Structural and sequence analysis of the RPO30 gene of sheeppox and goatpox viruses from India.

Sheeppox and goatpox are transboundary viral diseases of sheep and goats that cause significant economic losses to small and marginal farmers worldwide, including India. Members of the genus Capripoxvirus (CaPV), namely Sheeppox virus (SPPV), Goatpox virus (GTPV), and Lumpy skin disease virus (LSDV), are antigenically similar, and species differentiation can only be accomplished using molecular approaches. The present study aimed to understand the molecular epidemiology and host specificity of SPPV and GTPV circulating in India through sequencing and structural analysis of the RNA polymerase subunit-30 kDa (RPO30) gene. A total of 29 field isolates from sheep (n = 19) and goats (n = 10) belonging to different geographical regions of India during the period: Year 2015 to 2023, were analyzed based on the sequence and structure of the full-length RPO30 gene/protein. Phylogenetically, all the CaPV isolates were separated into three major clusters: SPPV, GTPV, and LSDV. Multiple sequence alignment revealed a highly conserved RPO30 gene, with a stretch of 21 nucleotide deletion in all SPPV isolates. Additionally, the RPO30 gene of the Indian SPPV and GTPV isolates possessed several species-specific conserved signature residues/motifs that could act as genotyping markers. Secondary structure analysis of the RPO30 protein showed four α-helices, two loops, and three turns, similar to that of the E4L protein of vaccinia virus (VACV). All the isolates in the present study exhibited host preferences across different states of India. Therefore, in order to protect vulnerable small ruminants from poxviral infections, it is recommended to take into consideration a homologous vaccination strategy.

Targeted Whole Genome Sequencing of the Capripoxvirus Genome from Clinical Tissue Samples and Lyophilized Vaccine Batches.

Diseases caused by Capripoxviruses (CaPVs) are of great economic importance in sheep, goats, and cattle. Since CaPV strains are serologically indistinguishable and genetically highly homologous, typing of closely related strains can only be achieved by whole-genome sequencing. In this chapter, we describe a robust, cost-effective, and widely applicable protocol for reconstructing (nearly) complete CaPV genomes directly from clinical samples or commercial vaccine batches in less than a week. Taking advantage of the genetic similarity of CaPVs, a set of pan-CaPVs long-range PCRs was developed that covers the entire genome with only a limited number of tiled amplicons. The resulting amplicons can be sequenced on all currently available high-throughput sequencing platforms. As an example, we have included a detailed protocol for performing nanopore sequencing and a pipeline for assembling the resulting tiled amplicon data.

Harnessing Attenuation-Related Mutations of Viral Genomes: Development of a Serological Assay to Differentiate between Capripoxvirus-Infected and -Vaccinated Animals.

Sheeppox, goatpox, and lumpy skin disease caused by the sheeppox virus (SPPV), goatpox virus (GTPV), and lumpy skin disease virus (LSDV), respectively, are diseases that affect millions of ruminants and many low-income households in endemic countries, leading to great economic losses for the ruminant industry. The three viruses are members of the Capripoxvirus genus of the Poxviridae family. Live attenuated vaccines remain the only efficient means for controlling capripox diseases. However, serological tools have not been available to differentiate infected from vaccinated animals (DIVA), though crucial for proper disease surveillance, control, and eradication efforts. We analysed the sequences of variola virus B22R homologue gene for SPPV, GTPV, and LSDV and observed significant differences between field and vaccine strains in all three capripoxvirus species, resulting in the truncation and absence of the B22R protein in major vaccines within each of the viral species. We selected and expressed a protein fragment present in wildtype viruses but absent in selected vaccine strains of all three species, taking advantage of these alterations in the B22R gene. An indirect ELISA (iELISA) developed using this protein fragment was evaluated on well-characterized sera from vaccinated, naturally and experimentally infected, and negative cattle and sheep. The developed wildtype-specific capripox DIVA iELISA showed >99% sensitivity and specificity for serum collected from animals infected with the wildtype virus. To the best of our knowledge, this is the first wildtype-specific, DIVA-capable iELISA for poxvirus diseases exploiting changes in nucleotide sequence alterations in vaccine strains.

Poxvirus sensitivity of a novel diploid sheep embryonic heart cell line.

Lumpy skin disease virus (LSDV), camelpox virus (CPV), and orf virus (ORFV) are members of the family Poxviridae. These viruses are usually isolated or produced in embryonated eggs or primary cells because continuous cell lines are less sensitive to infection. Disadvantages of the use of eggs or primary cells include limited availability, potential endogenous contaminants, and a limited ability to perform multiple passages. In this study, we developed a diploid cell culture from sheep embryonic hearts (EHs) and demonstrated its high proliferative and long-term storage capacities. In addition, we demonstrated its sensitivity to representatives of three genera of the family Poxviridae: Capripoxvirus (LSDV), Orthopoxvirus (CPV), and Parapoxvirus (ORFV). The cell culture had a doubling time of 24 h and reached 40 passages with satisfactory yield. This is comparable to that observed in primary lamb testis (LT) cells at passage 5 (P5). After infection, each poxvirus titer was 7.0-7.6 log TCID50/mL for up to five passages and approximately 6.8, 6.4, and 5.6 for the three viruses at P6-P25, P30, and P40, respectively. The sensitivity of sheep EH cells to poxvirus infection did not decrease after long-term storage in liquid nitrogen and was higher than that of primary LT cells, which are used for capripoxvirus and parapoxvirus detection and growth, and Vero cells, which are used for orthopoxvirus detection and growth. Thus, EH diploid cells are useful for poxvirus isolation and production without embryonated eggs or primary cells.

Development of the isothermal recombinase polymerase amplification assays for rapid detection of the genus Capripoxvirus.

Sheeppox virus (SPPV), goatpox virus (GTPV) and lumpy skin disease virus (LSDV) belong to the genus Capripoxvirus (CaPV), and are important pathogens of sheep, goat and cattle, respectively. Rapid and reliable detection of CaPV is critical to prevent its spread and promote its eradication. This study aimed to develop the recombinase polymerase amplification (RPA) assays combined with real-time fluorescence (real-time RPA) and naked-eye visible lateral flow strip (LFS RPA) for rapid detection of CaPV. Both developed RPA assays worked well at 39 °C within 20 min. They were highly specific for the detection of GTPV, SPPV and LSDV, while no cross-reactivity was observed for other non-targeted pathogens and genomic DNA of goat, sheep and cattle. The limit of detection for real-time RPA and LFS RPA were 1.0 × 102 and 1.0 × 101 copies per reaction, respectively. In the artificially contaminated samples with GTPV, the detection results of RPA assays were consistent with those of real-time PCR. For 15 clinical samples, LSDV was detected by real-time RPA, LFS RPA and real-time PCR in 13, 15 and 15 samples, respectively. The developed RPA assays were specific, sensitive, and user-friendly for the rapid detection of CaPV, and could be a better alternative method applied in low-resources settings.

Multiple accurate and sensitive arrays for Capripoxvirus (CaPV) differentiation.

Capripoxvirus (CaPV) contains three viruses that have caused massive losses in the livestock and dairy industries. Accurate CaPV differentiation has far-reaching implications for effectively controlling outbreaks. However, it has a great challenge to distinguishing three viruses due to high homology of 97%. Here, we established a sensitive CRISPR/Cas12a array based on Multiple-recombinase polymerase amplification (M-RPA) for CaPV differentiation, which provided a more comprehensive and accurate differentiation mode targeting VARV B22R and RPO30 genes. By sensitive CRISPR/Cas12a and M-RPA, the actual detection limits of three viruses were as low as 50, 40 and 60 copies, respectively. Moreover, Lateral flow dipstick (LFD) array based on CRISPR/Cas12a achieved portable and intuitive detection, making it suitable for point-of-care testing. Therefore, CRISPR/Cas12a array and LFD array paved the way for CaPV differentiation in practice. Additionally, we constructed a real-time quantitative PCR (qPCR) array to fill the qPCR technical gap in differentiation and to facilitate the quarantine departments.

Development and Validation of a New DIVA Real-Time PCR Allowing to Differentiate Wild-Type Lumpy Skin Disease Virus Strains, Including the Asian Recombinant Strains, from Neethling-Based Vaccine Strains.

The current epidemic in Asia, driven by LSDV recombinants, poses difficulties to existing DIVA PCR tests, as these do not differentiate between homologous vaccine strains and the recombinant strains. We, therefore, developed and validated a new duplex real-time PCR capable of differentiating Neethling-based vaccine strains from classical and recombinant wild-type strains that are currently circulating in Asia. The DIVA potential of this new assay, seen in the in silico evaluation, was confirmed on samples from LSDV infected and vaccinated animals and on isolates of LSDV recombinants (n = 12), vaccine (n = 5), and classic wild-type strains (n = 6). No cross-reactivity or a-specificity with other capripox viruses was observed under field conditions in non-capripox viral stocks and negative animals. The high analytical sensitivity is translated into a high diagnostic specificity as more than 70 samples were all correctly detected with Ct values very similar to those of a published first-line pan capripox real-time PCR. Finally, the low inter- and intra-run variability observed shows that the new DIVA PCR is very robust which facilitates its implementation in the lab. All validation parameters that are mentioned above indicate the potential of the newly developed test as a promising diagnostic tool which could help to control the current LSDV epidemic in Asia.

Generation and application of immortalized sertoli cell line from sheep testis.

Primary sheep testicular Sertoli cells (STSCs) are ideal for investigating the molecular and pathogenic processes of capripoxvirus. However, the high cost of isolation and culture of primary STSCs, time-consuming operation, and short lifespan greatly limit their real-world application. In our study, the primary STSCs were isolated and immortalized by transfection of a lentiviral recombinant plasmid containing simian virus 40 (SV40) large T antigen. Androgen-binding protein (ABP) and vimentin (VIM) protein expression, SV40 large T antigen activity, proliferation assays, and apoptosis analysis results showed that immortalized large T antigen STSCs (TSTSCs) still had the same physiological characteristics and biological functions as primary STSCs. Moreover, immortalized TSTSCs had strong anti-apoptosis ability, extended lifespan, and enhanced proliferative activity compared to primary STSCs, which had not transformed in vitro and showed any signs of malignancy phenotype in nude mice. Besides, immortalized TSTSCs were susceptible to goatpox virus (GTPV), lumpy skin disease virus (LSDV), and Orf virus (ORFV). In conclusion, immortalized TSTSCs are useful in vitro models to study GTPV, LSDV, and ORFV in a wide range of ways, suggesting that it can be safely used in virus isolation, vaccine and drug screening studies in future.

The emergence of novel Iranian variants in sheeppox and goatpox viral envelope proteins with remarkably altered putative binding affinities with the host receptor.

The outbreak of Sheep and goat pox (SGP) viral infections have increasingly been reported despite vaccinating the majority of sheep populations in Iran. The objective of this study was to predict the impacts of the SGP P32/envelope variations on the binding with host receptors as a candidate tool to assess this outbreak. The targeted gene was amplified in a total of 101 viral samples, and the PCR products were subjected to Sanger sequencing. The polymorphism and phylogenetic interactions of the identified variants were assessed. Molecular docking was performed between the identified P32 variants and the host receptor and the effects of these variants were evaluated. Eighteen variations were identified in the investigated P32 gene with variable silent and missense effects on the envelope protein. Five groups (G1-G5) of amino acid variations were identified. While there were no amino acid variations in the G1 (wild-type) viral protein, G2, G3, G4, and G5 proteins had seven, nine, twelve, and fourteen SNPs, respectively. Based on the observed amino acid substitutions, multiple distinct phylogenetic places were occupied from the identified viral groups. Dramatic alterations were identified between G2, G4, and G5 variants with their proteoglycan receptor, while the highest binding was revealed between goatpox G5 variant with the same receptor. It was suggested that the higher severity of goatpox viral infection originated from its higher affinity to bind with its cognate receptor. This firm binding may be explained by the observed higher severity of the SGP cases from which G5 samples were isolated.

A recombinant capripoxvirus expressing the F protein of peste des petits ruminants virus and the P12A3C of foot-and-mouth disease virus.

BACKGROUND: Peste des petits ruminants (PPR), foot-and-mouth disease (FMD) and sheep pox and goat pox are three important infectious diseases that infect goats, sheep and other small ruminants. It is well-known that the prevention of three diseases rely mainly on their individual vaccines. However, the vaccines have a variety of different disadvantages, such as short duration of immunity, increasing the number of vaccinations, and poor thermal stability. The purpose of this study is to construct a recombinant goat pox virus (rGPV) capable of expressing the F gene of PPRV and the P12A3C gene of FMDV as a live vector vaccine. RESULTS: The IRES, FMDV P12A3C and PPRV F genes into the multi-cloning site of the universal transfer plasmid pTKfpgigp to construct a recombinant transfer plasmid pTKfpgigpFiP12A3C, and transfected GPV-infected lamb testis (LT) cells with liposomes and produced by homologous recombination Recombinant GPV (rGPV/PPRVF-FMDVP12A3C, rGPV). The rGPV was screened and purified by green florescence protein (GFP) and xanthine-guanine-phosphoribosyltransferase gene (gpt) of Escherichia coli as selective markers, and the expression of rGPV in LT cells was detected by RT-PCR and immunofluorescence techniques. The results showed that the virus strain rGPV/PPRVF-FMDVP12A3C containing FMDV P12A3C and PPRV F genes was obtained. The exogenous genes FMDV P12A3C and PPRV F contained in rGPV were normally transcribed and translated in LT cells, and the expression products could specifically react with PPRV and FMDV antiserum. Then, the rGPV was intradermally inoculated with goats, the animal experiments showed that rGPV/PPRVF-FMDVP12A3C could induce high levels of specific antibodies against GPV, PPRV and FMDV. CONCLUSIONS: The constructed rGPV induced high levels of specific antibodies against GPV, PPRV and FMDV. The study provides a reference for " one vaccine with multiple uses " of GPV live vector vaccine.

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.

[Adaptation of the sheep pox virus (Poxviridae: Capripoxvirus: Sheeppox virus) to African green monkey kidney cell line and evaluation of its immunobiological properties].

INTRODUCTION: Outbreaks of infectious diseases seriously hinder the preservation and increase of the number of small ruminants. Such infections include sheep pox virus (SPPV). According to the OIE data of 2021, SPP outbreaks were registered in countries such as Turkey, Israel, China, Maldives, Mongolia, Thailand, Russia, Algeria, Kenya, and in 2019 in Mangistau and Atyrau regions. In Kazakhstan annually conducts routine immunization of sheep at risk with a live attenuated vaccine produced by RIBSP. MATERIALS AND METHODS: The object of the study was the vaccine strain of NISHI and the virulent strain A of the sheep pox virus. The virus was propagated in Vero cells. To determine the harmlessness and immunogenicity, sheep of the Kazakh fine-wool breed aged from 6 to 12 months were used. Virological, serological and immunobiological methods were used in the study. RESULTS: The results of the adaptation of the NISHI strain of SPPV to the Vero cell line are presented. Five passages in Vero cells resulted to the adaptation of the NISHI strain with the manifestation of a cytopathogenic effect specific to SPPV with a titer of 6.50 lg TCD50/ml. Following immunization, the formation of immunity was observed in animals on day 7 with an average protective titer 1.8 log2, which increased by day 21 to 4.33 log2. CONCLUSION: It has been established that the NISHI strain of SPPV retains its virological and immunobiological properties during reproduction in a Vero cell line.

[Determination of the optimal immunizing dose of heterologous goat pox virus vaccine (Poxviridae: Chordopoxvirinae: Capripoxvirus) against lumpy skin disease].

INTRODUCTION: Lumpy skin disease (LSD), sheep pox and goat pox are dangerous diseases of domestic ruminants. Representatives of the genus of capripoxviruses are antigenically similar and can be used as a vaccine for three infections, as in the case of representatives of the genus of orthopoxviruses, which includes viruses of smallpox, monkeypox, and cowpox, that all belong to a single family Poxviridae. MATERIALS AND METHODS: In this study, the vaccine strain G20-LKV of the goat pox virus and the virulent strain RIBSP2019/K of the LSD virus were used. The experiments were carried out on clinically healthy cattle of the Kazakh White-headed breed, aged six to eight months. Virological and serological research methods were used in the work. RESULTS: All immunized animals that received different doses of the vaccine showed resistance to the infection challenge, without showing any clinical signs of the disease. In animals that received the lowest doses of the vaccine 15,000, 30,000 and 40,000 TCID50, no adverse events, skin and temperature reactions were observed at the injection site. Those vaccinated with high doses of the vaccine had a local reaction in the form of swelling at the site of vaccine administration. Control animals infected with a virulent virus showed clinical signs of the cattle lumpy skin disease . CONCLUSION: The vaccine, prepared based on the "G20-LKV" strain of the goat virus, is protective for cattle against infection with a virulent LSD virus at immunizing doses from 15,000 to 80,000 TCID50, which are dependent on the LSD epizootic situation in particular region.

Temporal dysregulation of genes in lamb testis cell during sheeppox virus infection.

The present study was aimed to elucidate the host-virus interactions using RNA-Seq analysis at 1 h and 8 h of post-infection of sheeppox virus (SPPV) in lamb testis cell. The differentially expressed genes (DEGs) and the underlying mechanisms linked to the host immune responses were obtained. The protein-protein interaction (PPI) network analysis and ingenuity pathway analysis (IPA) illustrated the interaction between the DEGs and their involvement in cell signalling responses. Highly connected hubs viz. AURKA, CHEK1, CCNB2, CDC6 and MAPK14 were identified through PPI network analysis. IPA analysis showed that IL-6- and ERK5-mediated signalling pathways were highly enriched at both time points. The TP53 gene was identified to be the leading upstream regulator that directly responded to SPPV infection, resulting in downregulation at both time points. The study provides an overview of how the lamb testis genes and their underlying mechanisms link to growth and immune response during SPPV infection.

A highly adaptable platform powered by CRISPR-Cas12a to diagnose lumpy skin disease in cattle.

Lumpy skin disease (LSD) in cattle, a transboundary viral disease of cattle once restricted to Africa, has been spreading to many European and Asian countries in the past decade with huge economic losses. This emerging worldwide threat to cattle warrants the development of diagnostic methods for accurate disease screening of suspected samples to effectively control the spread of LSD. In this study, we integrated pre-amplification and three kinds of sensor systems with CRISPR and therefore established an LSD diagnosis platform with highly adaptable and ultra-sensitive advantages. It was the first CRISPR-powered platform that could identify lumpy skin disease virus from vaccine strains of goat pox virus and sheep pox virus. Its limit of detection (LOD) was one copy/reaction after introducing PCR or recombinase-aided amplification (RAA). Moreover, this platform achieved a satisfactory overall agreement in clinical diagnoses of 50 samples and its reproducibility and accuracy were superior to other qPCR methods we tested. The whole diagnostic procedure, from DNA extraction to the results, could complete in 5 h with a total cost of 1.7-9.6 $/test. Overall, this CRISPR-powered platform provided a novel diagnostic tool for portable, ultra-sensitive, rapid, and highly adaptable disease screening of LSD and may be an effective method to control this transboundary disease's spread.

Coinfection kinetics of goatpox virus and peste-des-petits-ruminants virus in Vero cells.

Goatpox, sheeppox, and peste-des-petits-ruminants (PPR) are economically important virus diseases affecting goats and sheep, which often cause coinfection/comorbidities in the field. Coinfection with these viruses leads to enhanced infection in natural scenarios in terms of morbidities and mortalities. Currently, individual live attenuated vaccines are being used to mitigate these diseases and research on combination vaccines for these diseases is encouraging. For the preparation of combination vaccines, vaccine strains of the peste-des-petits-ruminants virus (PPRV), goatpox virus (GTPV), and sheeppox virus (SPPV) are grown separately and GTPV + PPRV are mixed for vaccination of goats, and PPRV + SPPV for sheep. Growing capripox and PPRV strains in the same cells simultaneously without the titer loss will save the time and cost of production. In the current study, we have evaluated the coinfection kinetics of capripox virus and a PPRV using a candidate GTPV vaccine strain (originally caused infection in both goats and sheep in the field) and PPRV/Sungri/96 (vaccine strain) in Vero cells. At high multiplicity of infection (MOI), PPRV was excluded from coinfection by GTPV, whereas at a low multiplicity coexistence/accommodation was observed between PPRV and GTPV without loss of the titer. The results shed light on the possibility of the production of two vaccine strains in the same cells using the coinfection model economically.

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.

Cloning Strategies for the Generation of Recombinant Capripoxvirus Through the Use of Screening and Selection Markers.

The ability to manipulate capripoxvirus through gene knockouts and gene insertions has become an increasingly valuable research tool in elucidating the function of individual genes of capripoxvirus, as well as in the development of capripoxvirus-based recombinant vaccines. The homologous recombination technique is commonly used to generate capripoxvirus knockout viruses (KO), and is based on the targeting of a particular viral gene of interest. This technique can also be used to insert a gene of interest. A protocol for the generation of a viral gene knockout is described. This technique involves the use of a plasmid which encodes the flanking sequences of the regions where the homologous recombination will occur, and will result in the insertion of an EGFP reporter gene for visualization of recombinant virus, as well as the E. coli gpt gene as a positive selection marker. If an additional gene is to be incorporated, this can be achieved by inserting a gene of interest for expression under a poxvirus promoter into the plasmid between the flanking regions for insertion. This chapter describes a protocol for generating such recombinant capripoxviruses. An alternative step for the removal of both the EGFP and gpt cassettes and an optional selection step using CRISPR technology are also described.

A robust, cost-effective and widely applicable whole-genome sequencing protocol for capripoxviruses.

The diseases caused by capripoxviruses (CaPVs) are of major economic concern in sheep, goat and cattle as they are inexorably spreading into non-endemic regions. As CaPV strains are serologically indistinguishable and genetically highly homologous, typing closely related strains can only be achieved by whole genome sequencing. Unfortunately the number of publicly available genomes remains low as most sequencing methods rely on virus isolation. Therefore, we developed a robust, cost-effective and widely applicable method that allows to generate (nearly) complete CaPV genomes directly from clinical samples or commercial vaccine batches. A set of pan-CaPVs long-range PCRs spanning the entire genome was designed to generate PCR amplicons that can be sequenced on commonly used high-throughput sequencing platforms: MiSeq (Illumina), RSII (PacBio) and MinION (Oxford Nanopore Technologies). The robustness of the LR-PCR strategy was evaluated for all 3 members of CaPV directly from a variety of samples, including clinical samples (N = 7), vaccine batches (N = 6), and virus isolates (N = 2). The sequencing method described here allows to reconstruct (nearly) complete CaPV genomes in less than a week and will aid researchers studying closely-related CaPV strains worldwide.

Ultra-sensitive and point-of-care detection of Capripoxvirus (CaPV) based on loop-mediated amplification (LAMP) and trans-cleavage activity of CRISPR/Cpf1.

Capripoxvirus (CaPV) is one of the common skin diseases infecting cattle and sheep which can cause serious economic losses. Establishing ultra-sensitive, rapid, and point-of-care detection of CaPV is particularly important for hindering its spread. Here, we use the principle that CRISPR/Cpf1 can specifically recognize the target DNA and activate its trans-cleavage activity to identify the CaPV product amplified by loop-mediated amplification (LAMP). Under the designed specific primers, a set of LAMP which can amplify CaPV specifically was established and optimized firstly. Then, the CRISPR/Cpf1 was introduced to identify LAMP products. LAMP can be completed at a constant temperature, thus avoiding the use of temperature-variable instruments, making it possible to detect viruses outside the laboratory. To further satisfy the point-of-care detection of CaPV, we introduced a portable fluorometer and CRISPR-based lateral flow test. Due to the introduction of CRISPR/Cpf1, the sensitivity of the method is greatly increased, which is of great significance for the early detection of viruses. Through CRISPR/Cpf1-mediated fluorescence detection, we can detect CaPV as low as 1.47 × 10-3 TCID50 in 50 min, 1000 times more sensitive than quantitative real-time PCR. Through CRISPR-based lateral flow test, we can visually detect CaPV as low as 1.47 × 10-2 TCID50. Besides, this strategy can be used for the primary samples obtained from the cell culture of CaPV after simple ultrasonic disruption, which eliminates the complicated nucleic acid extraction steps required by traditional methods.