a live goatpox vaccine has been investigated up to 52 months after vaccination in goats by virulent virus challenge and demonstration of serum neutralization titres. This vaccine has immense potential for controlling and eradicating goatpox from an enzootic region.

Comparative sequence and structural analysis of the ORF095 gene, a vaccinia virus A4L homolog of capripoxvirus in sheep and goats.

Sheeppox and goatpox are important transboundary animal viral diseases of sheep and goats caused by sheeppox virus (SPPV) and goatpox virus (GTPV), respectively, of the genus Capripoxvirus, family Poxviridae. Among the proteins encoded by the capripoxvirus (CaPV) genome, ORF095 (vaccinia virus A4L homolog) is an immunodominant virion core protein that plays a pivotal role in virus assembly and morphogenesis. In the present study, sequence analysis of the ORF095 genes of 27 SPPV and GTPV isolates or field samples from different geographical regions of India was performed, and structure was prediction was done by homology modeling. A multiple sequence alignment of different CaPV isolates revealed that CaPV-A4L is highly conserved, with several species-specific signature residues, namely A93, A216, A315, G136 and G146 in GTPV, G47, A63, A168 and A276 in SPPV, and G48 and C98 in lumpy skin disease virus (LSDV). Phylogenetically, the CaPV isolates were separated into three major clusters, GTPV, SPPV and LSDV, based on the complete coding sequence of the CaPV-A4L gene. Genus-specific clustering of poxviruses was observed in phylogenetic analysis based on A4L protein homologs of chordopoxviruses. A secondary structure prediction showed the presence of six α-helices and one ß-sheet as well as some coils. The signature residues identified here are potentially useful for genotyping, and the predicted characteristics of the CaPV-A4L protein make it an ideal candidate for use as an immunogenic or diagnostic antigen for the development of immunoassays in  the sero-evaluation of CaPV in target hosts.

Expression and evaluation of recombinant P32 protein based ELISA for sero-diagnostic potential of capripox in sheep and goats.

The study is aimed to develop and evaluate a recombinant P32 protein based ELISA for sero-monitoring and sero-surveillance using known and random/suspected serum samples for capripox infections from sheep and goats. Truncated P32 gene of goatpox virus (with an ORF of 750 bp) was expressed in E. coli BL-21 CodonPlus (DE3)-RIPL cells using pET32a vector and characterized by SDS-PAGE analysis and confirmed by western blotting as 48 kDa polyhistidine-tagged fusion protein. The protein was purified under denaturing conditions using 8M urea and characterized by SDS-PAGE and immunoblotting. The purified protein was used for optimizing ELISA in a chequerboard titration method using anti-GTPV serum as known positive. The optimized conditions were found to be 300 ng of protein/well, 1:10 dilution of antibody, 1:10000 dilution of rabbit anti-goat/sheep conjugate with 3% skim milk powder and 2% gelatin in phosphate buffer saline containing tween-20 as blocking buffer. The expressed protein was specific only for goatpox virus and sheeppox virus but did not react with related viruses of sheep and goats namely orf virus, peste de petits ruminants virus, bluetongue virus and foot and mouth disease virus. The optimized ELISA was evaluated using pre-vaccinated, post-vaccinated and also post-challenge sera. The assay was found to have a diagnostic specificity of 100/98.7% and sensitivity of 97.1/98.1% when compared to whole virus antigen based ELISA/SNT by receiver operating characteristic (ROC) analysis. The optimized ELISA is able to determine the progression of antibody response against GTPV and SPPV following vaccination and challenge in sheep and goats. The rP32 protein based ELISA was evaluated using random field serum samples (n = 1008) suspected for sheeppox and goatpox and it has shown positivity rate as 24.4%. The rP32 protein based ELISA was found to be specific and sensitive for sero-evaluation of sheeppox virus and goatpox virus following vaccination and infection in sheep and goats.

Functional characterization of recombinant major envelope protein (rB2L) of orf virus.

Orf, or contagious ecthyma, a highly contagious transboundary disease of sheep and goats, is caused by a double-stranded DNA virus (ORFV) belonging to the genus Parapoxvirus of the family Poxviridae. The ORFV genome encodes the major envelope proteins B2L and F1L, which have been found to be highly immunogenic and have multiple functional characteristics. In order to investigate the functional properties of the B2L protein, in this study, the B2L gene of ORFV strain 59/05, encoding recombinant mature B2L (aa 1M-D334), was produced as a fusion protein in Escherichia coli. The functional characteristics of purified rB2L fusion protein (~60 kDa) were evaluated in vivo and in vitro, showing that this protein had lipase and immunomodulatory activities. Immunization trials involving laboratory animals (mice, rabbits and guinea pigs) using either constant or graded doses of rB2L fusion protein with or without adjuvants (FCA, alum) as well as co-administration with candidate rErns-Ag protein of classical swine fever virus (CSFV) indicated that the rB2L protein is immunogenic and has immunomodulatory properties. This study shows the potential utility of the rB2L protein as a safe and novel adjuvant in veterinary vaccine formulations.

Genetic diversity of fusion gene (ORF 117), an analogue of vaccinia virus A27L gene of capripox virus isolates.

The fusion gene (ORF 117) sequences of twelve (n = 12) capripox virus isolates namely sheeppox (SPPV) and goatpox (GTPV) viruses from India were demonstrated for their genetic and phylogenetic relationship among them. All the isolates were confirmed for their identity by routine PCR before targeting ORF 117 gene for sequence analysis. The designed primers specifically amplified ORF 117 gene as 447 bp fragment from total genomic DNA extracted from all the isolates. Sequence analysis revealed a significant percentage of identity among GTPV, SPPV and between them at both nucleotide and amino acid levels. The topology of the phylogenetic tree revealed that three distinct clusters corresponding to SPPV, GTPV and lumpy skin disease virus was formed. However, SPPV Pune/08 and SPPV Roumanian Fanar isolates were clustered into GTPV group as these two isolates showed a 100 and 99.3 % identity with GTPV isolates of India at nt and aa levels, respectively. Protein secondary structure and 3D view was predicted and found that it has high antigenic index and surface probability with low hydrophobicity, and it can be targeted for expression and its evaluation to explore its diagnostic potential in epidemiological investigation in future.

Detection and characterization of atypical capripoxviruses among small ruminants in India.

Recent developments in molecular biology shed light on cross-species transmission of SPPV and GTPV. The present study was planned to characterize the capripoxviruses which were circulating in the field condition among sheep and goats using RPO30 gene-based viral lineage (SPPV/GTPV) differentiating PCR and sequencing of RPO30 and GPCR genes from clinical samples. Out of 58 scabs (35 sheep and 23 goats) screened, 27 sheep and 18 goat scabs were found positive for capripox virus infections. With the exception of one sheep and one goat scabs, all the positive samples yielded amplicon size according to host origin, i.e. SPPV in sheep and GTPV in goats. In the above two exceptional cases, goat scab and sheep scab yielded amplicon size as that of SPPV and GTPV, respectively. Further, sequencing and phylogenetic analyses of complete ORFs of RPO30 and GPCR genes from six sheep and three goat scabs revealed that with the exception of above two samples, all had host-specific signatures and clustered according to their host origin. In case of cross-species infecting samples, sheep scab possessed GTPV-like signatures and goat scab possessed SPPV-like signatures. Our study identifies the circulation of cross-infecting SPPV and GTPV in the field and warrants the development of single-strain vaccine which can protect the animals from both sheeppox and goatpox diseases.

Molecular characterization of Indian sheeppox and goatpox viruses based on RPO30 and GPCR genes.

Sheeppox and goatpox are economically important diseases of small ruminants caused by sheeppox virus (SPPV) and goatpox virus (GTPV), respectively. Although SPPV and GTPV have host preference, some strains may infect both sheep and goats. As capripox viruses (SPPV, GTPV and LSDV) are antigenically related but genetically distinct, their differentiation requires analysis at molecular level. In the present study, RPO30 and GPCR genes of eight Indian SPPV and GTPV isolates were PCR amplified, cloned and sequences are genetically and phylogenetically analyzed. The RPO30 gene of SPPV and GTPV had lineage-specific signatures, and deletion of 21-nucleotide exclusively present in SPPV. Similarly, GPCR gene also had lineage-specific signatures for SPPV and GTPV. Phylogenetic analysis of capripox viruses based on RPO30 and GPCR genes revealed three distinct lineage-specific clusters as per their host origin. Our study supports that both RPO30 and GPCR genes could be used for differentiation of SPPV and GTPV as well as for molecular epidemiological studies. The study also highlights the distinct lineage specificities of the Indian SPPV and GTPV isolates including vaccine strains.

Genomic characterization of Lumpy Skin Disease virus (LSDV) from India: Circulation of Kenyan-like LSDV strains with unique kelch-like proteins.

Lumpy skin disease (LSD) is an economically important poxviral disease endemic to Asia, Europe, and Africa. Recently, LSD has spread to naïve countries, including India, China, Bangladesh, Pakistan, Myanmar, Vietnam, and Thailand. Here, we describe the complete genomic characterization of LSDV from India, LSDV-WB/IND/19 isolated from an LSD affected calf in 2019 determined by Illumina next-generation sequencing (NGS). The LSDV-WB/IND/19 has a genome size of 150,969 bp encoding 156 putative ORFs. Phylogenetic analysis based on complete genome sequence suggested that LSDV-WB/IND/19 is closely related to Kenyan LSDV strains with 10-12 variants with non-synonymous changes confined to LSD_019, LSD_049, LSD_089, LSD_094, LSD_096, LSD_140, and LSD_144 genes. In contrast to complete kelch-like proteins in Kenyan LSDV strains, LSDV-WB/IND/19 LSD_019 and LSD_144 genes were found to encode truncated versions (019a, 019b, and 144a, 144b). LSD_019a and LSD_019b proteins of LSDV-WB/IND/19 resemble that of wild-type LSDV strains based on SNPs and the C-terminal part of LSD_019b except for deletion at K229, whereas the LSD_144a and LSD_144b proteins resemble that of Kenyan LSDV strains based on SNPs, however, C-terminal part of LSD_144a resembles that of vaccine-associated LSDV strains due to premature truncation. The NGS findings were confirmed by Sanger sequencing of these genes in Vero cell isolate as well as in the original skin scab along with similar findings in another Indian LSDV from scab specimen. LSD_019 and LSD_144 genes are thought to modulate virulence and host range in capripoxviruses. This study demonstrates the circulation of unique LSDV strains in India and highlights the importance of constant monitoring of the molecular evolution of LSDV and associated factors in the region in light of the emergence of recombinant LSDV strains.

Identification and phylogenetic analysis of orf viruses isolated from outbreaks in goats of Assam, a northeastern state of India.

Two outbreaks of orf virus (ORFV) (a parapoxvirus) infection in goats, which occurred in Golaghat and Kamrup districts of Assam, a northeastern part of India, were investigated. The disease was diagnosed by standard virological and molecular techniques. The entire protein-coding region of B2L gene of two isolates were cloned and sequenced. Phylogenetic analysis based on B2L amino acid sequences showed that the ORFVs identified in these outbreaks were closely related to each other and both were closer to ORFV-Shahjahanpur 82/04 isolate from north India. The present study revealed that the precise characterization of the genomic region (B2L gene) might provide evidence for the genetic variation and movement of circulating ORFV strains in India.

An improved visual closed tube Loop mediated isothermal amplification (LAMP) assay for rapid identification of orf virus in sheep and goats.

The orf virus (ORFV) is an epitheliotropic virus causing a highly contagious skin disease mainly in sheep and goats. Several diagnostics including molecular tools like Loop mediated isothermal amplification (LAMP) assay are available to detect ORFV in affected species. However, the carry-over contamination associated with LAMP as open tube format prevents the assay applicability as point of care test in field diagnostic settings. In this study, the B2L gene based LAMP assay was optimized in a closed tube format using hydroxynaphthol blue (HNB) and calcein as pre-addition dyes and it has shown a clear positive and negative signal at 60 °C using 4 and 5 mM concentrations of MgSO4 respectively for these dyes. Optimitimzed assay that could reveal the result within one hour is highly specific and senstive with a limit of detection at 12.5 femtogram of viral genomic DNA or ~85 virus genome equivalent. This improved method prevented the cross-contamination of future LAMP reactions in the laboratory without compromising diagnostic sensitivity (100%) and specificity (100%) when compared to open tube system. This closed tube LAMP method has potential to act as a simple visual detection assay for the rapid and specific diagnosis of ORFV in sheep and goats.

The complete genome sequence of Indian sheeppox vaccine virus and comparative analysis with other capripoxviruses.

Sheeppox virus (SPPV) is responsible for a significant economic loss to sheep husbandry in enzootic regions of Africa, the Middle East, and Asia including the Indian subcontinent. In this study, we present the complete genome sequence of SPPV vaccine strain SPPV-Srin38/00 from India determined by next-generation sequencing (NGS) using Illumina technology. The attenuated Srinagar vaccine strain of SPPV (SPPV-Srin38/00) was developed by serial passaging the virus initially in lamb testes (LT) cells followed by Vero cell line. The SPPV-Srin38/00 virus has a genome size of 150, 103 bp, which encodes for 147 functional putative genes and consists of a central coding region flanked by two identical 2353 bp inverted terminal repeats (ITRs). Comparative phylogenetic analysis based on complete genome sequences of Capripoxviruses formed three distinct groups each for SPPV, GTPV, and LSDV with clustering of SPPV-Srin38/00 strain with SPPV-A strain. Nine ORFs of SPPV-Srin38/00 namely SPPV-Srin_002/SPPV-Srin_155, SPPV-Srin_004/SPPV-Srin_153, SPPV-Srin_009, SPPV-Srin_013, SPPV-Srin_026, SPPV-Srin_132, and SPPV-Srin_136 were found to be fragmented as compared to LSDV, whereas only one ORF (such as SPPV-Srin_136) was found to be fragmented as compared to GTPV. SPPV genomes, including the SPPV-Srin38/00 strain, shared 99.78-99.98% intraspecies nucleotide identity, indicating that SPPV strains have extremely low genetic diversity. The strain shared 96.80-97.08% and 97.11-97.61% nt identity with GTPV and LSDV strains, respectively. Its ORFs 016, 021, 022, 130 and 138 are the least identical ORFs among three species of the genus Capripoxvirus with 72.5-93% aa identity to GTPV and LSDV strains and may be potentially used for differentiation of CaPV species. This study may contribute to a better understanding of the epidemiology and evolution of capripoxviruses as well as the development of specific detection methods, better expression vectors, and vaccines with improved safety and efficacy.

Circulation of orf viruses containing the NZ7-like vascular endothelial growth factor (VEGF-E) gene type in India.

Orf, a poxviral skin infection of small ruminants is caused by orf virus (ORFV) of the genus Parapoxvirus of the Poxviridae family. Vascular endothelial growth factor (VEGF) is an important virulence factor that is responsible for proliferative lesions in parapoxviral infections. VEGF gene shows high intra- and inter-species variability. Two variants of VEGF have been described globally in ORFV, viz. NZ2- and NZ7-like. In the present study, ORFV isolates of different geographic regions of India were analysed on the basis of the VEGF gene. Indian ORFV isolates showed 95.7-100 % nucleotide (nt) and 78.4-99.3 % amino acid (aa) identity with each other, except ORFV-Assam/LK/14 and ORFV-Meghalaya/03 which shared 85.1-88.35 % and 79.1-81.8 % identity, at nt and aa levels, respectively with other Indian ORFV isolates. All Indian ORFVs under the study demonstrated 83.5-99.1 % nt and 80.5-97.9 % aa identity with NZ7-like VEGF as compared to 41.2-44.8 % nt and 30.7-38.4 % aa identity with NZ2-like VEGF on comparison with global ORFV strains. Phylogenetic analysis based on the VEGF gene showed two clusters of ORFV in which the Indian ORFVs clustered with NZ7-like VEGF from global ORFV strains, mostly from China. Despite the considerable variation, VEGF protein from Indian ORFV strains showed conserved VEGF homology domain with eight cysteine residues. Homology modeling of Indian ORFV strains predicted the presence of extended Loop 3 similar to NZ7-like VEGF. Therefore, the present study showed the circulation of ORFV strains with comparatively less variable NZ7-like VEGF in India which implicates its importance in the epidemiology of ORFV infections in the country.

Comparative efficacy of conventional and taqman polymerase chain reaction assays in the detection of capripoxviruses from clinical samples.

Sheeppox and goatpox are economically important viral diseases of sheep and goats, respectively. Both diseases are reportable to the World Organization for Animal Health. To implement a control and eradication program for these diseases, a rapid and user-friendly diagnostic tool is imperative for screening. Therefore, in the present study, TaqMan quantitative polymerase chain reaction (qPCR) and conventional PCR assays targeting the DNA polymerase (DNA pol) gene were developed for the detection of Capripoxvirus DNA from clinical specimens of sheep and goats. The 2 assays used different primer sets. Conventional PCR yielded a specific product of 134 bp, whereas qPCR yielded a 180-bp product. The specificity of amplified DNA pol gene products was confirmed by their size and by sequence analysis. The 2 assays were specific for Sheeppox virus and Goatpox virus. However, in comparison to conventional PCR, the qPCR was more rapid, specific, and 100 times more sensitive, with a detection limit as low as 0.042 pg of purified DNA. The qPCR assay was more sensitive (84.05%) than conventional PCR (76.06%) when used on clinical samples (n = 71) from sheep and goats.

A polymerase chain reaction strategy for the diagnosis of camelpox.

Camelpox is a contagious viral skin disease that is mostly seen in young camels. The disease is caused by the Camelpox virus (CMLV). In the present study, a polymerase chain reaction (PCR) assay based on the C18L gene (encoding ankyrin repeat protein) and a duplex PCR based on the C18L and DNA polymerase (DNA pol) genes were developed. The former assay yields a specific amplicon of 243 bp of the C18L gene, whereas the duplex PCR yields 243- and 96-bp products of the C18L and DNA pol genes, respectively, in CMLV, and only a 96-bp product of the DNA pol gene in other orthopoxviruses. The limit of detection was as low as 0.4 ng of viral DNA. Both PCR assays were employed successfully for the direct detection and differentiation of CMLV from other orthopoxviruses, capripoxviruses, and parapoxviruses in both cell culture samples and clinical material. Furthermore, a highly sensitive SYBR Green dye-based, real-time PCR was optimized for quantitation of CMLV DNA. In the standard curve of the quantitative assay, the melting temperature of the specific amplicon at 77.6 degrees C with peak measured fluorescence in dissociation plot was observed with an efficiency of 102%. To the authors' knowledge, this is the first report to describe a C18L gene-based PCR for specific diagnosis of camelpox infection.

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.

Genetic analysis of L1R myristoylated protein of Capripoxviruses reveals structural homogeneity among poxviruses.

Sheeppox virus (SPPV) and goatpox virus (GTPV) are members of the genus Capripoxvirus (CaPV) of the family Poxviridae. CaPVs are responsible for important contagious diseases of small ruminants that are enzootic to the Indian sub-continent, Central and Northern Africa and the Middle East. In the present study, the sequence and phylogenetic analysis of the L1R gene of sixteen CaPV isolates (seven SPPV and nine GTPV) from India were performed along with 3D homology modeling of the L1R protein. L1R is a myristoylated protein responsible for virion assembly and being present on intracellular mature virion (IMV) surface, it is also a potent target for eliciting neutralizing antibodies. Sequence analysis of CaPV L1R gene revealed an ORF of 738bp with >99% and >96% identity within species and between species, respectively, at both nucleotide as well as amino acid levels. Phylogenetic analysis displayed distinct clusters of members of genus Capripoxvirus, as GTPV, SPPV and LSDV. L1R at the protein level showed various species-specific signature residues that may be useful for future grouping or genotyping of CaPV members. CaPV L1R was predicted to possess myristoylation motif GAAASIQTTVNTLNEKI and a potential N-glycosylation site at amino acid residue 50 (Asn). Despite of different host specificity in poxviruses, comparative sequence analysis of L1R proteins revealed highly conserved nature with presence of myristoylation motif (GXXXS) and six cysteine residues forming three disulfide bonds among all poxviruses. The conserved and immunogenic nature of the CaPV L1R gene may prove to be a potential candidate/target for developing molecular diagnostics including recombinant protein based assays and prophylactics for the control of CaPV diseases in tropical countries like India.

Sequence analysis of haemagglutinin gene of camelpox viruses shows deletion leading to frameshift: Circulation of diverse clusters among camelpox viruses.

Orthopoxviruses (OPVs) have broad host range infecting a variety of species along with gene-specific determinants. Several genes including haemagglutinin (HA) are used for differentiation of OPVs. Among poxviruses, OPVs are sole members encoding HA protein as part of extracellular enveloped virion membrane. Camelpox virus (CMLV) causes an important contagious disease affecting mainly young camels, endemic to Indian subcontinent, Africa and the Middle East. This study describes the sequence features and phylogenetic analysis of HA gene (homologue of VACV A56R) of Indian CMLV isolates. Comparative analysis of CMLV HA gene revealed conserved nature within CMLVs but considerable variability was observed between various species of OPVs. Most Indian CMLV isolates showed 99.5%-100% and 96.3%-100% identity, at nucleotide (nt) and amino acid (aa) levels respectively, among themselves and with CMLV-M96 strain. Importantly, Indian CMLV strains along with CMLV-M96 showed deletion of seven nucleotides resulting in frameshift mutation at C-terminus of HA protein. Phylogenetic analysis displayed distinct clustering among CMLVs which might point to the circulation of diverse CMLV strains in nature. Despite different host specificity of OPVs, comparative sequence analysis of HA protein showed highly conserved N-terminal Ig V-set functional domain with tandem repeats. Understanding of molecular diversity of CMLVs and structural domains of HA protein will help in the elucidation of molecular mechanisms for immune evasion and design of novel antivirals for OPVs.