Melvyn Quan

Development and evaluation of real-time PCR assays for the quantitative detection of Babesia caballi and Theileria equi infections in horses from South Africa

A quantitative real-time polymerase chain reaction (qPCR) assay using a TaqMan minor groove binder (MGB) probe was developed for the detection of Babesia caballi infection in equids from South Africa. Nine previously published sequences of the V4 hypervariable region of the B. caballi 18S rRNA gene were used to design primers and probes to target unique, conserved regions. The B. caballi TaqMan MGB qPCR assay was shown to be efficient and specific. The detection limit, defined as the concentration at which 95% of positive samples can be detected, was determined to be 0.000114% parasitized erythrocytes (PE). We further evaluated a previously reported Theileria equi-specific qPCR assay and showed that it was able to detect the 12 T. equi 18S rRNA sequence variants previously identified in South Africa. Both qPCR assays were tested on samples from two ponies experimentally infected with either T. equi or B. caballi. The qPCR assays were more sensitive than the indirect fluorescent antibody test (IFAT) and the reverse-line blot (RLB) during the early onset of the disease. The assays were subsequently tested on field samples collected from 41 horses, resident on three stud farms in the Northern Cape Province, South Africa. The IFAT detected circulating T. equi and B. caballi antibody in, respectively, 83% and 70% of the samples. The RLB detected T. equi parasite DNA in 73% of the samples, but none of the samples were positive for B. caballi, although 19 T. equi-positive samples also hybridized to the Babesia genus-specific probe. This could indicate a mixed T. equi and B. caballi infection in these samples, with either the B. caballi parasitaemia at a level below the detection limit of the B. caballi RLB probe, or the occurrence of a novel Babesia genotype or species. In contrast, the qPCR assays correlated fairly well with the IFAT. The B. caballi TaqMan MGB qPCR assay was able to detect B. caballi parasite DNA in 78% of the samples. The T. equi-specific qPCR assay could positively detect T. equi DNA in 80% of the samples. These results suggest that the qPCR assays are more sensitive than the RLB assay for the detection of T. equi and B. caballi infections in field samples.

Molecular epidemiology of the African horse sickness virus S10 gene

Between 2004 and 2006, 145 African horse sickness viruses (AHSV) were isolated from blood and organ samples submitted from South Africa to the Faculty of Veterinary Science, University of Pretoria. All nine serotypes were represented, with a range of 3-60 isolates per serotype. The RNA small segment 10 (S10) nucleotide sequences of these isolates were determined and the phylogeny investigated. AHSV, bluetongue virus (BTV) and equine encephalosis virus (EEV) all formed monophyletic groups and BTV was genetically closer to AHSV than EEV. This study confirmed the presence of three distinct S10 phylogenetic clades (alpha, beta and gamma). Some serotypes (6, 8 and 9 in alpha; 3 and 7 in beta; 2 in gamma) were restricted to a single clade, while other serotypes (1, 4 and 5) clustered into both the alpha and gamma clades. Strong purifying selection was evident and a constant molecular clock was inappropriate. The S10 gene is the second most variable gene of the AHSV genome and the use of S10 in molecular epidemiology was illustrated by an AHS outbreak in the Western Cape in 2004. It was shown that two separate AHSV were circulating in the area, even though AHSV serotype 1 was the only isolate from the outbreak. The small size of the gene (755-764 bp) and conserved terminal regions facilitate easy and quick sequencing. The establishment of an S10 sequence database is important for characterizing outbreaks of AHS. It will be an essential resource for elucidating the epidemiology of AHS.

Development and optimisation of a duplex real-time reverse transcription quantitative PCR assay targeting the VP7 and NS2 genes of African horse sickness virus.

Nucleotide sequences of 52 South African isolates of African horse sickness virus (AHSV) collected during 2004-2005 and including viruses of all nine AHSV serotypes, were used to design and develop a duplex real-time reverse transcription quantitative PCR (RT-PCR) assay targeting the VP7 (S8) and NS2 (S9) genes of AHSV. The assay was optimized for detection of AHSV in fresh and frozen blood of naturally infected horses. Assay performance was enhanced using random hexamers rather than gene-specific primers for RT, and with denaturation of double-stranded RNA in the presence of random hexamers. The assay was efficient with a linear range of at least five orders of magnitude. The analytical sensitivity of the assay was 132 copies of the target genes (4125 copies per ml of blood), and the assay was at least 10-fold more sensitive than virus isolation on BHK-21 cells. The assay was also highly specific because it did not detect related orbiviruses, such as bluetongue and equine encephalosis viruses.

Sequence heterogeneity in the equi merozoite antigen gene (ema-1) of Theileria equi and development of an ema-1-specific TaqMan MGB assay for the detection of T. equi.

Although a quantitative real-time PCR assay (qPCR) assay for the detection of Theileria equi has been developed and evaluated, it is possible that additional, as yet undetected 18S rRNA gene sequence variants may exist. A qPCR assay targeting a different gene, used in conjunction with the T. equi 18S rRNA qPCR assay, could assist in the detection of all T. equi genotypes in field samples. A T. equi ema-1-specific qPCR (Ueti et al., 2003) was tested on 107 South African field samples, 90 of which tested positive for T. equi antibody using the immuno-fluorescent antibody test (IFAT). The qPCR assay performed poorly, as T. equi was detected in only 67 of the 90 IFAT-positive field samples at quantification cycle (C(q)) values ranging from 27 to 39.95. Furthermore, a high C(q) value of 36.18 was obtained from DNA extracted from a South African in vitro-cultured T. equi WL isolate [1.38% parasitized erythrocytes (PE)] when a low C(q) value (indicative of a high T. equi DNA concentration) was expected. Approximately 600 bp of the ema-1 gene from 38 South African samples were sequenced and BLASTN analysis confirmed all sequences to be merozoite surface protein genes, with an identity of 87.1-100% to previously published T. equi ema-1 gene sequences. Alignment of the sequences revealed extensive sequence variations in the target regions of the primers and probes (Ueti et al., 2003), explaining the poor performance of the qPCR assay. Based on these observations, we developed a new TaqMan minor-groove binder (MGB) probe-based qPCR assay, targeting a more conserved region of the ema-1 gene. This assay was shown to be efficient and specific, and the detection limit, defined as the concentration at which 95% of T. equi-positive samples are detected, was determined to be 1.4 x 10(-4)% PE. The two ema-1 assays were compared by testing 41 South African field samples in parallel. The results suggested that the new assay was more sensitive than the original assay, as T. equi was detected in more samples and at lower C(q) values when the new assay was used. Phylogenetic analyses of the 18S rRNA gene sequences and ema-1 amino acid sequences from the same samples showed inconsistencies between the clades, indicating that the T. equi 18S rRNA genetic groups previously identified in South Africa may not represent distinct T. equi lineages. It is possible that the different T. equi ema-1 genotypes could be related to antigenic variability and pathogenicity and may be associated with clinical differences in equine piroplasmosis cases, but this remains to be elucidated.

Molecular cloning and phylogenetic analysis of Babesia orientalis heat shock protein 70.

The heat shock protein 70 (hsp70) gene of Babesia orientalis was obtained from a cDNA expression library by immunoscreening with B. orientalis infected buffalo sera. The nucleotide sequence of the cDNA was 2192bp with an open reading frame (ORF) of 1944bp encoding a polypeptide of 648 amino acid residues. Phylogenetic analysis of the 1944bp sequence together with 30 inter-erythrocytic protozoa hsp70 nucleotide sequences available from GenBank was performed. The results showed that B. orientalis was occurred within the Babesia clade, and most closely related to B. ovis and B. bovis. Similar topologies were obtained from trees based on apicomplexa parasite 18S rRNA sequence. Meanwhile, the BoHsp70 gene was cloned into pET-32a and subsequently expressed in Escherichia coli Rosetta strain as a Trx-fusion protein. The recombinant hsp70 of B. orientalis (rBoHsp70) was purified and evaluated as an antigen in the western blot. The serum from B. orientalis infected buffalo recognized the 92kDa rBoHsp70 expressed in E. coli Rosetta (DE3) by western blotting. The rabbit antiserum against rBoHsp70 recognized a specific 70kDa band in lysates of B. orientalis infected buffalo erythrocytes. These results suggested that hsp70 gene was well conserved among inter-erythrocytic protozoa and the BoHsp70 might be a diagnostic and candidate vaccine antigen.

Diagnostic accuracy of a duplex real-time reverse transcription quantitative PCR assay for detection of African horse sickness virus

Blood samples collected from 503 suspect cases of African horse sickness (AHS) and another 503 from uninfected, unvaccinated South African horses, as well as 98 samples from horses from an AHS free country, were tested with an AHS virus (AHSV) specific duplex real-time reverse transcription quantitative PCR (RT-qPCR) assay and virus isolation (VI). The diagnostic sensitivity and specificity of this AHSV RT-qPCR assay and VI were estimated using a 2-test 2-population Bayesian latent class model which made no assumptions about the true infection status of the tested animals and allowed for the possibility of conditional dependence (correlation) in test results. Median diagnostic sensitivity and specificity of the AHSV RT-qPCR were 97.8% and 99.9%, respectively. Median diagnostic specificity of virus isolation was >99% whereas the estimated diagnostic sensitivity was 44.2%. The AHSV RT-qPCR assay provides for rapid, high-throughput analysis of samples, and is both analytically and diagnostically sensitive and specific. This assay is potentially highly useful for demonstrating freedom or infection of horses with AHSV, thus it is appropriate that its reproducibility be evaluated in other laboratories as a global standard for detection of AHSV.

African horse sickness in naturally infected, immunised horses

To determine whether subclinical cases, together with clinical cases, of African horse sickness (AHS) occur in immunised horses in field conditions, whole blood samples were collected and rectal temperatures recorded weekly from 50 Nooitgedacht ponies resident in open camps at the Faculty of Veterinary Science, University of Pretoria, Onderstepoort, during 2008-2010. The samples were tested for the presence of African horse sickness virus (AHSV) RNA by a recently developed real-time RT-PCR. It was shown that 16% of immunised horses in an AHS endemic area were infected with AHSV over a 2 year period, with half of these (8%) being subclinically infected. The potential impact of such cases on the epidemiology of AHS warrants further investigation.

Use of Confocal Immunofluorescence Microscopy To Localize Viral Nonstructural Proteins and Potential Sites of Replication in Pigs Experimentally Infected with Foot-and-Mouth Disease Virus

ABSTRACT Replication of foot-and-mouth disease virus in infected pig epithelium has been studied by immunofluorescence labeling of the viral nonstructural protein 3ABC and confocal microscopy. The results were correlated with viral RNA copy numbers in tissue samples from adjacent sites determined by reverse transcription-PCR (RT-PCR). Lesion formation was seen in the tongues and coronary band epithelia of infected pigs 2 days after infection. Viral replication was observed in cells of the epithelium of the tongue and coronary band but not in the associated stromal cells. Infected epithelial cells were present in the stratum spinosum, away from the lesion, with small lesions formed above the basement membrane. Viral replication was markedly reduced in tongue epithelium by day 3 postinfection but remained apparent in the coronary band tissue up to 5 days postinfection. These results were confirmed by the RNA copy number determined by RT-PCR.

Effect of the initial dose of foot-and-mouth disease virus on the early viral dynamics within pigs.

This paper investigates the early viral dynamics of foot-and-mouth disease (FMD) within infected pigs. Using an existing within-host model, we investigate whether individual variation can be explained by the effect of the initial dose of FMD virus. To do this, we consider the experimental data on the concentration of FMD virus genomes in the blood (viral load). In this experiment, 12 pigs were inoculated with one of three different doses of FMD virus: low; medium; or high. Measurements of the viral load were recorded over a time course of approximately 11 days for every 8 hours. The model is a set of deterministic differential equations with the following variables: viral load; virus in the interstitial space; and the proportion of epithelial cells available for infection, infected and uninfected. The model was fitted to the data for each animal individually and also simultaneously over all animals varying only the initial dose. We show that the general trend in the data can be explained by varying only the initial dose. The higher the initial dose the earlier the development of a detectable viral load.

Foot-and-mouth disease viral loads in pigs in the early, acute stage of disease.

The progress and pathogenesis of foot-and-mouth disease virus (FMDV) was studied in infected pigs by observing the development of clinical signs in two separate experiments. Viral loads were determined by real-time quantitative RT-PCR in the liver, spleen, cervical lymph node, mandibular lymph node, retropharyngeal lymph node, soft palate, pharynx, tonsil, tongue and skin (coronary band area). Tissue samples were collected from both inoculated and contact-infected pigs at several time points during infection, and blood samples were collected to assess viraemia and its relationship to tissue viral load. Virus first appeared in the lymph nodes, followed by viraemia and then clinical signs. The results suggested that FMDV accumulated in lymphoid tissue up to six hours after infection, in the tissues drained by the mandibular lymph node and tonsil and then disseminated throughout the body where epithelial cells were the favoured sites of replication.