Rapid detection of high consequence and emerging viral pathogens in pigs.

Introduction: An increasing emergence of novel animal pathogens has been observed over the last decade. Viruses are a major contributor to the increased emergence and therefore, veterinary surveillance and testing procedures are greatly needed to rapidly and accurately detect high-consequence animal diseases such as Foot and Mouth Disease, Highly Pathogenic Avian Influenza, Classical Swine Fever, and African Swine Fever. The major detection methods for such diseases include real-time PCR assays and pathogen-specific antibodies among others. However, due to genetic drift or -shift in virus genomes, failure to detect such pathogens is a risk with devastating consequences. Additionally, the emergence of novel pathogens with no prior knowledge requires non-biased detection methods for discovery. Methods: Utilizing enrichment techniques coupled with Oxford Nanopore Technologies MinION™ sequencing platform, we developed a sample processing and analysis pipeline to identify DNA and RNA viruses and bacterial pathogens from clinical samples. Results and discussion: The sample processing and analysis pipeline developed allows the identification of both DNA and RNA viruses and bacterial pathogens simultaneously from a single tissue sample and provides results in less than 12 h. Preliminary evaluation of this method using surrogate viruses in different matrices and using clinical samples from animals with unknown disease causality, we demonstrate that this method can be used to simultaneously detect pathogens from multiple domains of life simultaneously with high confidence.

Time and temperature stability of Tritrichomonas foetus in phosphate-buffered saline as evaluated by a reverse transcription real-time PCR assay and field analysis.

Tritrichomonas foetus (TF) is a significant reproductive pathogen of cattle, and sample collection, handling, transport, and testing are significant hurdles to surveillance programs. Recent methods have been developed that allow for the direct detection of TF using a reverse transcription real-time PCR (direct RT-qPCR) approach. To evaluate these methods, a comparative analysis was conducted to assess the technical performance of this assay with a commercially available real-time PCR (qPCR) assay. In addition, the evaluation of two types of collection media (PBS and TF transport tube) was conducted that evaluated sample stability from 0 to 3 days when stored at 4°C or 25°C. Extended incubation times for PBS media were also evaluated (5, 7, and 14 days) at both refrigeration and frozen temperatures to evaluate the effect of extended transport time on samples. Limits of detection (LODs), dynamic range, and RNA stability were assessed using lab-cultured TF spiked into samples of normal bovine smegma collected in PBS or TF transport media, and performance was assessed on field samples collected in parallel. 100% agreement was found between direct RT-qPCR and qPCR at 10 parasites/extraction and a LOD of 1 parasite/extraction. Differences in detection were not observed in either collection media when incubated at either temperatures for up to 3 days of incubation. In addition, the extended incubation experiments indicate that samples containing 10 parasites/extraction can be detected at 4°C for 5 days with a mean Cq 26.34 (95% CI: 23.11-29.58) and detected at -20°C for 7 or 14 days, with a mean Cq 29.55 (95% CI: 27.73-31.37). A significant decrease in detectable RNA was observed in samples containing <10 parasites/extraction at -20°C for 14 days, which should be considered for long-term storage. In summary, direct RT-qPCR was found to be equivalent or superior to qPCR and PBS was not significantly different from TF transport media. The findings of the current study allows for more flexibility during sample collection and transport and ultimately enhancement of TF surveillance programs.

Characterization of newly revealed sequences in the infectious myonecrosis virus genome in Litopenaeus vannamei.

Infectious myonecrosis virus (IMNV) causes significant economic losses in farmed shrimp, where associated mortality in ponds can reach 70 %. To explore host/pathogen interactions, a next-generation sequencing approach using lymphoid organ tissue from IMNV-infected Litopenaeus vannamei shrimp was conducted. Preliminary sequence assembly of just the virus showed that there were at least an additional 639 bp at the 5' terminus and 23 nt at the 3' terminus as compared with the original description of the IMNV genome (7561 nt). Northern blot and reverse transcription-PCR analysis confirmed the presence of novel sequence at both ends of the genome. Using 5' RACE, an additional 4 nt were discovered; 3' RACE confirmed the presence of 22 bp rather than 23 bp of sequence. Based on these data, the IMNV genome is 8226 bp in length. dsRNA was used to trigger RNA interference (RNAi) and suppress expression of the newly revealed genome sections at the 5' end of the IMNV genome in IMNV-infected L. vannamei. An RNAi trigger targeting a 376 bp length of the 5' UTR did not improve survival of infected shrimp. In contrast, an RNAi trigger targeting a 381 bp sequence in ORF1 improved survival to 82.2 % as compared with 2.2 % survival in positive control animals. These studies revealed the importance of the new genome sections to produce high-titre infection, and associated disease and mortality, in infected shrimp.

Sequence-optimized and targeted double-stranded RNA as a therapeutic antiviral treatment against infectious myonecrosis virus in Litopenaeus vannamei.

Infectious myonecrosis virus (IMNV) is a significant and emerging pathogen that has a tremendous impact on the culture of the Pacific white shrimp Litopenaeus vannamei. IMNV first emerged in Brazil in 2002 and subsequently spread to Indonesia, causing large economic losses in both countries. No existing therapeutic treatments or effective interventions currently exist for IMNV. RNA interference (RNAi) is an effective technique for preventing viral disease in shrimp. Here, we describe the efficacy of a double-stranded RNA (dsRNA) applied as an antiviral therapeutic following virus challenge. The antiviral molecule is an optimized dsRNA construct that targets an IMNV sequence at the 5' end of the genome and that showed outstanding antiviral protection previously when administered prior to infection. At least 50% survival is observed with a low dose of dsRNA administered 48 h post-infection with a lethal dose of IMNV; this degree of protection was not observed when dsRNA was administered 72 h post-infection. Additionally, administration of the dsRNA antiviral resulted in a significant reduction of the viral load in the muscle of shrimp that died from disease or survived until termination of the present study, as assessed by quantitative RT-PCR. These data indicate that this optimized RNAi antiviral molecule holds promise for use as an antiviral therapeutic against IMNV.

Nucleic-acid based antivirals: augmenting RNA interference to 'vaccinate'Litopenaeus vannamei.

The Pacific white shrimp, Litopenaeus vannamei (Penaeidae: Litopenaeus) has emerged as the dominant farmed shrimp species globally in tropical countries. Rearing animals at high density in semi-intensive or intensive culture systems, and translocating animals across the globe, have created optimum conditions for devastating epizootics. Of the various pathogens that impact shrimp culture, viruses are arguably the most important infectious disease agents that exact devastating economic losses to the industry. Augmenting the RNA interference (RNAi) capacity of shrimp is a promising, emerging solution to prevent disease caused by a variety of highly pathogenic shrimp viruses. Indeed RNAi functions as a primary mechanism of antiviral RNA in arthropods, as was revealed initially in studies of mosquito-virus interactions. Double-stranded RNA (dsRNA) or small interfering RNA (siRNA) can be used as RNAi triggers in vivo in L. vannamei to reduce the pathology associated with virus infection. We explored the efficacy of those triggers as a function of the target gene in the virus genome and show that efficacy is virus-specific and cannot be predicted based on the target gene function or transcript level in an infected cell. Further, we show that carefully designed RNAi triggers provide an immune stimulus that results in specific, long-term protection and therefore suggest that these dsRNA antivirals can function as vaccines in controlling disease.

dsRNA provides sequence-dependent protection against infectious myonecrosis virus in Litopenaeus vannamei.

Viral diseases are significant impediments to the sustainability of shrimp aquaculture. In addition to endemic disease, new viral diseases continue to emerge and cause significant impact on the shrimp industry. Disease caused by infectious myonecrosis virus (IMNV) has caused tremendous losses in farmed Pacific white shrimp (Litopenaeus vannamei) since it emerged in Brazil and translocated to Indonesia. There are no existing antiviral interventions, outside of pathogen exclusion, to mitigate disease in commercial shrimp operations. Here, we describe an iterative process of panning the genome of IMNV to discover RNA interference trigger sequences that initiate a robust and long-lasting protective response against IMNV in L. vannamei. Using this process, a single, low dose (0.02 µg) of an 81 or 153 bp fragment, with sequence corresponding to putative cleavage protein 1 in ORF1, protected 100 % of animals from disease and mortality caused by IMNV. Furthermore, animals that were treated with highly efficacious dsRNA survived an initial infection and were resistant to subsequent infections over 50 days later with a 100-fold greater dose of virus. This protection is probably sequence dependent, because targeting the coding regions for the polymerase or structural genes of IMNV conferred lesser or no protection. Interestingly, non-sequence specific dsRNA did not provide any degree of protection to animals as had been described for other shrimp viruses. Our data indicate that the targeted region for dsRNA is a crucial factor in maximizing the degree of protection and lowering the dose required to induce a protective effect against IMNV infection in shrimp.