Rapid Sequence-Based Characterization of African Swine Fever Virus by Use of the Oxford Nanopore MinION Sequence Sensing Device and a Companion Analysis Software Tool.

African swine fever virus (ASFV) is the causative agent of a severe and highly contagious viral disease of pigs that poses serious economic consequences to the swine industry due to the high mortality rate and impact on international trade. There is no effective vaccine to control African swine fever (ASF), and therefore, efficient disease control is dependent on early detection and diagnosis of ASFV. The large size of the ASFV genome (∼180 kb) has historically hindered efforts to rapidly obtain a full-genome sequence. Rapid acquisition of data is critical for characterization of the isolate and to support epidemiological efforts. Here, we investigated the capacity of the Oxford Nanopore MinION sequence sensing device to act as a rapid sequencing tool. When coupled with our novel companion software script, the African swine fever fast analysis sequencing tool (ASF-FAST), the analysis of output data was performed in real time. Complete ASFV genome sequences were generated from cell culture isolates and blood samples obtained from experimentally infected pigs. Removal of the host-methylated DNA from the extracted nucleic acid facilitated rapid ASFV sequence identification, with reads specific to ASFV detected within 6 min after the initiation of sequencing. Regardless of the starting material, sufficient sequence was available for complete genome resolution (up to 100%) within 10 min. Overall, this paper highlights the use of Nanopore sequencing technology in combination with the ASF-FAST software for the purpose of rapid and real-time resolution of the full ASFV genome from a diagnostic sample.

Development of a Feature and Template-Assisted Assembler and Application to the Analysis of a Foot-and-Mouth Disease Virus Genotyping Microarray.

Several RT-PCR and genome sequencing strategies exist for the resolution of Foot-and-Mouth Disease virus (FMDV). While these approaches are relatively straightforward, they can be vulnerable to failure due to the unpredictable nature of FMDV genome sequence variations. Sequence independent single primer amplification (SISPA) followed by genotyping microarray offers an attractive unbiased approach to FMDV characterization. Here we describe a custom FMDV microarray and a companion feature and template-assisted assembler software (FAT-assembler) capable of resolving virus genome sequence using a moderate number of conserved microarray features. The results demonstrate that this approach may be used to rapidly characterize naturally occurring FMDV as well as an engineered chimeric strain of FMDV. The FAT-assembler, while applied to resolving FMDV genomes, represents a new bioinformatics approach that should be broadly applicable to interpreting microarray genotyping data for other viruses or target organisms.

Detection of African swine fever, classical swine fever, and foot-and-mouth disease viruses in swine oral fluids by multiplex reverse transcription real-time polymerase chain reaction.

African swine fever (ASF), classical swine fever (CSF), and foot-and-mouth disease (FMD) are highly contagious animal diseases of significant economic importance. Pigs infected with ASF and CSF viruses (ASFV and CSFV) develop clinical signs that may be indistinguishable from other diseases. Likewise, various causes of vesicular disease can mimic clinical signs caused by the FMD virus (FMDV). Early detection is critical to limiting the impact and spread of these disease outbreaks, and the ability to perform herd-level surveillance for all 3 diseases rapidly and cost effectively using a single diagnostic sample and test is highly desirable. This study assessed the feasibility of simultaneous ASFV, CSFV, and FMDV detection by multiplex reverse transcription real-time polymerase chain reaction (mRT-qPCR) in swine oral fluids collected through the use of chewing ropes. Animal groups were experimentally infected independently with each virus, observed for clinical signs, and oral fluids collected and tested throughout the course of infection. All animal groups chewed on the ropes readily before and after onset of clinical signs and before onset of lameness or serious clinical signs. ASFV was detected as early as 3 days postinoculation (dpi), 2-3 days before onset of clinical disease; CSFV was detected at 5 dpi, coincident with onset of clinical disease; and FMDV was detected as early as 1 dpi, 1 day before the onset of clinical disease. Equivalent results were observed in 4 independent studies and demonstrate the feasibility of oral fluids and mRT-qPCR for surveillance of ASF, CSF, and FMD in swine populations.

Regional variation in mRNA transcript abundance within the ventricular wall.

Previous studies have shown that regional variation in ion channel gene expression contributes to electrical heterogeneity within the walls of the cardiac ventricles. To map the extent of regional variation in gene expression in the ventricular walls and to begin to understand its genesis we have performed a microarray analysis of gene expression in the epicardial and endocardial tissues of the rat adult left ventricle. While the vast majority of the genes are expressed at uniform levels across the ventricular wall, a total of 36 transcripts (representing less than 0.1% of the genes expressed in the ventricle) are expressed more abundantly in either epicardium or endocardium. One of these differentially expressed genes is the sodium channel gene Scn5a, which is expressed at higher levels in the endocardium than in the epicardium of rat heart. The transcription factor genes Irx3, Irx5 and Etv1 were found to be expressed in transmural gradients across the ventricular wall of rat heart and also of canine heart. The Irx3 and Irx5 genes were expressed in an inverse pattern to that of the Kcnd2 (Kv4.2) gene in rat heart, suggesting that these transcription factors may act as negative regulators of Kcnd2 expression in vivo.

Comparison of different probe-level analysis techniques for oligonucleotide microarrays.

Three different software packages for the probe-level analysis of high-density oligonucleotide microarray data were compared using an experiment-derived data set that was validated using real-time PCR. The efficiency with which these three programs could identify true positives in this data set was assessed. In addition, estimates of false-positive and false-negative rates were determined. The performance of the programs using very small data sets was also compared, and recommendations for use are suggested.

Concordant expression of KChIP2 mRNA, protein and transient outward current throughout the canine ventricle.

Expression of the transient outward K+ current (Ito) was analysed in nine different regions of the canine ventricle. In addition to the previously described transmural gradients in the right and left ventricular free walls, an inverted U-shaped pattern of Ito expression was observed in the interventricular septum. The mRNA and protein expression for the K+ channel beta subunit KChIP2 were examined in the same tissues. The KChIP2 protein levels closely matched mRNA expression in all regions of the ventricle and paralleled the density of Ito. The global pattern of gene expression in human epicardial and endocardial tissue was examined using microarrays. Only 0.1 % of the genes expressed in the human ventricle displayed the same expression pattern as the KChIP2 gene in left ventricle. It is unlikely, therefore, that the reported distribution of KChIP2 protein within the ventricle can be explained by a cross-reaction of the anti-KChIP2 antibody with a different protein. It is concluded that transcriptional regulation of the KChIP2 gene is a primary determinant of Ito expression in heart.