Molecular and serological prevalence of corridor disease (buffalo associated Theileria parva infection) in cattle populations at the livestock/game interface of KwaZulu-Natal province, South Africa.

Theileria parva are intracellular protozoal parasites responsible for three disease syndromes in cattle, namely East Coast fever (ECF), Corridor disease (CD) and Zimbabwean theileriosis. The increase in reports of CD outbreaks in recent years has raised questions about the probability of adaptation of buffalo-derived T. parva strains in cattle herds adjacent to game reserves. A cross-sectional study was conducted from March 2016 to December 2018 to investigate the extent of occurrence of T. parva infections in cattle in the CD-controlled area of KwaZulu-Natal Province. Blood samples were collected from 1137 cattle from 14 herds and analysed by quantitative real-time PCR (qPCR) and indirect fluorescent antibody test (IFAT) to determine the prevalence of T. parva. A total of 484 samples from 4 of the 14 herds were further tested on qPCR for the presence of T. taurotragi infections. The data were analysed using descriptive statistics and a chi-square test was used to assess association between variables. The overall prevalence of T. parva was 1.3% (95%CI:1-2%) and 19.9% (95%CI:17-22%) on qPCR and IFAT, respectively. The qPCR positive samples were detected in March and May while IFAT positive samples were detected in all seasons sampled, with higher numbers during summer months. The Pearson Chi-squared test showed that T. parva prevalence rates based on both qPCR and IFAT were positively associated with herds with previous history of CD outbreaks (χ2 = 8.594, p = 0.003; χ2 = 69.513, p < 0.001, respectively). The overall prevalence of T. taurotragi was 39.4% (95% CI: 35-44%) with the herd-level prevalence ranging between 35.0% and 43.4%. Possible cross-reaction of T. parva IFAT to T. taurotragi was detected on few samples, however, there was no significant association between T. taurotragi infections and IFAT positivity (χ2 = 0.829, p = 0.363). Results from this study demonstrated the extent of occurrence of subclinical carriers and the level of exposure to T. parva infections in cattle populations at a livestock/game interface area of KwaZulu-Natal Province. The molecular and seroprevalence rates were low when compared with other areas where cattle-adapted T. parva infections are endemic. The adaptation of buffalo-derived T. parva in cattle population resulting in cattle-cattle transmissions seem to be unlikely under the current epidemiological state.

South African Buffalo-Derived Theileria parva Is Distinct From Other Buffalo and Cattle-Derived T. parva.

Theileria parva is a protozoan parasite transmitted by the brown-eared ticks, Rhipicephalus appendiculatus and Rhipicephalus zambeziensis. Buffaloes are the parasite's ancestral host, with cattle being the most recent host. The parasite has two transmission modes namely, cattle-cattle and buffalo-cattle transmission. Cattle-cattle T. parva transmission causes East Coast fever (ECF) and January disease syndromes. Buffalo to cattle transmission causes Corridor disease. Knowledge on the genetic diversity of South African T. parva populations will assist in determining its origin, evolution and identify any cattle-cattle transmitted strains. To achieve this, genomic DNA of blood and in vitro culture material infected with South African isolates (8160, 8301, 8200, 9620, 9656, 9679, Johnston, KNP2, HL3, KNP102, 9574, and 9581) were extracted and paired-end whole genome sequencing using Illumina HiSeq 2500 was performed. East and southern African sample data (Chitongo Z2, Katete B2, Kiambu Z464/C12, Mandali Z22H10, Entebbe, Nyakizu, Katumba, Buffalo LAWR, and Buffalo Z5E5) was also added for comparative purposes. Data was analyzed using BWA and SAMtools variant calling with the T. parva Muguga genome sequence used as a reference. Buffalo-derived strains had higher genetic diversity, with twice the number of variants compared to cattle-derived strains, confirming that buffaloes are ancestral reservoir hosts of T. parva. Host specific SNPs, however, could not be identified among the selected 74 gene sequences. Phylogenetically, strains tended to cluster by host with South African buffalo-derived strains clustering with buffalo-derived strains. Among the buffalo-derived strains, South African strains were genetically divergent from other buffalo-derived strains indicating possible geographic sub-structuring. Geographic sub- structuring was also observed within South Africa strains. The knowledge generated from this study indicates that to date, ECF is not circulating in buffalo from South Africa. It also shows that T. parva has historically been present in buffalo from South Africa before the introduction of ECF and was not introduced into buffalo during the ECF epidemic.

Whole genome sequencing of Theileria parva using target capture.

Protozoan parasite isolation and purification are laborious and time-consuming processes required for high quality genomic DNA used in whole genome sequencing. The objective of this study was to capture whole Theileria parva genomes directly from cell cultures and blood samples using RNA baits. Cell culture material was bait captured or sequenced directly, while blood samples were all captured. Baits had variable success in capturing T. parva genomes from blood samples but were successful in cell cultures. Genome mapping uncovered extensive host contamination in blood samples compared to cell cultures. Captured cell cultures had over 81 fold coverage for the reference genome compared to 0-33 fold for blood samples. Results indicate that baits are specific to T. parva, are a good alternative to conventional methods and thus ideal for genomic studies. This study also reports the first whole genome sequencing of South African T. parva.

Investigations into the carrier-state of Theileria sp. (buffalo) in cattle.

The Theileria are apicomplexan parasites transmitted by ticks to vertebrate hosts. Most Theileria species exhibit some form of host or vector specificity, since under endemic conditions only a limited number of tick species act as vectors and not all vertebrate hosts are able to maintain a persistent carrier state. Data for Theileria sp. (buffalo) suggest host specificity for African buffalo (Syncerus caffer). However, T. sp. (buffalo) infections in cattle co-grazing with African buffalo have been reported in Kenya and schizonts were cultured from these infected cattle, raising questions regarding host specificity. A Corridor disease outbreak in 2013 on a ranch in South Africa where cattle co-grazed with Theileria parva and T. sp. (buffalo) infected buffalo presented the opportunity to investigate the possible carrier-state of T. sp. (buffalo) in cattle using real-time PCR analysis. Almost all buffalo (n = 19, 95%) were infected with T. sp. (buffalo) and showed CP values (22-20) indicative of high parasitemia similar to that observed for buffalo in endemic areas. Conversely, only ~14-27% cattle (n = 69, 100, 96) were positive with CP values (31-40) suggesting low parasitemia and a carrier state epidemiology different from African buffalo. Long term monitoring of T. sp. (buffalo) positive cattle showed that most cattle lost their parasitemia or presented fluctuating parasitemia around the PCR assay detection limit. A single splenectomized animal showed a persistent carrier state. The general trends and epidemiology observed in cattle infected with T. sp. (buffalo) are similar to that seen for buffalo-adapted T. parva, for which a defined carrier state in cattle has not yet been proven. The study suggests that cattle may be infected by T. sp. (buffalo) but are not definitive hosts that play an important part in the epidemiology of this parasite.

Corridor disease (buffalo-associated Theileria parva) outbreak in cattle introduced onto a game ranch and investigations into their carrier-state.

East Coast fever (Theileria parva infection in cattle) was eradicated from South Africa in the mid-1900. However, another form named Corridor disease (CD), associated with T. parva carrier buffaloes exists and outbreaks have increased in endemic areas. The occurrence of a CD carrier state in cattle under field situations has not been demonstrated but remains a subject of controversy. The current study investigated the T. parva carrier state following a severe outbreak in cattle introduced onto a game ranch. Monitoring of the outbreak included clinical signs, mortality, microscopy, serology, real-time PCR and xenodiagnoses. The herd of cattle received block treatment using oxytetracyclines (OTC) by the farmer during the outbreak. Cattle were sampled early during the outbreak and twice within the following 75 days. All buffaloes were tested for a T. parva carrier state. Two batches of questing adult R. appendiculatus were collected at the time of disease occurrence and a year later. These ticks were fed on susceptible cattle under controlled conditions and monitored for disease transmission. Ticks infected with a buffalo-derived stock of T. parva were fed on one bovine under controlled conditions and simultaneously injected with OTC, simulating the infection and treatment method of vaccination and was used as a positive control. Clean R. appendiculatus nymphs were fed on four recovered PCR positive cattle from the outbreak and on the positive control animal. The adult ticks were tested for infectivity by xenodiagnoses on susceptible bovines. For the initial outbreak the CD prevalence was 62.3% with a mortality rate of 29.5%. However, the outbreak was contained by block OTC treatment of the herd since only 3.4% cattle subsequently died until the end of the investigations. Adult ticks fed on one field bovine and the laboratory established T. parva carrier both transmitted fatal infections to susceptible cattle. Ticks fed on two field cattle transmitted T. taurotragi and one failed to transmit any infection. Questing adult R. appendiculatus collected during the outbreak transmitted fatal CD to two bovines while ticks collected a year later transmitted T. taurotragi. These findings demonstrated the effectiveness of disease control either by cattle treatment using OTC simulating the ITM or by intensive cattle dipping following the outbreak or by both interventions. The potential risk of creating carrier cattle by OTC treatment during CD outbreaks should be considered, supporting the continued control measures of segregation of cattle and buffalo herds.