Senecavirus A: An Emerging Vesicular Infection in Brazilian Pig Herds

Vesicular diseases are clinically and economically important infections that affect farm animals. North American studies have suggested that Senecavirus A infection might be associated with a vesicular disease in pigs known as porcine idiopathic vesicular disease (PIVD). In the beginning of 2015, outbreaks of porcine vesicular disease have occurred in six Brazilian states from three geographical regions. Official diagnostic tests were performed with negative results for classical vesicular diseases of compulsory reporting. This study investigated Senecavirus A infection in PIVD outbreaks in which other aetiological agents were ruled out. A primer set was designed to amplify a 542‐bp product size of VP3/VP1 region of Senecavirus A genome in RT‐PCR assay. Primer specificity was analysed in silico and in porcine biological specimens. For this, clinical specimens were collected from eight pig herds affected with PIVD, including vesicular fluid (n = 4) and swabs (n = 7) and scrapings of ruptured vesicles and ulcerative lesions (n = 5) from weaned and adult pigs. Clinically healthy animals (n = 52) of PIVD‐affected and non‐affected pig herds also were evaluated for Senecavirus A infection. The 16 samples from PIVD‐affected animals were positive for Senecavirus A in the RT‐PCR assay, while none of the clinically healthy pigs were detected with the virus. Sequencing analysis revealed high nucleotide (87.6–98.5%) and amino acid (95–99.4%) similarities to SVV‐01 prototype and other Senecavirus A strains from North American pigs. Primer set presented herein was suitable for molecular characterization of Senecavirus A. The results suggest that Senecavirus A was the aetiological agent of the vesicular disease outbreaks in the evaluated pig herds. This is the first study to report the Senecavirus A infection in clinically affected pigs outside of North America. Senecavirus A was considered a novel emerging pathogen associated with an important vesicular disease in Brazil.     

The First Identification and Complete Genome of Senecavirus A Affecting Pig with Idiopathic Vesicular Disease in China

Senecavirus A (SVA) infection was recently confirmed in pigs in Brazil. In March, 2015, an outbreak of vesicular disease occurred in Guangdong, China, characterized by vesicular lesions in sows and acute death of neonatal piglets. Cumulative incidence of porcine idiopathic vesicular disease in farm A was 258, which had a total number of 5500 sows. Sows in farm B displayed typical vesicular symptoms by May, 2015, which also had 5500 sows. A total of 278 and 142 of 5500 sows in farm B demonstrated lame and presented vesicles, respectively, associated with a total of 186 mortality in piglets. Routine differential diagnoses for swine vesicular disease were carried out to exclude infection with foot‐and‐mouth disease virus, swine vesicular disease virus, vesicular exanthema of swine virus and vesicular stomatitis virus. In this study, seven pairs of primer were designed to amplify the complete genome of SVA in RT‐PCR assays. Sequence alignment showed that this Chinese strain shares 94.4–97.1% sequence identity to other eight strains of SVA. This is the first report of SVA in China and provides information about the association between SVA infection and vesicular disease.     

Identification and genomic characterization of the emerging Senecavirus A in southeast China, 2017

Senecavirus A (SVA ) is an emerging non‐enveloped virus with a single‐stranded, positive‐sense RNA genome that belongs to the Senecavirus genus in the Picornaviridae family. Senecavirus A‐associated swine idiopathic vesicular disease and epidemic transient neonatal losses have caused substantial economic losses for the swine industry. Here, we describe a case of re‐emerging vesicular disease among sows and finishing pigs on a swine farm in Fujian Province of southeast China. Other causative pathogens, including FMDV , SVDV and VSV , were excluded, and a novel SVA strain, CH ‐FJZZ ‐2017, was isolated. Sequencing and phylogenetic analysis of the complete genome and individual viral proteins revealed that CH ‐FJZZ ‐2017 is closely related to the US strains in 2015. The results further showed that Chinese SVA s have formed two distinct subclades with 2016 as the turning point. Viruses causing outbreaks after late 2016 shared higher nucleotide identities with the US strains in 2015. There is still some evolutionary distance between CH ‐FJZZ ‐2017 and other strains isolated in late 2016, suggesting that Chinese SVA isolates have been evolving in different directions. This study provides a basis for the development of effective prevention and control strategies.     

Emergence and whole‐genome sequence of Senecavirus A in Colombia

In 2015 and 2016, Senecavirus A (SVA) emerged as an infectious disease in Brazil, China and the United States (US). In a Colombian commercial swine farm, vesicles on the snout and coronary bands were reported and tested negative for foot‐and‐mouth disease virus (FMDv), but positive for SVA. The whole‐genome phylogenetic analysis indicates the Colombian strain clusters with the strains from the United States, not with the recent SVA strains from Brazil.     

Systematic Epidemiological Investigations of Cases of Senecavirus A in US Swine Breeding Herds

Epidemiological investigations were conducted on a case series of six Senecavirus A (SVA)‐affected breeding herds in the United States to determine potential routes of introduction and enhance the swine industry's knowledge of SVA's clinical presentation and spread. Each SVA‐affected herd was evaluated using a standard form to ensure that all relevant data were collected. The form was used to guide a detailed discussion about the clinical presentation of SVA and risk events that occurred in the 4 weeks prior to the first observation of clinical signs with the herd veterinarian and farm personnel. Each event was then subjectively assigned a risk level of low, medium or high likelihood for SVA introduction by the investigation team. The clinical presentation of SVA varied by case. All SVA‐affected herds (six of six) reported increases in pre‐weaning mortality and sow anorexia. Vesicular lesions were observed in four of six herds, and mild‐to‐moderate neonatal diarrhoea was observed in three of six herds. No gross anatomic or histologic lesions were observed in neonatal pigs that tested positive for SVA via PCR. Multiple potential routes of introduction were identified. Events subjectively rated as high risk for SVA introduction were on‐farm employee entry (six of six), carcass disposal (four of six), cull sow removal (three of six) and breeding replacement entry (two of six). Non‐swine domestic animals, rodents, other visitors, repairs outside swine barns, feed delivery, weaned pig removal and semen entry were assigned a high risk level in one of six herds. Cases occurred in breeding herds of all sizes with variable biosecurity in both swine dense and swine sparse areas.     

Development of a novel quantitative real‐time PCR assay with lyophilized powder reagent to detect African swine fever virus in blood samples of domestic pigs in China

African swine fever (ASF) is a devastating disease, which is causing huge economic losses in China. Therefore, it is urgent to provide a rapid, highly specific and sensitive diagnostic method for the detection of African swine fever virus (ASFV), the ASF infectious agent. In this study, a novel quantitative real‐time polymerase chain reaction (qPCR) assay with lyophilized powder reagents (LPR), targeting the major structural protein p72 gene, was established for the detection of ASFV. This assay had many advantages, such as saving time and money, good sensitivity and repeatability. The sensitivity of this assay was 100 copies/μl of ASFV plasmid templates, and the assay showed 10‐fold greater sensitivity than a qPCR assay recommended by OIE. Furthermore, specificity analysis showed that qPCR with LPR for ASFV had no cross‐reactivity with other important swine pathogens. In clinical diagnoses of 218 blood samples of domestic pigs in China, the positive rate of the diagnosis of ASFV by qPCR with the LPR and commercial kit reached 80.73% (176/218) and 76.61% (167/218) respectively. The coincidence rate between the two assays is 92.20% (201/218), and kappa value is 0.768 (p < .0001) by SPSS analysis. The overall agreement between the two assays was 95.87% (209/218). Further Pearson correlation and linear regression analysis showed a significant correlation between the two assays with an R² value of 0.9438. The entire procedure, from specimen processing to result reporting, can be completed within 2 hr. Our results demonstrated that the qPCR‐LPR assay is a good laboratory diagnostic tool for sensitive and efficient detection of ASFV.     

Newcastle Disease Virus in Little Owls (Athene noctua) and African Penguins (Spheniscus demersus) in an Israeli Zoo

Newcastle disease is a contagious and often fatal disease, capable of affecting all species of birds. A velogenic Newcastle disease virus (vNDV) outbreak occurred in an Israeli zoo, in which Little owls (Athene noctua) and African penguins (Spheniscus demersus) were found positive for presence of NDV. Some of them have died. The diagnostic process included: post‐mortem examination, histopathology, real‐time RT‐PCR assay, virus isolation, serology, intracerebral pathogenicity index and phylogenetic analysis. A vNDV was diagnosed and found to be closely related to isolates from vNDV outbreaks that occurred in commercial poultry flocks during 2011. All isolates were classified as lineage 5d.     

The first detection of Senecavirus A in pigs in Thailand, 2016

We report the first detection of Senecavirus A (SVA ) in nine of 12 (75%) pigs in Thailand in 2016. The full‐length genome demonstrated that Thai SVA isolates were closely related to the first Canada strain (11‐55910‐3) than the recent strains causing outbreaks in Brazil, the United States and China in 2015–2016.     

Phylogenetic and genome analysis of seven senecavirus A isolates in China

Senecavirus A (SVA) is the only member of genus Senecavirus that causes vesicular lesions in pigs. We have characterized seven SVA isolates from different swine farms in Guangdong, China. The most variable isolate, CH‐DL‐01‐2016, contained a single amino acid insertion at position 219–220 and a 16 amino acid insertion at position 250–251. The VP1 protein also had four nucleotide changes when compared to 31 other SVA VP1 sequences obtained from GenBank. These mutations have not been identified before. Phylogenetic trees demonstrated that the new SVA isolates were clustered into two different clades and shared 96.3%–97.1% similarity with US strains and 97.9%–98.3% similarity with Brazilian stains on nucleotide level, respectively. Prediction of antigenic epitope indicated that SVA VP1 protein contained both potential B‐cell and potential T‐cell epitopes. This report provides information about variation analysis in SVA in southern China.     

Development and evaluation of multiplex real‐time RT‐PCR assays for the detection and differentiation of foot‐and‐mouth disease virus and Seneca Valley virus 1

Foot‐and‐mouth disease virus (FMDV) causes a highly contagious and economically important vesicular disease in cloven‐hoofed animals that is clinically indistinguishable from symptoms caused by Seneca Valley virus 1 (SVV‐1). To differentiate SVV‐1 from FMDV infections, we developed a SVV‐1 real‐time RT‐PCR (RT‐qPCR) assay and multiplexed with published FMDV assays. Two published FMDV assays (Journal of the American Veterinary Medical Association, 220, 2002, 1636; Journal of Virological Methods, 236, 2016, 258) targeting the 3D polymerase (3D) region were selected and multiplexed with the SVV‐1 assay that has two targets, one in the 5′ untranslated region (5′ UTR, this study) and the other in the 3D region (Journal of Virological Methods, 239, 2017, 34). In silico analysis showed that the primers and probes of SVV‐1 assay matched 98.3% of the strain sequences (113/115). The primer and probe sequences of the Shi FMDV assay matched 85.4% (806/944), and that of the Callahan FMDV assay matched 62.7% (592/944) of the sequences. The limit of detection (LOD) for the two multiplex RT‐qPCR assays for SVV‐1 was both 9 copies per reaction by cloned positive plasmids and 0.16 TCID50 per reaction by cell culture. The LOD for FMDV by both multiplex assays was 11 copies per reaction using cloned positive plasmids. With cell cultures of the seven serotypes of FMDV, the Shi assay (Journal of Virological Methods, 236, 2016, 258) had LODs between 0.04 and 0.18 TCID50 per reaction that were either the same or lower than the Callahan assay. Interestingly, multiplexing with SVV‐1 increased the amplification efficiencies of the Callahan assay (Journal of the American Veterinary Medical Association, 220, 2002, 1636) from 51.5%–66.7% to 89.5%–96.6%. Both assays specifically detected the target viruses without cross‐reacting to SVV‐1 or to other common porcine viruses. An 18S rRNA housekeeping gene that was amplified from multiple cloven‐hoofed animal species was used as an internal control. The prevalence study did not detect any FMDV, but SVV‐1 was detected from multiple types of swine samples with an overall positive rate of 10.5% for non‐serum samples.     

Arrival of rabbit haemorrhagic disease virus 2 to northern Europe: Emergence and outbreaks in wild and domestic rabbits (Oryctolagus cuniculus) in Sweden

Incursion of rabbit haemorrhagic disease virus (RHDV ) into Sweden was documented in 1990 and it is now considered endemic in wild rabbit (Oryctolagus cuniculus ) populations. Rabbit haemorrhagic disease virus 2 (RHDV 2), a new, related lagovirus was first detected in France in 2010, and has spread rapidly throughout Europe and beyond. However, knowledge of RHDV 2 in northern Europe is sporadic and incomplete, and in Sweden, routinely available diagnostic methods to detect rabbit haemorrhagic disease (RHD ) do not distinguish between types of virus causing disease. Using RHDV 2‐specific RT ‐qPCR , sequencing of the VP 60 gene and immunological virus typing of archived and prospective case material from the National Veterinary Institute's (SVA ) wildlife disease surveillance programme and diagnostic pathology service, we describe the emergence of RHDV 2 in Sweden in both wild and domestic rabbits. The earliest documented outbreak occurred on 22 May 2013, and from May 2013 to May 2016, 10 separate incidents of RHDV 2 were documented from six different municipalities in the southern half of Sweden. Phylogenetic analysis of the VP 60 gene shows clear clustering of Swedish isolates into three separate clusters within two different clades according to geographic location and time, suggesting viral evolution, multiple introduction events or both. Almost all cases of RHD examined by SVA from May 2013 to May 2016 were caused by RHDV 2, suggesting that RHDV 2 may be replacing RHDV as the predominant cause of RHD in Sweden.     

Development of a multiplex RT‐PCR for the detection of major diarrhoeal viruses in pig herds in China

The major enteric RNA viruses in pigs include porcine epidemic diarrhoea virus (PEDV), transmissible gastroenteritis virus (TGEV), porcine rotavirus A (PRV‐A), porcine kobuvirus (PKV), porcine sapovirus (PSaV) and porcine deltacoronavirus (PDCoV). For differential diagnosis, a multiplex RT‐PCR method was established on the basis of the N genes of TGEV, PEDV and PDCoV, the VP7 gene of PRV‐A, and the polyprotein genes of PKV and PSaV. This multiplex RT‐PCR could specifically detect TGEV, PEDV, PDCoV, PRV‐A, PKV and PSaV without cross‐reaction to any other major viruses circulating in Chinese pig farms. The limit of detection of this method was as low as 10⁰–10¹ ng cDNA of each virus. A total of 398 swine faecal samples collected from nine provinces of China between October 2015 and April 2017 were analysed by this established multiplex RT‐PCR. The results demonstrated that PDCoV (144/398), PSaV (114/398), PEDV (78/398) and PRV‐A (70/398) were the main pathogens, but TGEV was not found in the pig herds in China. In addition, dual infections, for example, PDCoV + PSaV, PDCoV + PRV‐A, PRA‐V + PSaV and PEDV + PDCoV, and triple infections, for example, PDCoV + PRV‐A + PSaV and PEDV + PDCoV + PKV, were found among the collected samples. The multiplex RT‐PCR provided a valuable tool for the differential diagnosis of swine enteric viruses circulating in Chinese pig farms and will facilitate the prevention and control of swine diarrhoea in China.     

Direct detection and characterization of foot‐and‐mouth disease virus in East Africa using a field‐ready real‐time PCR platform

Effective control and monitoring of foot‐and‐mouth disease (FMD ) relies upon rapid and accurate disease confirmation. Currently, clinical samples are usually tested in reference laboratories using standardized assays recommended by The World Organisation for Animal Health (OIE ). However, the requirements for prompt and serotype‐specific diagnosis during FMD outbreaks, and the need to establish robust laboratory testing capacity in FMD ‐endemic countries have motivated the development of simple diagnostic platforms to support local decision‐making. Using a portable thermocycler, the T‐COR ™ 8, this study describes the laboratory and field evaluation of a commercially available, lyophilized pan‐serotype‐specific real‐time RT ‐PCR (rRT ‐PCR ) assay and a newly available FMD virus (FMDV) typing assay (East Africa‐specific for serotypes: O, A, Southern African Territories [SAT ] 1 and 2). Analytical sensitivity, diagnostic sensitivity and specificity of the pan‐serotype‐specific lyophilized assay were comparable to that of an OIE ‐recommended laboratory‐based rRT ‐PCR (determined using a panel of 57 FMDV ‐positive samples and six non‐FMDV vesicular disease samples for differential diagnosis). The FMDV ‐typing assay was able to correctly identify the serotype of 33/36 FMDV ‐positive samples (no cross‐reactivity between serotypes was evident). Furthermore, the assays were able to accurately detect and type FMDV RNA in multiple sample types, including epithelial tissue suspensions, serum, oesophageal–pharyngeal (OP ) fluid and oral swabs, both with and without the use of nucleic acid extraction. When deployed in laboratory and field settings in Tanzania, Kenya and Ethiopia, both assays reliably detected and serotyped FMDV RNA in samples (n  = 144) collected from pre‐clinical, clinical and clinically recovered cattle. These data support the use of field‐ready rRT ‐PCR platforms in endemic settings for simple, highly sensitive and rapid detection and/or characterization of FMDV.     

Distinction Between Persistent and Transient Infection in a Bovine Viral Diarrhoea (BVD) Control Programme: Appropriate Interpretation of Real‐Time RT‐PCR and Antigen‐ELISA Test Results

Control of bovine viral diarrhoea (BVD) in Belgium is currently implemented on a voluntary basis at herd level and mainly relies on detection and culling of persistently infected (PI) animals. The present field study was conducted during the winter of 2010/2011 to assess the performances of diagnostic assays used in the testing scheme for BVD as proposed by the two Belgian regional laboratories. Individual blood samples were collected from 4972 animals, and individual samples from the same herd were pooled (maximum of 30 individual samples per pool) and screened for the presence of Bovine Viral Diarrhoea Virus (BVDV)‐specific RNA using a commercial real‐time RT‐PCR test (ADIAGENE). Individual samples from positive pools were then tested in parallel with the same RT‐PCR test and with an antigen‐capture ELISA test (IDEXX) to detect viremic animals. This study demonstrated that individual results differed according to the type of assay used (P < 0.001): 140 animals (2.8%) were positive by RT‐PCR and 72 (1.4%) by antigen‐ELISA. A second blood sample was taken 40 days later from 74 PCR positive animals to detect persistent viremia: 17 (23%) of these were still PCR positive and considered to be PI and the 57 that no longer tested positive were assumed to be transiently infected (TI) animals. All PI animals were positive also by antigen‐ELISA at both time points. Among TI animals, 10 (16%) were positive by antigen‐ELISA at the first but none at the second sampling. A highly significant difference in cycle threshold (C_t) values obtained by RT‐PCR was observed between PI and TI animals. ROC analysis was performed to establish thresholds to confirm with high probability that an animal is PI, based on the result of RT‐PCR test performed on a single individual blood sample.     

Rapid and simple detection of foot‐and‐mouth disease virus: Evaluation of a cartridge‐based molecular detection system for use in basic laboratories

Highly contagious transboundary animal diseases such as foot‐and‐mouth disease (FMD ) are major threats to the productivity of farm animals. To limit the impact of outbreaks and to take efficient steps towards a timely control and eradication of the disease, rapid and reliable diagnostic systems are of utmost importance. Confirmatory diagnostic assays are typically performed by experienced operators in specialized laboratories, and access to this capability is often limited in the developing countries with the highest disease burden. Advances in molecular technologies allow implementation of modern and reliable techniques for quick and simple pathogen detection either in basic laboratories or even at the pen‐side. Here, we report on a study to evaluate a fully automated cartridge‐based real‐time RT ‐PCR diagnostic system (Enigma MiniLab^®) for the detection of FMD virus (FMDV ). The modular system integrates both nucleic acid extraction and downstream real‐time RT ‐PCR (rRT ‐PCR ). The analytical sensitivity of this assay was determined using serially diluted culture grown FMDV , and the performance of the assay was evaluated using a selected range of FMDV positive and negative clinical samples of bovine, porcine and ovine origin. The robustness of the assay was evaluated in an international inter‐laboratory proficiency test and by deployment into an African laboratory. It was demonstrated that the system is easy to use and can detect FMDV with high sensitivity and specificity, roughly on par with standard laboratory methods. This cartridge‐based automated real‐time RT ‐PCR system for the detection of FMDV represents a reliable and easy to use diagnostic tool for the early and rapid disease detection of acutely infected animals even in remote areas. This type of system could be easily deployed for routine surveillance within endemic regions such as Africa or could alternatively be used in the developed world.