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Research article2024Peer reviewedOpen access

Epidemiology and ecology of the sylvatic cycle of African Swine Fever Virus in Kenya

Obanda, Vincent; Akinyi, Mercy; King'ori, Edward; Nyakundi, Ruth; Ochola, Griphin; Oreng, Purity; Mugambi, Kevin; Waiguchu, Grace Mwihaki; Chege, Mary; Rosenbaum, William; Ylitalo, Erik Bovinder; Back, Anne Tuiskunen; Pettersson, Lisa; Mukunzi, Opanda Silvanos; Agwanda, Bernard; Stenberg-Lewerin, Susanna; Lwande, Olivia Wesula

Abstract

African Swine Fever (ASF) is caused by a DNA virus (AFSV) maintained and transmitted by the Argasid ticks. The re-emergence of the disease in Africa coupled with its rapid spread globally is a threat to the pig industry, food security and livelihoods. The ecology and epidemiology of the ASFV sylvatic cycle, especially in the face of changing land use and land cover, further compounds the menace and impacts of this disease in Kenya. The study aimed to determine the occurrence and distribution of ASFV seroprevalence in warthog populations, the tick vectors and extent of tick infestation of warthog burrows, and the genotypes of ASFV in soft ticks in Kenya. Warthogs from different parts of Kenya were captured and venous blood was centrifuged to harvest sera. Warthog burrows were examined for their conditions and to extract ticks. Sera were analyzed for antibodies against ASFV using a commercial ELISA kit coated with p32 ASFV recombinant protein. Ticks were pooled, DNA extracted and the p72 gene of the ASFV was amplified by qPCR and conventional PCR. The overall seroprevalence of ASFV in warthogs was 87.5%. A total of 228 warthog burrows were examined and 2154 argasid ticks were extracted from the burrows. Tick pools from Kigio Farm and Lewa Wildlife Conservancies were ASFVpositive by qPCR and conventional PCR. ASFV was further confirmed by the Twist Comprehensive Viral Research Panel (TCVRP), which also identified the argasid ticks as Ornithodoros porcinus. . The ticks were infected with virus genotype IX, and their occurrence overlaps with regions of previous ASF outbreaks in domestic pigs. Further, Viruses that could be tick endosymbionts/commensals or due to bloodmeal were detected in ticks by TCVRP; Porcine type-C oncovirus; Pandoravirus neocaledonia; Choristoneura fumiferana granulovirus; ; Enterobacteria phage p7; Leporid herpesvirus 4 isolate; 5; Human Lymphotropic virus; Human herpesvirus 5. In conclusion, our results suggest that infected Ornithodoros spp. seems to have a rich virome, which has not been explored but could be exploited to inform ASF control in Kenya. Further, the ecology of Ornithodoros spp. and burrow-use dynamics are complex and more studies are needed to understand these dynamics, specifically in the spread of ASFV at the interface of wild and domestic pigs. Further, our results provide evidence of genotype IX ASFV sylvatic cycle which through O. porcinus tick transmission has resulted in high exposure of adult common warthogs. Finally, the co-circulation of ASFV genotype IX in the same location with past ASF outbreaks in domestic pigs and presently in ticks brings to focus the role of the interface and ticks on virus transmission to pigs and warthogs.

Keywords

Tick-borne diseases; Microbial community; Food security; Soft ticks; Ornithodoros moubata; Argasid ticks

Published in

Virus Research
2024, Volume: 348, article number: 199434Publisher: ELSEVIER

    UKÄ Subject classification

    Clinical Science
    Pathobiology

    Publication identifier

    DOI: https://doi.org/10.1016/j.virusres.2024.199434

    Permanent link to this page (URI)

    https://res.slu.se/id/publ/131530