Detection of Atypical Porcine Pestivirus in Piglets from Danish Sow Herds

Enhancing the understanding of coinfection outcomes: Impact of natural atypical porcine pestivirus infection on porcine reproductive and respiratory syndrome in pigs

Atypical porcine pestivirus (APPV) is a novel member of the Pestivirus genus detected in association with congenital tremor (CT) type A-II outbreaks and from apparently healthy pigs, both as singular infection and as part of multi-pathogen infections. 'Classical' pestiviruses are known to cause immunosuppression of their host, which can increase susceptibility to secondary infections, severely impacting health, welfare, and production. To investigate APPV's effect on the host's immune system and characterise disease outcomes, 12 piglets from a natural APPV CT type A-II outbreak were experimentally infected with porcine reproductive and respiratory syndrome virus (PRRSV), a significant porcine pathogen. Rectal temperatures indicating febrile responses, viremia and viral-specific humoral and cellular responses were assessed throughout the study. Pathological assessment of the lungs and APPV-PRRSV co-localisation within the lungs was performed at necropsy. Viral co-localisation and pathological assessment of the lungs (Immunohistochemistry, BaseScope in situ hybridisation) were performed post-mortem. APPV status did not impact virological or immunological differences in PRRSV-infected groups. However, significantly higher rectal temperatures were observed in the APPV+ve/PRRSV+ve group over four days, indicating APPV increased the febrile response. Significant differences in the lung consolidation of the apical and intermediate lobes were also present, suggesting that APPV co-infection may augment lung pathology.

Development of a Crystal Digital RT-PCR for the Detection of Atypical Porcine Pestivirus

Atypical porcine pestivirus (APPV), a newly discovered virus, is associated with the type A-II congenital tremor (CT) in neonatal piglets. APPV distributes throughout the world and causes certain economic losses to the swine industry. The specific primers and probe were designed targeting the 5' untranslated region (UTR) of APPV to amplify a 90 bp fragment, and the recombinant standard plasmid was constructed. After optimizing the concentrations of primers and probe, annealing temperature, and reaction cycles, a crystal digital RT-PCR (cdRT-PCR) and real-time quantitative RT-PCR (qRT-PCR) were successfully established. The results showed that the standard curves of the qRT-PCR and the cdRT-PCR had R² values of 0.999 and 0.9998, respectively. Both methods could specifically detect APPV, and no amplification signal was obtained from other swine viruses. The limit of detection (LOD) of the cdRT-PCR was 0.1 copies/µL, and that of the qRT-PCR was 10 copies/µL. The intra-assay and inter-assay coefficients of variation of repeatability and reproducibility were less than 0.90% for the qRT-PCR and less than 5.27% for the cdRT-PCR. The 60 clinical tissue samples were analyzed using both methods, and the positivity rates of APPV were 23.33% by the qRT-PCR and 25% by the cdRT-PCR, with a coincidence rate of 98.33%. The results indicated that the cdRT-PCR and the qRT-PCR developed here are highly specific, sensitive methods for the rapid and accurate detection of APPV.

Detection and localization of atypical porcine pestivirus in the testicles of naturally infected, congenital tremor affected piglets

Atypical porcine pestivirus (APPV) belongs to the genus Pestivirus within the family Flaviviridae. Recently, APPV has been identified as the causative agent of congenital tremor (CT) type AII. The disease is a neurological disorder that affects newborn piglets and is characterized by generalized trembling of the animals and often splay legs. CT is well known worldwide, and the virus seems to be highly prevalent in major swine producing areas. However, little is known about the epidemiology of the infection, transmission and spread of the virus between herds. Here, we show the high prevalence of APPV in processing fluid samples collected from Hungarian pig herds which led us to investigate the cellular targets of the virus in the testicles of newborn piglets affected by CT. By the development of an RNA in situ hybridization assay and the use of immunohistochemistry on consecutive slides, we identified the target cells of APPV in the testicle: interstitial Leydig cells, peritubular myoid cells and smooth muscle cells of medium-sized arteries. Previous studies have shown that APPV can be found in the semen of sexually mature boars suggesting the role of infected boars and their semen in the transmission of the virus similar to many other members of the Flaviviridae family. As in our case, the virus has not been identified in cells beyond the Sertoli cell barrier, further studies on infected adult boars' testicles and other reproductive glands are needed to analyze the possible changes in the cell tropism of APPV that might contribute to its prolonged extraction by the semen beyond the period of viraemia.

Development of a quantitative real time RT-PCR assay for sensitive and rapid detection of emerging Atypical Porcine Pestivirus associated with congenital tremor in pigs

Atypical Porcine Pestivirus (APPV) is reported as the etiologic agent for type AII congenital tremors in newborn piglets. Initial PCR-based diagnostic tests to detect APPV were designed based on the limited sequence information and are not capable of detecting the majority of APPV strains. A sensitive and reliable PCR-based diagnostic test is critical for accurate detection of APPV. In this study, a quantitative reverse transcription PCR (RT-qPCR) assay was developed for reliable detection of all currently known APPV strains. The assay design also included swine 18S rRNA gene as an internal control to monitor RNA extraction efficiency. Two APPV gene fragments, one each from NS5b and NS3, were cloned and used to determine the dynamic range of detection, linearity and analytical sensitivity/limit of detection (LOD). Both individual and multiplex assays (duplex and triplex) had correlation coefficients of >0.99 and PCR amplification efficiencies of >90 %. Comparison of detection limit and analytical sensitivity between individual, and multiplex assays indicated no inhibition of PCR sensitivity upon multiplexing. The detection limit for APPV target, based on analytical sensitivity, is 7.75 copies (NS5b) and 5.2 copies (NS3) per reaction. Assay specificity was verified by testing nucleic acids of other closely related pestiviruses and clinical samples that are positive for other common swine pathogens. Assay sensitivity was also assessed on synthesized gene fragments of the most divergent China strains. Testing 339 known APPV-positive and 202 negative clinical samples demonstrated a good diagnostic sensitivity and specificity. Data from six independent runs, including 5 replicates of three clinical samples with three Ct ranges, were utilized to assess inter-assay repeatability and intra-assay reproducibility. This analysis demonstrated intra-assay/inter-assay coefficients of variation of 0.71 % and 0.01 %, respectively, with a PCR efficiency of 92.71 % for the triplex assay. Testing of 1785 clinical samples revealed ∼19 % prevalence of APPV in the US swine herds and oral fluids demonstrates to be a reliable specimen for viral detection. This multiplex RT-qPCR assay offers a rapid and reliable detection of APPV in swine herds and serves as useful tool in APPV surveillance and epidemiological investigations.