Abstract:
In South Africa, resource-poor farmers are negatively affected by death and ill health
of livestock due to high tick infestations. Tick infestations are associated with tick-
borne pathogens causing various diseases that are a major constraint to cattle
farming, a threat to human health and consequently the economy. This has been an
ongoing concern for resource-poor farmers, mostly influenced by the inability to
access veterinary care or proper education on the usage of veterinary products. This
study sought to investigate the presence of ticks and their associated pathogens at
three study sites, namely Harrismith and Phuthaditjhaba in the Free State province as
well as Bergville in KwaZulu Natal. These are three neighbouring towns, where the
point of intersection for livestock is the Drakensberg Mountains, which serve as a
source of vegetation for grazing livestock. Between these three study sites there is
uncontrolled translocation of livestock due to traditional practices and trade and thus
the introduction of several tick species.
Ticks are recognised worldwide as major vectors of several disease-causing
pathogens and are good indicators of pathogen distribution and epidemiology.
However, global warming has result in climate change and consequently expanded tick distribution. Consequently, growing incidences of emerging and re-emerging tick-
borne pathogens capable of causing tick-borne diseases (TBDs) of veterinary and economic importance. These TBDs are major hindrances that constrain cattle farming,
thus culminating in significant losses: threatening food security, global trade, eco-
tourism, and affecting human and livestock health. Therefore, this study sought to identify ticks and detect bacterial tick-borne pathogens
in the three neighbouring towns: Harrismith, Phuthaditjhaba and Bergville using a 16S
rRNA next-generation sequencing (NGS) approach based on the PacBio sequencing
platform. A total of n=50 blood samples were collected from cattle in each study site
and n=418 ticks were collected from these cattle, comprising n=126 ticks from
Harrismith, n=160 from Phuthaditjhaba and n=132 from Bergville. Ticks infesting cattle
were identified morphologically to belong to the genera Rhipicephalus with six species
and Hyalomma with only two species. Harrismith had Rhipicephalus decoloratus, R.
microplus, R. evertsi evertsi, Hyalomma truncatum, H. rufipes, Phuthaditjhaba: R.
appendiculatus R. simus, R. evertsi evertsi, R. afranicus, H. rufipes and Bergville: R.
evertsi evertsi, R. appendiculatus, H. truncatum. Out of n=418 ticks collected, R.
evertsi evertsi with n=332 was the most dominant tick species in the three study sites,
whereas R. decoloratus and R. microplus tick species were only present in Harrismith.
A full-length 16S rRNA gene was amplified and sequenced using PacBio technology
for the identification of bacterial pathogens associated with these ticks. A total of
7,687,581 reads were obtained. Bacterial pathogens identified belonged to the genera
Anaplasma, Mycoplasma and Ehrlichia. Anaplasma species detected were A.
marginale, A. centrale, A. phagocytophilum, A. platys and A. bovis. Mycoplasma
species were M. wenyonii and M. bovis. Ehrlichia species detected were E.
ruminantium and E. canis. Anaplasma marginale, with a relative abundance of 43.5%
in Harrismith, 54.2% in Phuthaditjhaba and 56.2% in Bergville, was the most abundant,
followed by A. platys with 31.5% in Harrismith, 32.9% in Phuthaditjhaba and 22.6% in
Bergville. Mycoplamsa wenyonii was 19.6% Harrismith, 7.8% in Phuthadijthaba and
14% in Bergville. The bacterial composition at the three sites aligned with the tick
vectors identified at the three-study sites. The presence of R. microplus and R.
decoloratus was reported for the first time in Harrismith, while R. turanicus was
identified for the first time in Phuthaditjhaba. This shows that there has been an
expansion in tick distribution because of climate change and possibly other ecological
and anthropogenic factors.