Evaluation of a Real-Time PCR Test for the Detection and Discrimination of Theileria Species in the African Buffalo (Syncerus caffer)

Chaisi, Mamohale E.; Janssens, Michiel Etienne; Vermeiren, Lieve; Oosthuizen, Marinda C.; Collins, Nicola E.; Geysen, Dirk

doi:10.1371/journal.pone.0075827

Cited by 33 publications

(29 citation statements)

References 29 publications

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“…While real-time assays that detect T. orientalis have been developed, most have focused on species-level detection (not discrimination of genotypes) (34), discrimination of different Theileria spp. (43,44), or are only semiquantitative (28). The UIC multiplex qPCR assay developed here was both sensitive and specific for T. orientalis detection compared to cPCR and reliably identified the clinically relevant Ikeda and Chitose genotypes.…”

Section: Discussionmentioning

confidence: 91%

Development and Validation of a Quantitative PCR Assay Using Multiplexed Hydrolysis Probes for Detection and Quantification of Theileria orientalis Isolates and Differentiation of Clinically Relevant Subtypes

et al. 2015

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T heileria orientalis is a vector-borne hemoprotozoan that infects cattle and buffalo and is generally spread by ticks of the Haemaphysalis genus (1-3). Historically, this organism has been referred to as Theileria sergenti, Theileria buffeli, or the T. orientalis/T. sergenti/T. buffeli complex; however, the name T. sergenti is now considered invalid (4), and T. orientalis is commonly used to refer to all (5). From a clinical perspective, T. orientalis can cause anemia, lethargy, jaundice, fever, abortion, and mortality in cattle (6). Clinical infection can also result in decreased milk production in dairy cattle (7). T. orientalis is a conditional pathogen, and while pathogenic forms are largely limited to Eastern Asia and Australasia (5, 6, 8-10), it is frequently detected in asymptomatic animals; these benign forms are globally spread (5,(11)(12)(13)(14). Analysis of the most common genotyping locus (p32), encoding the variable major piroplasm surface protein (MPSP), currently identifies 11 distinct T. orientalis genotypes (13,15,16). Of these genotypes, type 2 (Ikeda) and to a lesser extent type 1 (Chitose) are typically found in association with clinical disease (6,9,10,(17)(18)(19)(20)(21)(22). The presence of pathogenic and benign forms of T. orientalis greatly complicates its clinical diagnosis, with standard blood film analysis unable to identify the pathogenic genotypes.Multiple conventional PCR (cPCR) assays have been published for the identification of T. orientalis in blood samples (9,21,23,24). The most commonly cited assays detect and genotype T. orientalis by amplifying unique regions of the MPSP gene (21). These assays use two universal primers to detect T. orientalis infection and specific forward primers to identify the Ikeda, Chitose, and Buffeli genotypes. While this method is highly sensitive and has been validated in prior studies (19,21), it is not multiplexed and is highly susceptible to PCR inhibitors (6), which are often found in nucleotide extractions obtained from blood (25,26). To overcome inhibition, undiluted and diluted nucleotide extracts can be examined in parallel to prevent false-negative results (6,19,27). However, if multiple reactions per sample are required to determine the presence of infection, the procedure becomes both expensive and time-consuming. Furthermore, cPCR does not give an accurate representation of parasite load and therefore cannot provide an indication of the severity of T. orientalis infection. A recently developed multiplexed tandem PCR (28) is able to discriminate between four genotypes of T. orientalis, but it is only semiquantitative and therefore cannot be used to define a clinical threshold.Hydrolysis probe quantitative PCR (qPCR) assays employ sequence-specific, fluorescently labeled probes attached to duplex-

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Section: Discussionmentioning

confidence: 91%

Development and Validation of a Quantitative PCR Assay Using Multiplexed Hydrolysis Probes for Detection and Quantification of Theileria orientalis Isolates and Differentiation of Clinically Relevant Subtypes

et al. 2015

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“…(buffalo) ( Allsopp et al., 1993 ). Subsequent studies have found this Theileria genotype to be well conserved and widespread in buffalo populations in both Uganda and South Africa, frequently in co-infections with T. parva ( Chaisi et al., 2013; Mans et al., 2011a; Mans et al., 2015; Oura et al., 2011a,b; Pienaar et al., 2011b; Pienaar et al. 2014 ).…”

Section: Introductionmentioning

confidence: 99%

The African buffalo parasite Theileria. sp. (buffalo) can infect and immortalize cattle leukocytes and encodes divergent orthologues of Theileria parva antigen genes

Bishop

Hemmink

Morrison

et al. 2015

International Journal for Parasitology: Parasites and Wildlife

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African Cape buffalo (Syncerus caffer) is the wildlife reservoir of multiple species within the apicomplexan protozoan genus Theileria, including Theileria parva which causes East coast fever in cattle. A parasite, which has not yet been formally named, known as Theileria sp. (buffalo) has been recognized as a potentially distinct species based on rDNA sequence, since 1993. We demonstrate using reverse line blot (RLB) and sequencing of 18S rDNA genes, that in an area where buffalo and cattle co-graze and there is a heavy tick challenge, T. sp. (buffalo) can frequently be isolated in culture from cattle leukocytes. We also show that T. sp. (buffalo), which is genetically very closely related to T. parva, according to 18s rDNA sequence, has a conserved orthologue of the polymorphic immunodominant molecule (PIM) that forms the basis of the diagnostic ELISA used for T. parva serological detection. Closely related orthologues of several CD8 T cell target antigen genes are also shared with T. parva. By contrast, orthologues of the T. parva p104 and the p67 sporozoite surface antigens could not be amplified by PCR from T. sp. (buffalo), using conserved primers designed from the corresponding T. parva sequences. Collectively the data re-emphasise doubts regarding the value of rDNA sequence data alone for defining apicomplexan species in the absence of additional data. ‘Deep 454 pyrosequencing’ of DNA from two Theileria sporozoite stabilates prepared from Rhipicephalus appendiculatus ticks fed on buffalo failed to detect T. sp. (buffalo). This strongly suggests that R. appendiculatus may not be a vector for T. sp. (buffalo). Collectively, the data provides further evidence that T. sp. (buffalo). is a distinct species from T. parva.

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“…Serological tests have been developed to detect circulatory antibodies against the parasites, but these generally have poor sensitivity and specificity due to involving cross-reactions or nonspecific immune responses (Passos et al , 1998), and only detect previous exposure as opposed to current infection. Conventional PCR methods are useful in the detection of particular haemoprotozoan species for which the reagents and conditions have been developed, but can have limitations in the detection of other species and lack scalability (Bilgic et al , 2013; Chaisi et al , 2013; Gubbels et al , 1999; Kundave et al , 2018). In contrast, the deep amplicon sequencing method is potentially providing more reliable and accurate in the automated high throughput analysis of all haemoprotozoan species.…”

Section: Discussionmentioning

confidence: 99%

“…Determination of sequence variations in the hyper-variable 18S rDNA cistron can discriminate between haemoprotozoan parasites (Gubbels et al , 1999) and overcome limitations of traditional gross parasitological methods for the diagnosis of haemoprotozoa at species level (Agudelo et al , 2013; Haanshuus et al , 2013; Lee et al , 2015; Lefterova et al , 2015; Mens et al , 2006; Rougemont et al , 2004; Steenkeste et al , 2009). Various PCR methods (reverse line blot (RLB)-PCR, quantitative (q)PCR, multiple PCR) have been described to amplify the 18S region for sequence determination, but these are low throughput, hence relatively expensive, and can be error-prone (Bilgic et al , 2013; Chaisi et al , 2013; Gubbels et al , 1999; Kundave et al , 2018). These methods depend on the use of species-specific primers and probes, hence can only identify the tested species.…”

Section: Introductionmentioning

confidence: 99%

Development of a deep amplicon sequencing method to determine the proportional species composition of piroplasm haemoprotozoa as an aid in their control

Chaudhry

Rashid

et al. 2019

Preprint

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Piroplasmosis is caused by tick-borne haemoprotozoa of the genera Theileria and Babesia. These parasitic infections can cause serious impact on the health of livestock and production. Multiple piroplasm species can infect a single host, but reliable molecular diagnostic tools are needed with which to understand the composition of these complex parasite communities. Theileria and Babesia vary in their epidemiology, drug sensitivity, pathogenicity and interaction of co-infecting species, but are similar in the animals, become persistent carriers after recovery from primary infection, acting as reservoir hosts. Here, we describe for the first time the use of a deep amplicon sequencing platform to identify proportions of piroplasm species in co-infecting communities and develop the concept of a "haemoprotobiome". First, four phenotypically-verified species of Theileria and Babesia were used to prepare mock pools with random amounts of the parasites and amplified with four different numbers of PCR cycles to assess sequence representation of each species. Second, we evaluated the detection threshold of the deep amplicon sequencing assay for each of the four species and to assess the accuracy of proportional quantification of all four species. Finally, we applied the assay to the field samples to afford insight of the species composition of piroplasm communities in small and large ruminants in the Punjab province of Pakistan. The "haemoprotobiome" concept has several potential applications in veterinary and human research, including understanding of responses to drug treatment; parasite epidemiology and ecology; species interactions during mixed infections; and parasite control strategies.

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Evaluation of a Real-Time PCR Test for the Detection and Discrimination of Theileria Species in the African Buffalo (Syncerus caffer)

Cited by 33 publications

References 29 publications

Development and Validation of a Quantitative PCR Assay Using Multiplexed Hydrolysis Probes for Detection and Quantification of Theileria orientalis Isolates and Differentiation of Clinically Relevant Subtypes

Development and Validation of a Quantitative PCR Assay Using Multiplexed Hydrolysis Probes for Detection and Quantification of Theileria orientalis Isolates and Differentiation of Clinically Relevant Subtypes

The African buffalo parasite Theileria. sp. (buffalo) can infect and immortalize cattle leukocytes and encodes divergent orthologues of Theileria parva antigen genes

Development of a deep amplicon sequencing method to determine the proportional species composition of piroplasm haemoprotozoa as an aid in their control

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