Peer-reviewed veterinary case report
Bluetongue virus infection in farm dogs exposed to sheep in South
By Hanekom, Josef et al.·Published in Transboundary and emerging diseases·2024·Companion Animal Clinical Studies University of Pretoria Faculty of Veterinary Science·View original on PubMed →
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Original publication title: Bluetongue Virus Infection in Farm Dogs Exposed to an Infected Sheep Flock in South Africa.
- Species:
- dog
Plain-English summary
A pregnant Rottweiler living on a sheep farm in South Africa was diagnosed with bluetongue virus (BTV) infection after showing clinical signs. Blood tests revealed that three out of six dogs on the farm had detectable BTV RNA, indicating they were infected, while one additional dog showed antibodies against the virus. The investigation also found that the virus was present in some of the sheep on the farm. Although the dogs were infected, it's uncertain if they can spread the virus to other animals. The situation highlights the risk of bluetongue virus entering new areas through dog importation.
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Abstract
In 2021, a pregnant Rottweiler dog living on a sheep farm was diagnosed with clinical bluetongue (BT) infection. This study reports on the investigation of this farm where bluetongue virus (BTV) infection was diagnosed in this atypical host species. Samples were collected during farm visits 14, 28, 60, and 89 days after the onset of clinical signs in the pregnant Rottweiler. Blood was collected from all farm dogs ( = 6) and tested for BTV genome using a reverse-transcriptase quantitative PCR (RT-qPCR) assay and BTV antibodies with the competitive ELISA (cELISA) and dogs positive by RT-qPCR were further tested using virus neutralization (VN) serological testing. Blood was also collected from 16 sick sheep and tested using RT-qPCR. Midges were trapped on the study farm using an Onderstepoort UV light trap placed above a sheep pen for 36 hr at the first farm (14 days) visit. Parous/gravid midges were tested by BTV RT-qPCR in batches of up to 200 midges per species. Blood-fed midges ( = 308) were tested using a PCR species probe (KAPA Multiplex Master Mix) to identify the host species on which the midge had fed. Three dogs ( = 3/6) had detectable BTV RNA with RT-qPCR and high VN antibody titers to BTV. All RT-qPCR-positive dogs and one additional dog tested cELISA seropositive ( = 4/6). Bluetongue virus RNA was detected in 5/16 sheep tested. The most abundant midge species was(99.3%) and BTV was only detected in this species ( = 3/4 batches of 200 parous midges). Dog blood was not detected in any blood-fed midges tested. The occurrence of natural BT viraemia in exposed dogs creates a potential risk of BTV entry into BT-free countries through dog importation. It remains unclear whether BT viremia in dogs is capable of onward transmission.
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Search related cases →Original publication on PubMed: https://pubmed.ncbi.nlm.nih.gov/40303113/