Detection of atypical porcine pestivirus in Swedish piglets with congenital tremor type A-II

First detection of atypical porcine pestivirus in piglets affected by congenital tremor in Poland

Congenital tremors are neurological disorders of newborn piglets that may lead to serious health consequences, including increased mortality. Many reports have indicated that atypical porcine pestivirus (APPV), first identified in 2015, is a possible cause of this condition. In different countries, APPV was detected in farms affected by piglets' congenital tremors. There is a lack of data regarding the presence of this virus in Poland. However, swine veterinarians report outbreaks of congenital tremor with unestablished aetiology nationwide. Therefore, this study aimed to verify the presence of APPV in piglets with congenital tremors in Poland. Samples of blood (2), faecal swabs (7), brain (7), cerebellum (5), spinal cord, (7) lymph nodes (7), tonsil (7), thymus (6), tongue (7), heart (7), lung (7) and liver (7) were collected from piglets. Form sows' blood (5) and oral fluid (3, pooling samples) were collected. All samples have been derived from a commercial breeding farm reporting a case of congenital tremor and subjected to the qPCR via commercial kit (EXOone Atypical Porcine Pestivirus, Exopol, Spain). Six out of seven piglets tested positive for APPV, with the highest viral loads detected in the cerebellum and tonsils. All samples from sows were negative, emphasising the virus's specificity to piglets. To the authors' knowledge, this is the first report confirming APPV's presence in Poland. Given the potentially significant impact of APPV infections on swine health and production economics, further research evaluating the epidemiology and pathogenicity of APPV, as well as identifying preventive measures, is sorely needed.

Network of Interactions between the Mut Domains of the E2 Protein of Atypical Porcine Pestivirus and Host Proteins

Atypical porcine pestivirus (APPV) can cause congenital tremor type A-II in neonatal piglets, posing a significant threat to swine herd health globally. Our previous study demonstrated that the Mut domains, comprising 112 amino acids at the N-terminus, are the primary functional regions of the E2 protein of APPV. This study identified 14 host cellular proteins that exhibit potential interactions with the Mut domains of the E2 protein using yeast two-hybrid screening. Using bioinformatics analysis, we discovered that the Mut domains of the E2 protein might exert regulatory effects on apoptosis by modulating energy metabolism within the mitochondria. We also conducted co-immunoprecipitation, glutathione S-transferase pull-down, and immunofluorescence assays to confirm the interaction between the Mut domains of the E2 protein and cathepsin H and signal sequence receptor subunit 4 (SSR4). Ultimately, SSR4 enhanced APPV replication in vitro. In summary, our study successfully elucidated the interactions between the Mut domains of the E2 protein and host cell protein, predicted the potential pathways implicated in these interactions, and demonstrated SSR4 involvement in APPV infection. These significant findings contribute valuable knowledge toward a deeper understanding of APPV pathogenesis and the role of the Mut domains of the E2 protein in this intricate process.

Development and application of an indirect ELISA for detection of antibodies against emerging atypical porcine pestivirus

BACKGROUND

Atypical porcine pestivirus (APPV) is a newly discovered swine pestivirus, which can cause congenital tremor and high mortality in newborn piglets and subclinical infection in adult pigs, leading to significant impacts on the pig industry. Currently, there is no approved serological method to assess APPV infection status in pig farms.

METHODS

In this study, the envelope glycoprotein E2 of APPV was highly expressed in suspension HEK293 cells, and further an indirect enzyme-linked immunosorbent assay based on the recombinant E2 protein (E2-iELISA) was developed and evaluated.

RESULTS

The reaction parameters of the E2-iELISA were optimized, and the cutoff value was determined to be 0.2 by analyzing S/P values of 165 negative sera against APPV that were confirmed by virus neutralization test (VNT). Specificity test showed that the method had no cross-reaction with other common swine viruses. The E2-iELISA was evaluated using a panel of swine sera, and showed high sensitivity (113/120, 94.2%) and specificity (65/70, 92.9%), and the agreement rate with VNT was 93.7% (178/190). Subsequently, the E2-iELISA was utilized to investigate the seroprevalence of APPV in pig herds of China. When detecting 1368 pig serum samples collected from nine provinces in China, the overall seroprevalence of APPV was 73.9% (1011/1368).

CONCLUSION

Our findings suggest that the E2-iELISA is specific and sensitive, and could be a valuable tool for serological surveillance of APPV infection in pigs.

Screening for atypical porcine pestivirus in Swedish boar semen used for artificial insemination and a characterisation of the seminal RNA microbiome including the virome

BACKGROUND

This study aimed to characterise the RNA microbiome, including the virome of extended semen from Swedish breeding boars, with particular focus on Atypical porcine pestivirus (APPV). This neurotropic virus, associated with congenital tremor type A-II in piglets, was recently demonstrated to induce the disease through insemination with semen from infected boars.

RESULTS

From 124 Artificial Insemination (AI) doses from Swedish breeding boars, APPV was detected in one dose in addition to a sparse seminal RNA virome, characterised by retroviruses, phages, and some fecal-associated contaminants. The detected seminal microbiome was large and characterized by Gram-negative bacteria from the phylum Proteobacteria, mainly consisting of apathogenic or opportunistic bacteria. The proportion of bacteria with a pathogenic potential was low, and no antimicrobial resistance genes (ARGs) were detected in the datasets.

CONCLUSION

Overall, the results indicate a good health status among Swedish breeding boars. The detection of APPV in semen raises the question of whether routine screening for APPV in breeding boars should be instigated.

Congenital tremor and splay leg in piglets – insights into the virome, local cytokine response, and histology

Background

Atypical porcine pestivirus (APPV) is a neurotropic virus associated with congenital tremor type A-II. A few experimental studies also indicate an association between APPV and splay leg. The overarching aim of the present study was to provide insights into the virome, local cytokine response, and histology of the CNS in piglets with signs of congenital tremor or splay leg.

Results

Characterization of the cytokine profile and virome of the brain in piglets with signs of congenital tremor revealed an APPV-associated upregulation of Stimulator of interferon genes (STING). The upregulation of STING was associated with an increased expression of the gene encoding IFN-α but no differential expression was recorded for the genes encoding CXCL8, IFN-β, IFN-γ, IL-1β, IL-6, or IL-10. No viral agents or cytokine upregulation could be detected in the spinal cord of piglets with signs of splay leg or in the brain of piglets without an APPV-infection. The histopathological examination showed no lesions in the CNS that could be attributed to the APPV-infection, as no difference between sick and healthy piglets could be seen.

Conclusion

The results from this study provide evidence of an APPV-induced antiviral cytokine response but found no lesions related to the infection nor any support for a common causative agent.

An outbreak of splayleg and congenital tremors in piglets farrowed by a newly populated sow herd

A newly populated sow herd suffered an outbreak of splayleg and congenital tremors in the offspring. Some piglets were affected by one or the other condition, others by both. The problem lasted for about 9 months and was associated with significant losses, mainly because of the splayleg component. Most piglets with only congenital tremors were able to survive and their condition improved as they got older. Piglets with congenital tremors had histological lesions consistent with this condition, and pestivirus K (formerly atypical porcine pestivirus) was identified from their nervous tissues.

Genotyping atypical porcine pestivirus using NS5a

Atypical porcine pestivirus (APPV) is an emerging virus discovered in 2014 and it can cause congenital tremors in pigs. Molecular epidemiology serves as an essential tool in monitoring and controlling the disease. Virus epidemiology mainly relies on genome sequencing and phylogenetic characterization. Previous molecular epidemiology studies have been using different genes/regions for phylogeny, namely whole genome, Npro, and E2 coding sequences. However, with increasing number of APPV sequences available in GenBank, no systemic studies have been performed for detailed classification of APPV strains around the globe. The goal of this study is to propose a classification strategy or taxonomy of APPV strains at genotype, subgenotype, and isolate levels. A total of 76 whole genomes and 16 partial polyprotein coding sequences were analyzed for genetic variability and suitability of all individual genes for viral phylogenies. Our results revealed that, among all the viral genes, NS5a coding sequences were proved to be the most suitable alternative for tracing APPV strains supported by its capability of reproducing the same phylogenetic and evolutionary information as the whole viral genome did. Also, a reliable cutoff to accurately classify APPV at different levels is established. We propose a genotyping scheme with three well-defined genotypes (1-3) and 7 subgenotypes for genotype 1 (1.1-1.7). For whole genome analysis, a threshold value of 84%-91% pairwise identity allows separation of all APPV subgenotypes, whereas 80% identity clearly segregate the three major APPV genotypes. For NS5a gene analysis, 82%-91% identity allows subgenotype separation and 76% identity segregate APPV genotypes. Additionally, genetic distance of whole genome exhibits ≤8% in isolate level, 9%-14% in subgenotype level, and 17%-22% in genotype level, while for NS5a encoding sequences the genetic distance displays ≤9% in isolate level, 9.9%-19.1% in subgenotype level, and 21.6%-29.7% in genotype level. These allow a clear segregation among APPV genotypes, subgenotypes, and isolates. Therefore, the proposed strategy in this study provides a solid and improved basis for molecular phylogenetics to understand APPV genetic diversity, trace the origins and control the spread of new disease outbreaks.

Atypical porcine pestivirus-A widespread virus in the Swedish wild boar population

The recently identified causative agent of congenital tremor in domestic piglets, atypical porcine pestivirus (APPV), was detected in serum from Swedish wild boar. A previous study from Sweden described APPV in domestic piglets suffering from congenital tremor, but the APPV situation in the wild boar population was unknown. In this study, 595 serum samples from wild boar originating from 13 counties in the south and central parts of Sweden, collected between 2000 and 2018, were analysed for the presence of the APPV-genome and for antibodies against the APPV-glycoprotein E^rns . The results revealed that APPV is highly abundant in the Swedish wild boar population; 12% (73/595) were APPV-genome positive in serum and 72% (433/595) of the tested wild boars displayed APPV-specific antibodies. The present study also shows that APPV has been present in the Swedish wild boar population since at least the year 2000. The viral sequences obtained from the wild boars were highly similar to those obtained from Swedish domestic pigs positive for APPV and suffering from congenital tremor, suggesting a viral exchange between wild boars and domestic pigs. The high proportion of viraemic and seropositive wild boar is indicative of wild boar being an important reservoir for APPV.

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.

Detection and genetic analysis of a novel atypical porcine pestivirus from piglets with congenital tremor in Japan

Atypical porcine pestivirus (APPV), which has been confirmed to be associated with congenital tremor (CT) in pigs, is a newly discovered porcine virus that has been found in the Americas, Europe and Asia; however, no report of APPV in Japan has been published. We identified an APPV in the central nervous system of Japanese piglets with CT and firstly determined and analysed the complete genome sequence. Phylogenetic analysis using the complete genome nucleotide sequence of the Japanese APPV, named Anna/2020, and those of APPVs from the NCBI database showed that APPVs were divided into three genotypes (genotypes 1 to 3), and that Anna/2020 clustered with the genotype 3 APPV strains, but distantly branched from these strains. Pairwise complete coding region nucleotide sequence comparisons revealed that there was 94.0%- 99.7% sequence identity among the genotype 3 strains, while Anna/2020 showed 87.0%-89.3% identity to those genotype 3 strains, suggesting that Anna/2020 represents a novel APPV lineage within genotype 3. Retrospective examinations using RT-PCR revealed one genotype 1 and two novel genotype 3 APPVs from pigs without CT, and that novel genotype 3 APPVs have been prevalent in Japan since at least 2007.

Atypical Porcine Pestiviruses: Relationships and Conserved Structural Features

For two decades, the genus pestivirus has been expanding and the host range now extends to rodents, bats and marine mammals. In this review, we focus on one of the most diverse pestiviruses, atypical porcine pestivirus or pestivirus K, comparing its special traits to what is already known at the structural and functional level from other pestiviruses.

Detection of Atypical Porcine Pestivirus in Piglets from Danish Sow Herds

Atypical porcine pestivirus (APPV) was first discovered in North America in 2015 and was later shown to be associated with congenital tremor (CT) in piglets. CT is an occasional challenge in some Danish sow herds. Therefore, we initiated an observational case control study to clarify a possible relationship between CT and APPV in Danish pig production. Blood samples were collected from piglets affected by CT (n = 55) in ten different sow herds and from healthy piglets in five sow herds without a history of CT piglets (n = 25), as well as one sow herd with a sporadic occurrence of CT (n = 5). APPV was detected by RT-qPCR in all samples from piglets affected by CT and in three out of five samples from piglets in the herd with a sporadic occurrence of CT. In the herds without a history of CT, only one out of 25 piglets were positive for APPV. In addition, farmers or veterinarians in CT-affected herds were asked about their experience of the issue. CT is most often seen in gilt litters, and a substantial increase in pre-weaning mortality is only observed in severe cases. According to our investigations, APPV is a common finding in piglets suffering from CT in Denmark.

Genetic diversity and prevalence of Atypical Porcine Pestivirus in the Midwest of US swine herds during 2016-2018

Atypical porcine pestivirus (APPV), a highly divergent pestivirus, has a wide geographical distribution around the world. APPV is known to cause type A-II congenital tremors in newborn piglets. The main objective of this study is to access APPV prevalence in the US swine herds utilizing a newly developed quantitative real-time RT-PCR assay. Retrospective analysis of 1,785 samples revealed a 19.0% prevalence in Midwest swine herds over a period of three years (2016-2018). Among all clinical and field samples that were APPV positive, 82 samples (24.19%) were also positive for one or more swine viral pathogens. Two APPV US strains identified in this study demonstrated significant sequence diversity (~12% in full genome) compared to the first reported APPV strain from the United States in 2014. Of the two strains identified in this study, USA/023005/2016 is closer to two strains identified in Germany, and USA/047310/2017 shares more similarities with two US strains including Minnesota-1 and ISDVDL2014016573. Partial NS5B sequences (9127-9836 nt of the polyprotein gene) obtained from 54 APPV-positive samples revealed considerable sequence diversity, ranging from 85.8% to 100% nucleotide identity, within the US strains in samples from different geographic regions. Analysis of all US samples indicates high prevalence of APPV in Minnesota (37.35%), followed by Illinois (32.86%), Iowa (30.60%) and Kansas (21.89%). APPV was detected in 15.48% of samples assayed from 2017, slightly higher than that in 2016 (13.08%), but much lower than 2018 (28.77%). Among the various sample types tested, oral fluid samples had the highest prevalence and lowest average Ct value suggesting their suitability as a reliable diagnostic specimen for APPV detection. Overall, sequence variation among APPV strains and prevalence of the pathogen within the United States provides a basis for understanding the genetic diversity and molecular epidemiology of APPV in the US swine herds.