The Prevalence of Pathogens among Ticks Collected from Livestock in Kazakhstan

Ticks carry and transmit a wide variety of pathogens (bacteria, viruses and protozoa) that pose a threat to humans and animals worldwide. The purpose of this work was to study ticks collected in different regions of Kazakhstan for the carriage of various pathogens. The collected ticks were examined by PCR for the carriage of various pathogens. A total of 3341 tick samples parasitizing three animal species (cattle, sheep and horses) were collected at eight regions of Kazakhstan. Eight tick species were found infesting animals: Dermacentor marginatus (28.08%), Hyalomma asiaticum (21.28%), Hyalomma anatolicum (17.18%), Dermacentor reticulatus (2.01%), Ixodes ricinus (3.35%), Ixodes persulcatus (0.33%), Hyalomma scupense (12.87%) and Hyalomma marginatum (14.90%). Ticks collected from livestock animals were examined for the pathogen spectrum of transmissible infections to determine the degree of their infection. Four pathogen DNAs (lumpy skin disease virus (LSDV), Coxiella burnetti, Teileria annulata, and Babesia caballi) were detected by PCR in Dermacentor marginatus, Hyalomma asiaticum, Hyalomma scupense, Hyalomma anatolicum. The infection of ticks Dermacentor marginatus and Hyalomma asiaticum collected on cattle in the West Kazakhstan region with LSDV was 14.28% and 5.71%, respectively. Coxiella burnetti was found in the ticks Dermacentor marginatus (31.91%) in the Turkestan region and Hyalomma anatolicum (52.63%) in the Zhambyl region. Theileria annulata was found in ticks Hyalomma scupense (7.32%) and Dermacentor marginatus (6.10%) from cattle in the Turkestan region. Babesia caballi was isolated only from the species Hyalomma scupense (17.14%) in the Turkestan region. There were no PCR-positive tick samples collected from sheep. RNA/DNAs of tick-borne encephalitis virus (TBEV), African swine fever virus (ASFV), Hantavirus hemorrhagic fever with renal syndrome (HFRS), and chlamydia pathogens were not found in ticks. The new data give a better understanding of the epidemiology of tick-borne pathogens and the possibility of the emergence of tick-borne animal diseases in Kazakhstan.


Introduction
Ticks are significant vectors of various diseases that pose serious public health threats and significant economic losses, affecting the health and productivity of animals [1,2]. Ticks transmit a wide range of microorganisms, including protozoa, bacteria, and viruses [3].
The territory of Kazakhstan occupies from the eastern outskirts of the Volga delta in the west to the Altai Mountains in the east, from the West Siberian Plain in the north to the Tien Shan mountain system in the south of the country. The total area is 2724.9 thousand km 2 . The relief of Kazakhstan is mostly flat-more than 80% of the country is dry steppes.
The diversity of landscape and climatic conditions and the animal world of the country creates the prerequisites for the existence of foci of various pathogens, primarily associated with ticks.
Over the past few decades, an increase in both the number of ticks in Kazakhstan and the number of cases of tick-borne diseases (TBD) has been recorded [8,[10][11][12][13].
Research on tick-borne diseases in Kazakhstan is rare. All research findings concerning tick-borne diseases are the results of studies performed within the framework of small scientific projects. These studies are insufficient to better understand the risk of tick-borne infections in different ecological zones. There is no state program to study the prevalence of pathogens among ticks in Kazakhstan. Therefore, many issues of the current state of tick populations and their epidemiological significance in the territory remain insufficiently studied. The current situation on the spread of ixodid ticks-potential carriers of infections-in the Republic of Kazakhstan requires further study of the ranges, abundance and infection of these arthropods, as well as the establishment of their epidemiological significance. Eliminating this deficiency is the goal of this study, studying ticks collected in different regions of Kazakhstan for the carriage of various pathogens.
LSDV DNA was detected in Dermacentor marginatus (14.28%) and Hyalomma asiaticum (5.71%) collected from cattle in the Bokey Orda district of the West Kazakhstan region. Coxiella burnetti DNA was detected in Dermacentor marginatus (31.91%) collected from cattle in the Otrar district of Turkestan region and Hyalomma anatolicum (52.63%) in Taraz city of Zhambyl region. Teileria annulata DNA was found in Hyalomma scupense (7.32%) and Dermacentor marginatus (6.10%) collected from cattle in the Tolebi district of Turkestan region. Babesia caballi DNA was isolated only in Hyalomma scupense (17.14%) in the Tolebi district of Turkestan region ( Figure 2). There were no PCR-positive tick samples collected from sheep.
As a result of data analysis of Coxiella burnetii (GenBank accession number OP122559, OP046711, OP046710), it was found that the sequenced region of the IS1111A gene, was RNA/DNA of TBEV, ASFV, HFRS, and chlamydia pathogens were not found in ticks.

Discussion
Ticks play a substantial role as vectors of pathogens. Pathogens transmitted are responsible for the majority of the vector-borne diseases in temperate regions o ica, Europe and Asia. According to some researchers, more than 100,000 cases pe tick-borne diseases are recorded in the world [14]. Tick-borne pathogens affect 80 world's cattle and are widespread throughout the world, especially in developin tries where little attention is paid to the study of tick-borne animal diseases [15, is the first comprehensive study of tick-borne viral, bacterial, rickettsial and pr pathogens of human and veterinary interest in Kazakhstan.

Discussion
Ticks play a substantial role as vectors of pathogens. Pathogens transmitted by ticks are responsible for the majority of the vector-borne diseases in temperate regions of America, Europe and Asia. According to some researchers, more than 100,000 cases per year of tick-borne diseases are recorded in the world [14]. Tick-borne pathogens affect 80% of the world's cattle and are widespread throughout the world, especially in developing countries where little attention is paid to the study of tick-borne animal diseases [15,16]. This is the first comprehensive study of tick-borne viral, bacterial, rickettsial and protozoan pathogens of human and veterinary interest in Kazakhstan.
In our study, four species of ticks (Dermacentor marginatus, Hyalomma asiaticum, Hyalomma anatolicum, Hyalomma scupense) out of eight tested were PCR-positive and considered as vectors of pathogens among domestic animals. Lumpy skin disease, Q fever, babesiosis, and theileriosis viral DNAs were detected in ticks from various regions of Kazakhstan.
Lumpy skin disease (LSD) is an infectious disease that is transmitted by various arthropods [21]. Almost to the end of the last century, the disease was previously reported only in the countries of Central and South Africa, and only in the 1980s was it first introduced to the Middle East [22]. In 2014, the disease spread to Azerbaijan [23], then from there, it spread to Russia and resulted in significant economic losses [24]. In the European Union, namely Greece, LSD was discovered in 2015. In 2016, the list had grown, with Armenia, Bulgaria, Serbia, Albania and Kazakhstan [24]. Later, LSD outbreaks were reported in Bangladesh, India, China, Nepal, Bhutan, Vietnam, Myanmar, Sri Lanka, Thailand, Malaysia, and Laos [25,26].
Until 2015, the disease had not been reported in northern temperate regions and there were many gaps in the knowledge about potential carriers of LSDV. The first report on the transmission of LSDV by ticks in northern latitudes was confirmed after LSD outbreaks in Russia. Viral DNA has been detected at least in 13 species of ixodid ticks belonging to six genera. LSDV genome has been detected in Ixodes ricinus (16.3% of the total studied ticks), Boophilus annulatus (14.3%), Dermacentor marginatus (13.8%), Hyalomma marginatum (11.6%), and Haemaphysalis scupense (8.1%). This led to the conclusion that ixodid ticks may have acted as LSDV reservoirs during the 2015 outbreaks, but more detailed studies are required to confirm these preliminary results [27]. In our studies, LSDV DNA was detected from the tick species Dermacentor marginatus (14.28%) and Hyalomma asiaticum (5.71%) collected from cattle in the West Kazakhstan region. These data are consistent with the results of our previous studies, where it was shown that Dermacentor marginatus and Hyalomma asiaticum ticks taken from sick animals during the LSD epizootics in the Atyrau region were involved in LSDV transmission [28]. The presence of PCR-positive ticks in the western regions of Kazakhstan is possibly associated with the movement of wild animals, which are possibly asymptomatic carriers of this disease. We hypothesize that ticks remained infected after feeding with infected blood during the outbreak in Atyrau region of Kazakhstan or the border regions of Russia. Subsequently, they spread to the territory of the West Kazakhstan region through wild animals. Currently, the largest population of saigas (about 1.0 million individuals) inhabits Western Kazakhstan, which migrates through the territory of Atyrau and West Kazakhstan regions, as well as the border regions of the Russian Federation and possibly may transmit the LSDV from infected ticks. To confirm this hypothesis, it is necessary to conduct monitoring studies both in the saiga population and in other wild artiodactyl animals.
Q fever is an infectious disease caused by Coxiella burnetii that is prevalent throughout the world and has a significant impact on animal welfare and human health [29,30]. The outbreak of Q fever in the Netherlands is an example of this [31]. Between 2007 and 2010, during the Q fever epidemic in the Netherlands, more than 4000 human cases were confirmed and over 50,000 dairy goats were slaughtered. From 2011 to 2016, Germany had the highest prevalence of Q fever, with an average of 240 cases per year (incidence of 2 per 100,000), followed by France, Spain and Hungary, with 180, 110 and 60 cases per year, respectively [32]. In China, there have been 29 reports of Q fever over the last 25 years (1989-2013), almost half of which occurred over the last 5 years [33]. The overall prevalence of Coxiella burnetii infection in China is 10% in humans, 15% in cattle, and 12% in goats.
However, knowledge of Coxiella burnetii remains limited to this day. Besides the main route of transmission via inhalation of infectious aerosols, ticks are still under debate as potential vectors for Coxiella burnetii. The importance of ticks in the epidemiology of Q fever remains controversial, although a sufficient number of studies have shown the presence of Coxiella burnetii in ticks [34]. Recent studies have shown the prevalence of 4.8% of Coxiella burnetii infection among 25 different tick species in 23 European countries. Significantly higher prevalence was observed in southern European countries [34].
Q fever has been reported in Kazakhstan since the early 1950s [35]. There are no data about the prevalence of Q fever among wild and domestic animals in the territory of Kazakhstan in the available literature. There are separate records on the identified seropositivity for Coxiella burnetii in saigas [36]. There is very little research evidence of ticks for the carriage of Coxiella burnetii in various regions of the country. Our studies showed PCR-positive results for Coxiella burnetii in Dermacentor marginatus (31.91%) collected in Turkestan region and Hyalomma anatolicum (52.63%) in the Zhambyl region. These data are consistent with the results of our previous studies [9].
The authors have shown that in 2013, in the Kyzylorda region, the tick infestation of Coxiella burnetii in Hyalomma asiaticum and Dermacentor marginatus was 4% and 2.3%, respectively. In the present study, we did not detect positive samples in other regions of Kazakhstan. However, according to some researchers, Coxiella burnetii was previously detected in the northern and western regions [37]. To obtain a comprehensive assessment of the prevalence of Coxiella burnetii in various regions of Kazakhstan, it is necessary to continue monitoring studies with a larger number of samples.
The prevalence of diseases caused by blood parasites in Kazakhstan is poorly understood. There are isolated reports indicating the presence of these diseases among animals and ticks in Kazakhstan [7,44].
Studies conducted by a group of scientists from Kazakhstan, China and Hungary showed that Theileria annulata are present among ticks Rhipicephalus turanicus in the Almaty region, Dermacentor marginatus in the Turkestan region and Rhipicephalus turanicus in the Zhambyl region. The prevalence among ticks ranged from 2.30% to 33.33% [8]. In our studies, Theileria annulata DNA was detected in Hyalomma scupense (7.32%) and Dermacentor marginatus (6.10%) tick species collected from cattle. All PCR-positive ticks were collected in Turkestan region. These results are consistent with the results of our previous studies [7] and confirm that Dermacentor marginatus is the main carrier of Theileria annulata in Turkestan region. The detection of theileria in Hyalomma scupense indicates that this tick species is a potential vector for this disease.
Equine Piroplasmosis (EP) is widespread in almost all countries of the world and cause enormous harm to agriculture [45,46]. Animals of each species have their own specific pathogens. The causative agents of equine piroplasmosis are Babesia caballi and Theileria equi. Equine babesiosis is endemic in most countries of the tropical and subtropical regions of the world [47][48][49]. However, there is reported evidence of the presence of this disease in EU countries, such as the Netherlands and Italy [50,51]. The global spread and distribution of equine piroplasmidoses depends on the availability of competent tick vectors capable of transmitting these pathogens to horses. Ticks are the definitive hosts and vectors of Babesia caballi and Theileria equi. Scoles and Ueti described 33 Ixodid tick species belonging to six genera as competent vectors responsible for equine piroplasmosis [52]. The authors have shown that ticks belonging to the genera Hyalomma, Dermacentor, Rhipicephalus are the biological vectors of Theileria equi and Babesia caballi, while other genera of ticks, including Amblyomma, Haemaphysalis and Ixodes, are suspected but not confirmed. The list is probably not exhaustive since most research studies are focused on only a small subset of ticks closely related to horses.
The presence of Theileria species in livestock and wild animals or their ticks is not well studied in our country. Recent studies have suggested that causative agents of piroplasmosis in horses are present in ticks in the territory of Almaty and Turkestan regions [7]. In their study, Sang C. et al. showed the presence of Babesia caballi DNA in one Dermacentor marginatus tick and Theileria equi DNA in two Hyalomma asiaticum ticks in the Almaty region. The same study also revealed that Babesia caballi DNA was found in 2 ticks and Theileria equi DNA in 6 Dermacentor marginatus ticks in Turkestan region.
In our studies, the DNA of Babesia caballi was isolated only from the Hyalomma scupense (17.14%) specie collected from horses. All PCR-positive ticks were collected in Turkestan region. Based on the data obtained, it can be assumed that Hyalomma scupense is one of the likely vectors of this disease. To confirm these data, it is necessary to continue studies on a larger number of samples.
Our results have increased awareness about the distribution of tick-borne pathogens in Kazakhstan. However, study results on tick distribution, population and disease presence are insufficient in Kazakhstan to better understand the risk of tick-borne infections within various ecologic zones. Further research on ticks in different regions is needed to assess the current situation in the country. Further research on ticks in different regions is required to assess the current situation in the country.

Study Area and Collection of Samples
We conducted a field sampling of ticks in April, May of 2021 and 2022 in rural area in Turkestan, West Kazakhstan, Zhambyl, North Kazakhstan and Almaty regions. A total of 3341 ixodid ticks (Dermacentor marginatus, Dermacentor reticulatus, Ixodes ricinus, Ixodes persulcatus, Hyalomma asiaticum, Hyalomma scupense, Hyalomma marginatum, and Hyalomma anatolicum) were collected from animals ( Table 2).
Adult ticks were sampled using tweezers directly from cattle, horses, and sheep of both sexes. Ticks were collected from different body parts of animals as the inner side of the thigh, udder, scrotum, neck, and armpit of the animals. Ticks were transported for analysis on the day of collection. In the absence of such a possibility, adult ticks were maintained alive in plastic vials with grass for 10 days in a cool place or refrigerated. Each vial contained a detailed label with the following information for each included sample: date, type and number of examined animals, and the collection place. Each arthropod was identified using the stereomicroscope RS0745 (Altami, Saint Petersburg, Russia). Species identification of ticks was confirmed morphologically [53,54].
While sampling and accounting, sampling staff had to follow special precautions as wearing a personal protective clothing with a high neckline and cuffs, also periodic selfand mutual inspections for the presence of ticks.  Cattle  10  95  -15  7  --40  35   Sheep  22  37  -----25  18 Horse