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REVIEW article

Front. Vet. Sci., 26 July 2022
Sec. Parasitology
This article is part of the Research Topic Soft Ticks as Parasites and Vectors View all 10 articles

A review of argasid ticks and associated pathogens of China

  • Hebei Key Laboratory of Animal Physiology, Biochemistry and Molecular Biology, College of Life Sciences, Hebei Normal University, Shijiazhuang, China

It has been recorded 221 species of soft ticks in the world. However, the classification system of Argasidae is still unclear with nearly two-third controversial species in genus level. Therefore, comprehensive research is still necessary. In 2016, Wen and Chen overviewed the valid species of soft ticks in China for the first time. Up to now, the soft tick fauna of China remains poorly known. Although several studies have been undertaken, the information regarding soft ticks and associated diseases are fragmentary. To facilitate the future study of this group, the scattered information on soft ticks of China is herein synthesized. Toward the end of 2021, 15 valid species of argasid ticks have been reported, of these, 9 species (60%) including Argas beijingensis, A. japonicus, A. persicus, A. sinensis, A. vespertilionis, A. vulgaris, Ornithodoros lahorensis, O. tartakovskyi, and O. papillipes have been recorded biting humans. Argas persicus is the most common species, and its borne pathogens are widely investigated, while most other argasid ticks are not sufficiently studied in China. Here, we summarize detailed information regarding hosts, geographical distribution, molecular data, and vector roles of argasid ticks in China.

Introduction

Ticks are obligate hematophagous ectoparasites of a wide variety of mammals, birds, reptiles, and amphibians. They cause direct injuries by blood-sucking and are important vectors of a large variety of human, domestic, and wild-animal pathogens, including viruses, bacteria, and protozoans, which can damage to livestock production and human health (1). Tick species can be grouped into three current families (Argasidae, Ixodidae, and Nuttalliellidae) and one extinct family (Deinocrotonidae) (1, 2). Argasidae is second to Ixodidae with regard to the number of species. However, there is widespread disagreement concerning the taxonomy above the species level (i.e., subgenus and genus) in this family, with nearly two-third controversial species (3). According to various schools of scientific thought, the following five classification systems have been proposed for Argasidae: The American school of acarologists (4, 5), the French school (6, 7), the Soviet school (810), the cladistic scheme of Klompen and Oliver (11), and, most recently, a molecular system of classification by Mans and colleagues (12). The classification systems of American and Soviet schools are based on unique morphological characters, which are determined by the degree of phenetic differentiation, without reflecting the evolutionary history. The classification system of cladistic school is based on morphology and biology, and was first proposed from a phylogenetic perspective. The French school only proposes a simple list of taxonomic rank, in which the taxa are not supported by morphological or biological characters. Burger et al. (13) first tested the genus–level classification of soft ticks by using mitochondrial genome and nuclear rRNA sequences. Their analyses strongly supported a clade of neotropical species within the subfamily Ornithodorinae, which included species from two genera, Antricola and Nothoaspis, and two subgenera, Ornithodoros (Alectorobius) and Ornithodoros (Subparmatus). Additionally, their analysis strongly supported a clade called Ornithodoros sensu stricto consisting of O. savignyi and four other Ornithodoros species (O. brasiliensis, O. moubata, O. porcinus, and O. rostratus) (13). Mans et al. (12) first proposed a molecular classification system for soft ticks based on the mitochondrial genome and nuclear sequence data. This classification system corresponds broadly with that of Klompen and Oliver (11), in which Carios and Chiropterargas were included in the subfamily Ornithodorinae, and Alveonasus in the subfamily Argasinae. There were also modifications made to several genera and subgenera. For example, the taxonomic status of Ogadenus, Secretargas, Proknekalia, Alveonasus, and Chiropterargas suggested as subgenera by Klompen and Oliver (11) were all promoted to the genus level by Mans et al. (12). Additionally, Mans et al. (12) established a new genus, Navis. This molecular classification system has essential reference significance. Later, Mans et al. (14) modified this classification scheme after analyzing the phylogenetic status of the bat tick Argas vespertilionis (Latreille) (Carios vespertilionis), and suggested that the subfamily Argasinae should be divided into six genera: Alveonasus, Argas, Navis, Ogadenus, Proknekalia, and Secretargas. The subfamily Ornithodorinae contains nine genera: Alectorobius, Antricola, Carios, Chiropterargas, Nothoaspis, Ornithodoros, Otobius, Reticulinasus, and Subparmatus (12, 14). This represents significant progress in the systematic classification of soft ticks. However, the further studies involving more controversial species and species from understudied regions should be conducted.

China is a country whose argasid fauna is poorly known (only 15 species reported thus far) (15, 16). In China, studies on ticks prior to the 1960s are scarce and not systematically documented. According to Li (17), the earliest research on soft ticks can be traced back to 1929, when Faust found an Argas sp. on domestic dogs in China. Later, Feng Lanzhou began to study the development of Borrelia duttoni in O. moubata collected abroad. In 1951, Feng and Huang collected A. persicus (Oken) from Shanxi province (17). Since then, research on soft ticks in China has been gradually developing, and includes case reports, morphological descriptions, biological characters, pathogens, and studies on the protein composition and karyotype characters of ticks (1850). Wen and Chen (15) reviewed valid species of soft ticks for the first time (15). Toward the end of 2015, they listed valid argasid names of the world and China, and proposed a Chinese scientific term for each valid species and genus. Chen and Yang (51) published a monograph named “Systematics and taxonomy of Ixodida,” in which argasid ticks from China were systematically redescribed. Over the past two decades, we have witnessed the emergence and re-emergence of tick-borne diseases. However, systematic surveys of soft ticks and associated pathogens still lack in China. Here, we reviewed literature on soft ticks published in Chinese, English, Russian, and Japanese to provide a detailed summary of argasid ticks and associated pathogens in China.

Argasid ticks and associated pathogen in fauna of china

As previously described, the classification system for soft ticks requires improvement. With further studies on more controversial species and the application of integrated methods, the taxonomic status of some tick species or groups is likely to change in the future. To prevent confusion in species names caused by constant changes, we followed Guglielmone et al. (3) and temporarily adopted the genus-level classification of Argasidae proposed by Hoogstraal (5) throughout this article. With regard to the nomenclature of the tick hosts, we place the genus name after the common name, except for the hosts identified to species level by authors. Some host species might have been misidentified; however, to avoid missing information, we quote the original name reported in the literature.

Currently, the argasid tick fauna of China consists of 15 species from two genera, Argas (10 species) and Ornithodoros (5 species). An overview of each soft tick species in China is presented below. Additionally, information on the deposition of type material of tick species first discovered in China is presented in this study. The administrative and biogeographical divisions of China are based on Chen et al. (52).

Argas assimilis Teng & Song, 1983

This species was first described in Jiangxi Province of China (45). The meaning of the specific name “assimilis” is “similar and closely resembling” (45).

Type depositories

Institute of Zoology, Chinese Academy of Sciences (IZAS) (holotype ♀, allotype ♂, paratypes 2♀♀ 2♂♂ and 1 nymph); Jiangxi Medical College of China (paratypes 4♀♀).

Local distribution

Oriental Region (Jiangxi, Guizhou) (45, 5154).

Natural host

Passeriformes: swallow (Hirundo daurica japonica) (45, 5154).

Habitats

Swallows' nest.

Molecular data

No record.

Tick-borne pathogens

No record from China.

Remarks

This species is closely related to A. japonicus, but can be distinguished by the following characters: Integumental ridges relatively narrower and markedly raised (integumental ridges thick, and not markedly raised in A. japonicus); peripheral integumental ridges narrower and more elongate, and regularly arranged (peripheral ridges thick and short, and irregularly arranged in A. japonicus); hypostome of female extending to mid-length of palpal article 3 (extending to mid-length of palpal article 2 in A. japonicus); article 3 shorter than article 4 (article 3 equal to article 4 in A. japonicus); each tarsus of nymph with a prominent dorsal subapical protuberance (no dorsal subapical protuberance in A. japonicus) (45).

Argas beijingensis Teng, 1983

This species was first described in Beijing, China (55). The specific name beijingensis is derived from “Beijing,” China, the origin of the type species, plus the Latin adjectival suffix “-ensis,” meaning “belonging to.”

Type depositories

Institute of Zoology, Chinese Academy of Sciences (IZAS) (holotype ♀, allotype ♂, paratypes 3♀♀ 2♂♂ 4 nymphs and 4 larvae).

Local distribution

Palearctic Region (Beijing, Hebei, Shandong) (5155).

Natural host

Columbiformes: pigeon (Columba livia), Streptopelia chinensis; Passeriformes: sparrow (Passer montanus), swallow (Hirundo rustica); Galliformes: chicken (Gallus gallus domesticus) (5155).

Habitats

Avian nests and their surroundings.

Molecular data

No record.

Tick-borne pathogens

No record from China.

Remarks

According to Teng (55), this species is closely related to A. reflexus, but can be distinguished by the following characters: In adults, body slightly broader posteriorly (markedly broadened in posterior one-third in A. reflexus), the fixed digit of chelicera with two teeth (three teeth in A. reflexus), the setae on tarsi I–IV different in number between A. beijingensis and A. reflexus; in larva, body oval with an approximate oval plate of the dorsum (body subcircular with a relatively narrower and longer plate in A. reflexus), eight pairs of seta in posterolateral quadrants of the dorsum (nine pairs in A. reflexus). Argas beijingensis is also related to A. vulgaris, but can be distinguished by the following characters: In adults, the anus slightly posterior to the center of venter (much more separated from the middle of ventral body surface in A. vulgaris), peripheral integumental ridges short and sinuous (relatively narrower and longer in A. vulgaris); in larva, body oval, and its dorsolateral margin with 24–25 pairs of setae (body subcircular, and its dorsolateral margin with 19–21 pairs of setae in A. vulgaris) (55).

Sun et al. (53) reported specimens from Inner Mongolia, Beijing, Hebei, Shanxi, Shandong, Shaanxi, Jiangsu, Shanghai, Anhui, Fujian, Taiwan, and Sichuan in China as A. beijingensis, which were initially recorded as A. reflexus. However, according to the descriptions of Sun et al. (53), they only checked the specimens from Shandong; other specimens were not re-examined, thus the distribution of A. beijingensis should be further investigated.

Argas japonicus Yamaguti, Clifford & Tipton, 1968

Local distribution

Palearctic Region (Beijing, Hebei, Jilin, Liaoning, Inner Mongolia, Ningxia, Xinjiang); Oriental Region (Taiwan) (33, 5158).

This species has also been reported in Japan and Korea (59), and has been studied more in depth in Japan.

Natural host

Columbiformes: Streptopelia spp.; Passeriformes: swallow (Hirundo daurica japonica, Deliclion dasypus), sparrow (Passer spp.); Galliformes: chicken (Gallus gallus domesticus) (33, 51, 5358).

It has been reported that the overwhelming majority of specimens have been collected from swallows and swallow nests (54, 6069). Researchers rarely collected A. japonicus ticks from hosts other than wild birds, although it has been found that this species successfully sucks blood from chickens and many mammals in the laboratory (62, 64). Zhao et al. (56) first reported A. japonicus collected from cattle in nature, and found this species actively infesting livestock from February to March in spring in Xinjiang. They also screened the pathogens of fed A. japonicus ticks from cattle and found spotted fever group Rickettsia spp. and “Candidatus Anaplasma boleense” in this species (56). In Japan, Uchikawa (62) used chicken skin as a feeding membrane to study feeding behavior of A. japonicus. The results indicated that most A. japonicus ticks fed on chicken, rabbit, sheep, and bovine blood could develop successfully but those fed on human, horse, and pig blood showed high mortality rates (68–77%) (62). However, the reason for this difference remains unknown. Several human infestations by this species have been reported in China and Japan (33, 57, 70). In China, the first reported case of human dermatitis caused by A. japonicus biting was recorded in Liaoning, China in 1986 (34). In April 2016, several human cases of A. japonicus ticks biting were reported in Inner Mongolia Autonomous Region of China, and the patients appeared to have fever, skin rash, swelling, itching and inoculation eschars (57). Subsequently, the microbiota of free-living A. japonicus in the affected community was explored (57). In Japan, a group of elderly patients with physical disabilities experienced infestation with A. japonicus coming from sparrow nests located under the eaves of a rehabilitation hospital. The tick bites were painful and accompanied by pruritus (70). Therefore, A. japonicus selects birds, especially swallows, as its primary and preferred hosts. Human and other mammals may act as accidental hosts.

Habitats

This species often inhabits the nests of birds, occasionally hencoops, poultry and livestock yards, and attacks people at night.

Molecular data

China: 16S rDNA (MH782636), 12S rDNA (MG668793– MG668795).

Other countries

Japan: 16S rDNA (AB819156, AB819157), mitochondrial genome (MT371799).

Tick-borne pathogens

Spotted fever group rickettsiae (56, 57), Alcaligenes faecalis (57), “Candidatus Anaplasma boleense” (56).

There are a few studies on the pathogens and diseases transmitted by A. japonicus. Further investigations of A. japonicus and its pathogens should be conducted in China.

Argas persicus (Oken, 1818)

Local distribution

Palearctic Region (Beijing, Xinjiang, Gansu, Qinghai, Hebei, Jilin, Liaoning, Heilongjiang, Inner Mongolia, Shandong, Shanxi, Shaanxi); Oriental (Shanghai, Hubei, Fujian); Paleozoic–Oriental ecotone (Anhui, Sichuan, Jiangsu) (17, 5254, 7176).

Natural host

Columbiformes: pigeon (Columba spp.); Passeriformes: sparrow (Passer monatanus), swallow (Hirundo spp.); Galliformes: chicken (Gallus gallus domesticus) (17, 5254, 7176).

This species appears to be mainly a parasite of domestic fowl and arboreal nesting birds (77). It commonly attacks humans, causing it to have an evil reputation especially in early Persia (77). Additionally, this species can sometimes be found in domestic animals, especially sheep and cattle, in China (51), which has not been reported in other countries or areas (7783). This is mainly because domestic animals are often mixed and housed together with poultry in the rural areas of China.

Habitats

In the crevices of poultry houses and nearby human houses, or in the cracks or under the bark of trees frequented by their wild avian hosts.

Life cycle

Qi et al. (31) and Tian (30) thoroughly studied the life history of A. persicus in a laboratory. Di (39, 43) reported on its life habits and the seasonal and diurnal activities. In Shandong, A. persicus was found from early March to mid-October with an active period from May to September and peak prevalence in July (75). The overwintering period for this species was from November to February. This species endures for long periods, with larvae starving up to 8 months, nymphs 24 months and 3 years in adults. Any developed stage of A. persicus could overwinter, and the longevity was reported to be 10–20 years (43). The activity of A. persicus larvae was not limited by day and night. In contrast, the activity of A. persicus nymphs and adults was affected by light and mostly were active at night. Usually, the larva is attached to the featherless part or near the feather roots of poultry, where they can suck blood, whereas the nymphs and adults are attached to the featherless toes of poultry. There were two to seven instars in the nymphal stage with similar morphological features, but they increased in size. Ticks began seeking for hosts at 7–8 pm, reaching a peak around midnight from late July to mid-September (39). The mating behavior between males and females was carried out after sucking a small amount of blood during the day or night (30). Ticks only climbed to the host when sucking blood and left the host immediately after completion of the blood meal. Most of the larvae usually fed for 2–7 days, while very few fed for 10 days. Each nymphal instar fed for several minutes to several hours, and the adults were generally replete in 15 min to 3 h. The molting period of larva was 6–18 days (30) or 4–17days (31), while the molting time of first instar nymph was 7–12 days (30) or 10–97 days (31), and that of second instar nymph was 9 days (30) or 12–63 days (31) under 26–28°C with 65–85% relative humidity. The various molting period of nymph may be related to individual differences and blood engorgement levels (30, 31).

According to the experimental observations, the preoviposition stage of females has been reported to range from 3 to 160 days (30, 31). Oviposition time seems to be related to the month in which females are fed. The preoviposition period of females sucking blood from June to August was the shortest, whereas that of females sucking blood in January was the longest. They generally oviposited in 4–21 days after engorgement, and the number of eggs was related to the amount of bloodsucking. Generally, 50–200 eggs were laid at a time, and more than 1,000 eggs could be laid in the lifetime of a female.

Molecular data

China: 16S rDNA (MN894073, MK555333, KR297208, KR297209, LC209197, LC209198, KX258880); COI (LC209195, LC209196, MN900726, MK571448); mitochondrial genome (OM368319, OM368320, MT012684, NC_053794).

Other countries

Australia: 16S rDNA (AY436769, AY436770, AY436772); Egypt: 16S rDNA (AF001402); COI (OM177661); Iran: Cathepsin L-like protein (MN175238, MN175239); COI (KX879770); Italy: 16S rDNA (GU451248); Kazakhstan: COI (MN900726); Kenya: 28S rDNA (KJ133607); 18S rDNA (KJ133633); ITS1 (KJ133633); ITS2 (KJ133607); mitochondrial genome (KJ133581); Pakistan: 16S rDNA (MZ496987, MT002847); Romania: COI (FN394341); NAD5 (FN394358); South Africa: 16S rDNA (GU355920); USA: 18S rDNA (L76353); 16S rDNA (L34321); 12S rDNA (GU355920); COI (U95864).

Tick-borne pathogens

Borrelia anserina, Francisella tularensis, Coxiella burnetii, Rickettsia hoogstraalii, Coxiella-like endosymbiont, Pseudomonas geniculata, Sphingomonas koreensis, Acinetobacter haemolyticus, Streptococcus suis, Staphylococcus aureus (8487).

In China, A. persicus has been reported to carry many pathogens, as described above, and only B. anserina is well-known to cause fowl spirochetosis. There are many cases of illness in chickens, geese, and ducks bitten by A. persicus in China (2427, 32, 72, 87). In 2006, there was an outbreak of goose spirochetosis in Inner Mongolia, which caused mortality in nearly half of the sick geese, and many adults of A. persicus were found in goose housings. Clinical symptoms, pathological anatomy, and microscopic examination indicated that the goose disease was caused by B. anserina, transmitted by the vector A. persicus (87). Additionally, it was also reported that most chickens lost their appetite, were emaciated, and even died within a week in Gansu China, because of the infestation by A. persicus larvae. The chickens were observed for depression, fluffy feathers, liquid stools, crowns, beards, feet visible mucous membranes of pale color, and unstable standing or paralysis. However, the cause of the disease or pathogens has not yet been reported (71).

In other countries or regions, this species has also been reported to transmit Aegyptionella pullorum (Aegyptianellosis), Slovakia virus, Kyasanur forest disease virus and Francisella persica, which all have not been detected in China (8892).

Remarks

Argas persicus is considered native to Turanian–Central Asia but with human activities it become established throughout most continents except Antarctica (78). Many records report the presence of this species in Taiwan (51, 54, 72). However, Robbins (93) believed that published references to A. persicus in Taiwan were misidentifications (9398). Indeed, A. persicus listed in Taiwan by Teng (72) may represent the morphologically similar A. robertsi (93). Thus, records of A. persicus from the Oriental region should be further determined.

Zhou and Meng (99) studied the karyotypes of 56 A. persicus ticks and found 51 ticks were diploids, i.e., 2n = 26 (24 + XY) (♂); 2n = 26 (24 + XX) (♀). Interestingly, it was also discovered that four ticks were tetraploid (4n = 52) and one tick was octoploid, i.e., 8n = 104 (96 + XXXXYYYY). Zhou and Meng (99) speculated that the reason of this polyploidy could be related to the use of colchicine during the sample processing (99). Additionally, they also reported that the Y-chromosome of A. persicus from Xinjiang was 37.8% the length of the X-chromosome, and the average length of all autosomes was 14.7% the length of the X-chromosome (99). Goroschenko (100) reported those ratios of A. persicus from the former USSR as 54.4 and 26.5%, respectively. These differences might be related to tick strains from different geographical areas.

Argas pusillus Kohls, 1950

Local distribution

Oriental (Taiwan) (5153, 93).

Argas pusillus is a typical southeastern Asian species that has been reported in Philippines, China, Thailand, Malaysia, and Singapore (5, 51, 93, 101104).

Natural host

Chiroptera: bats (Scotophilus temminckii, Pipistrellus imbircatus).

This species mainly parasitizes bats, specifically Scotophilus spp.

Habitats

Near bat caves.

Molecular data

No record.

Tick-borne pathogens

No record from China.

Studies on A. pusillus and its pathogens all over the world are very limited, mainly including species examination, distribution, hosts and a few on pathogen detections (101106). To date, Issyk–Kul fever virus and Keterah virus have been reported in this species (5, 105, 106).

Remarks

It is often confused with the bat tick, A. vespertilionis. Hoogstraal (letter No. 251, February 14, 1984 and letter No. 376, February 14, 1977) concluded that the samples of A. vespertilionis collected in Taiwan were A. pusillus (93). Robbins (93) stated that the published records of A. vespertilionis in Taiwan (72, 94, 95, 98, 107) may represent A. pusillus (93). In addition to Taiwan, this species probably also occurs in other areas of China; therefore, A. vespertilionis collected from southern China should be further re-examined.

Argas reflexus (Fabricius, 1794)

Local distribution

Palearctic (Gansu, Qinghai, Hebei, Henan, Inner Mongolia, Ningxia, Shandong, Shaanxi, Xinjiang, and Heilongjiang); Palaeozoic–Oriental ecotone (Anhui).

Argas reflexus can be found in the Palearctic region between parallels 31°N and 51°N (108, 109). This species is widely distributed in Europe and has been reported in some regions of Asia (Israel, Turkey, Iran, Pakistan, Afghanistan and Kazakhstan), as described in detail by Pfäffle and Petney (108). Additionally, Hoogstraal and Kohls (110) found a single unengorged larva of A. reflexus in Egypt.

Natural host

Columbiformes: pigeon (Columba livia domestica, Columba rupestris); Passeriformes: sparrow (Passer spp.), swallow (Hirundo spp.), chough (Pyrrhocorax graculus); Galliformes: chicken (Gallus gallus domesticus) (19, 22, 23, 42, 51, 53, 55, 73, 111, 112).

Argas reflexus predominantly parasitizes domestic pigeons (Columba livia domestica) and bites other birds, including rock pigeons (Columba livia), rock swallow (Ptyonoprogne rupestris), turtle doves (Streptopelia turtur), fan–tailed ravens (Corvus rhipidurus), jackdaw (Corvus monedula), swifts, swallows, owls, crows, several passerine birds, chickens and even humans (108110, 113).

Habitats

Inhabit pigeon and other bird nests, and the vicinity of its hosts.

Molecular data

China: No record.

Other countries

Luxembourg: arg-r-1 (AJ697694); Poland: 16S rDNA (AF001401); Spain: 16S rDNA (MW289075, MW289076, MW289084); COI (MW288388); USA: 16S rDNA (L34322); 12S rDNA (U95865).

Tick-borne pathogens

No record from China.

It has been reported that A. reflexus is a vector of Aegyptianella pullorum, Crimean–Congo hemorrhagic fever virus, Uukuniemi virus, Grand Arbaud virus, Ponteves virus, Tunis virus, West Nile virus, Chenuda virus, Nyamanini virus, and Quaranfil virus (98, 114118).

Remarks

Teng (55) concluded that A. reflexus published in “Economic Insect Fauna of China Fasc 15” was misidentified: specimens collected from Xinjiang should be A. vulgaris while those collected from Beijing should be A. beijingensis. However, he did not mention the specimens collected from other regions. Yu et al. (73) reported this species in Xinjiang. Based on the geographical location of China and the distribution area and host characters of A. reflexus, it is possible for this tick species to appear in China. Therefore, this species has been kept in the valid tick list of China until conclusive evidence is obtained.

Argas robertsi Hoogstraal, Kaiser & Kohls, 1968

Local distribution

Oriental (Taiwan) (52–54, 93).

Argas robertsi is common in Australia (Queensland, Northern Territory, New South Wales) and the Indo–Malaya region, including Indonesia (Java), China (Taiwan), Thailand, India (West Bengal), and Sri Lanka (82, 119, 120).

Natural host

Galliformes: chicken (Gallus gallus domesticus), Pelecaniformes: cormorant (Phalacrocorax spp.), ibis (Threskiornis spp.); Ciconiiformes: heron (Ardea spp., Ardeola spp., Bubulcus spp., Nycticorax spp., Egretta spp., Plegadis spp.), stork (Anastomus spp.) (29).

Habitats

Often inhabits bird nests, occasionally occur in hencoops.

Life cycle

Hoogstraal et al. (119) studied the life cycle of A. robertsi collected from Taiwan, using domestic pigeons as experimental hosts at 28–30°C and 75% RH. The life cycle of A. robertsi was 2–10 months and included two to five nymphal instars in Taiwan, similar to other A. robertsi populations from different regions. The nymphs and adults fed within a few days of molting. Many males molted from the earlier nymphal instars. Most females needed to suck blood twice to lay eggs, while few needed to suck blood only once (119).

Molecular data

China: No record.

Other countries

Australia: 16S rDNA (AY436768).

Tick-borne pathogens

Kuo Shuun virus (29).

Other viruses, including CSIRO 1499 virus, Lake Clarendon virus, Nyamanini virus and Pathum Thani virus have also been detected in other countries or regions (82, 105).

Remarks

Barker and Walker (82) stated that A. robertsi and A. persicus lived in sympatry in Australia. Although A. persicus is very common in China, A. robertsi has only been reported in Taiwan. Further investigations on A. robertsi and A. persicus should be conducted in China.

Argas sinensis Jeu & Zhu, 1982

The specific name “sinensis” means “belonging to China.”

Type depositories

Department of Parasitology, Chongqing Medical College, Chongqing, China (holotype one unfed larva, paratypes two unfed larvae, two partly engorged larvae, and four engorged larvae).

Local distribution

Oriental (Sichuan) (36, 38, 52).

Natural host

Chiroptera: bat (Pipistrellus abramus).

Jeu (36) stated that larvae could feed successfully on white rats and mice. Nymphs and adults could feed well on a wide range of vertebrate animals (including Rattus tanezumi, Rattus norvegicus, Mus musculus, guinea pig, rabbit, dog, cat and monkey) and poultry (including chicken, goose, duck, and pigeon) under laboratory conditions. Jeu even contributed his skin to verify that humans are also suitable hosts for ticks (36).

Habitats

Occurs in bat colonies, often can be found in bat infested buildings (38).

Life cycle

Jeu (36) carefully investigated the life history of A. sinensis collected from Chongqing, under laboratory conditions from 1973 to 1977 (36). There were two to four nymphal instars for this species. The molting nymph could be divided into the following three types: (1) composed of two instars that sucked blood twice; (2) composed of three instars that sucked blood 3 times; and (3) composed of four instars, the first instar nymph could molt into the second instar nymph directly without sucking blood, then sucked blood 3 times. Females laid eggs several times, with prolonged oviposition periods, but delaying the time between oviposition periods progressively. They were able to deposit four to eight batches of eggs, totaling 144–423 eggs (36).

Molecular data

No record.

Tick-borne pathogens

No record from China.

Remarks

The larva of this species is closely related to A. vespertilionis and A. daviesi, but differs from them in the following characters: (1) dorsal setae numbering 14 pairs; (2) body with 11 pairs of dorsoexternal setae and micro setae; and (3) relative distance between postpalpal and posthypostomal setae 2.3:1 (38).

Argas vespertilionis (Latreille, 1796)

Local distribution

Palearctic (Hebei, Shandong, Henan, Gansu, and Xinjiang); Oriental (Hubei, Hunan, Guangdong, Zhejiang, Guizhou, Fujian, Guangxi, and Yunnan); Paleozoic–Oriental ecotone (Sichuan, Jiangsu) (37, 5153, 55, 121, 122).

Natural host

Chiroptera: bat (Vespertilio spp.) (37, 5153, 55, 121, 122).

This species parasitizes bats, and occasionally attacks humans.

Habitats

Associated with bats and bat habitats.

Molecular data

China: 16S rDNA (MW132811, MF106219–MF106221, KY657240, OK047498, OK054512); COI (KY657239); mitochondrial genome (OM368317, OM368318).

Other countries

Belgium: COI (MK140084, MK140088); France: 12S rDNA (JX233821); Hungary: 16S rDNA (KX831484–KX831489); COI (KX431953–KX431955); Italy: 16S rDNA (KX831496–KX831498, HM751841); Japan: 16S rDNA (AB819158); mitochondrial genome (MT762370); Kenya: 16S rDNA (KX831491); COI (KX431956); Netherlands: COI (MK140082, MK140083, MK140085–MK140087); Pakistan: 16S rDNA (MK571555); COI (MK571553); Romania: 16S rDNA (KX831490); Spain: 28S rDNA(MT739330, MT739331); 18S rDNA(MT739410, MT739411); 5.8S rDNA(MT739330, MT739331); ITS1(MT739410, MT739411, MT739330, MT739331); ITS2(MT739330, MT739331); mitochondrial genome (MT680027, MT680028, NC_060373); United Kingdom: 16S rDNA (MF510175–MF510177); COI (MF510173, MF510174); Viet Nam: 16S rDNA (KX831492–KX831495); COI (KX431957–KX431960).

Tick-borne pathogens

Babesia vesperuginis, Rickettsia raoultii, Rickettsia rickettsia (121, 123, 124).

In other parts of the world, this tick species has been reported as a vector of Issyk–Kul, Keterah, and Sokuluk viruses, Q fever rickettsia, Coxiella burnetii, Ehrlichia sp. AvBat, Rickettsia sp. AvBat, Borrelia burgdorferi sensu lato and an unknown Borrelia species closely related to B. recurrentis, B. crocidurae and B. duttonii (101, 125).

Remarks

Argas vespertilionis is confused with morphologically similar species, therefore, the global distribution of this species is not clear. It appears that A. vespertilionis is widely distributed in Africa, Europe, the Palearctic parts of Asia, and a few parts of the oriental region, including some parts of India, Cambodia (126), Vietnam (123) and southern China (5, 51, 52, 93). Hoogstraal (5) stated that reports of A. vespertilionis from other parts of the oriental region (Bangladesh, Malaysia, and Philippines) were misidentifications with A. pusillus. Robbins (93) excluded A. vespertilionis from the checklist of tick species in Taiwan and corrected it to A. pusillus. Then, identifications of A. pusillus in China are all from Taiwan, and those oriental records of the A. vespertilionis are currently doubtful. Therefore, the occurrence of these two species in China should be reconsidered.

Argas vulgaris Filippova, 1961

Local distribution

Palearctic (Xinjiang, Jilin, Gansu, Ningxia, Liaoning, Beijing, Hebei, Inner Mongolia, Shanxi, Shandong, Shaanxi) (5153, 55).

Filippova (8) indicated that this species was widely distributed in the Palearctic region and was common in the former Soviet Union.

Natural host

Columbiformes: pigeon (Columba spp.); Passeriformes: sparrow (Passer spp.) (5153, 55).

Habitats

Often inhabits bird nests.

This species inhabits lowland and foothill meadow steppes, dry steppes, and deserts. Its vertical distribution ranges from sea level (lower reaches of the Talghinka River in Dagestan) to 900 m above sea level (Karabil, Turkmenistan). Its favorite habitats are ground nests or burrows of birds in outcrops of loess, sandstone, and limestone, as well as the steep banks of rivers and lakes (8).

Molecular data

China: No record.

Other countries

Poland: 16S rDNA (AF001404).

Tick-borne pathogens

No record from China.

Few studies have been conducted on the pathogens of A. vulgaris. Hissar virus (Bunyaviridae) and Tyulek virus (Orthomyxoviridae) were isolated from this tick species in Tadjikistan and Kyrgyzstan, respectively (127, 128).

Remarks

Teng (55) stated that A. reflexus from Xinjiang published by Teng (72) should be A. vulgaris. Yu et al. (73) reported only A. reflexus in Xinjiang. In terms of geographic location and climate, both species have the potential to be distributed in Xinjiang. Therefore, the tick specimens of Xinjiang need to be re-examined.

Ornithodoros capensis (Neumann, 1901)

Local distribution

Oriental (Taiwan) (93).

This species is globally distributed along the coasts and islands of the Pacific, Atlantic and Indian Oceans; the Caribbean and Coral Seas and the lakes of the eastern African Rift Valley system (5, 129131). Except for Taiwan, very few surveys have been conducted in other parts of China along the coastline, especially in the southern part where the species might also be distributed.

Natural host

No record from China.

Habitats

Inhabits in seabird nests.

Molecular data

China: No record.

Other countries

Algeria: 16S rDNA (KP776644); Australia: 16S rDNA (AH011497); COI (AH011497); NAD1 (AH011497); Brazil: 16S rDNA (KU757069); Cape Verde: 18S rDNA (JQ824327–JQ824368); 16S rDNA (JQ824295–JQ824326); Japan: 16S rDNA (AB819266, AB242431, AB242431, AB057537–AB057540, AB076080–AB076082); mitochondrial genome (AB075953, NC005291); USA: 16S rDNA (EF636462, EF636466).

Tick-borne pathogens

No record from China.

It has been reported that this species can transmit Soldado virus, West Nile virus, Johnston Atoll virus, Upolu virus, Nyaminini virus, Quaranfil virus, Saumarez Reef virus, Hughes virus, Rickettsia spp. and Borrelia spp. (129, 132).

Remarks

Although China has many islands scattered along the seashore, studies on seabird ticks are scarce, with the exception of O. capensis. It is known that both seabird ticks O. sawaii and O. maritimus are distributed in Palearctic region. O. maritimus is distributed in Great Britain, Ireland, France (Corsica), Tunisia, Portugal, Italy (off Sardinia), southwestern USSR, and Senegal (133). Ornithodoros sawaii is reported from Republic of Korea and Japan (133, 134). Therefore, these two species might also be distributed in the islands of China.

Ornithodoros huajianensis Sun, Xu, Liu & Wu, 2019

The specific epithet is in allusion to the habitat where this species was found (16).

Type depositories

Medical Entomology Gallery of Academy of Military Medical Sciences, Beijing, China (AMMSC) (holotype ♀, paratypes 2♀♀ 3♂♂ and 3 nymphs).

Local distribution

Palearctic (Gansu) (16).

Natural host

Rodentia: Marmota bobak sibirica (16).

Habitats

Prefer semiarid hilly steppes.

Molecular data

China: 16S rDNA (MK208992–MK208994).

Tick-borne pathogens

No record.

Remarks

This species belongs to the subgenus Ornithodoros. It was diagnosed by its broad rectangular tongue and triangular tongue–shaped posterior lip in the male genital apron, a shallow camerostome with definite folds, and smaller mammillae with a single seta mixed with larger ones in nymphs and adults (16).

Ornithodoros lahorensis (Neumann, 1908)

Local distribution

Palearctic (Xinjiang, Inner Mongolia, Shandong, Gansu, Liaoning, and Tibet) (18, 20, 41, 5153, 56, 72, 135, 136).

This species is widely distributed in the Palearctic region, including Armenia, Dagestan, Kazakhstan, Uzbekistan, Turkmenistan, Kyrgyzstan, Tajikistan, Russia, Kosovo, Republic of Macedonia, Syria, Turkey, Iran, Iraq, Saudi Arabia, Afghanistan, Lebanon, Syria, Pakistan, Bulgaria, Greece, Israel, China, and India (5, 8, 132, 137141).

Natural host

Carnivora: dog (Canis spp.); Artiodactyla: cattle (Bos spp.), sheep (Ovis spp.), goat (Capra spp.), camel (Camelus spp.); Perissodactyla: horse (Equus spp.) (18, 20, 41, 5153, 56, 72, 135, 136).

This species was originally as a parasite of the Asiatic mouflon, Ovis orientalis arkal, and other wandering ungulates resting beside cliffs. However, nowadays, it is a notorious parasite of sheep, camels, and cattle, especially in primitive stables and dwellings in steppes and mountain deserts (5). This species has also been reported to infest human in Turkey and the former Soviet Union (138140).

Habitats

Living mainly in sheep pens or other livestock sheds (also found in chicken coops). It is rarely reported from natural habitats.

Molecular data

China: 18S rDNA (KX530878, KX530879); 16S rDNA (MG651950–MG651959, KX530872–KX530877, ON159478–ON159502, MN564903–MN564909, OM673115–OM673125, OL444952–OL444957); 12S rDNA (MG651960–MG651967); COI (KX530866–KX530871).

Other countries

Afghanistan: 18S rDNA (L76354); Iran: COI (MK318148, MG582607).

Tick-borne pathogens

Candidatus Anaplasma boleense” and Anaplasma ovis (35, 56).

Other pathogenic associations include Crimean–Congo haemorrhagic fever (CCHF) virus, Rickettsia sibirica, R. conorii, Brucella abortus, F. tularensis, and C. burnetii, which have not been detected in China (139).

Life cycle

Ornithodoros lahorensis is one of the most studied species of soft tick in China. Shao (28) studied the biology of O. lahorensis feeding on rabbit under laboratory conditions in Xinjiang. After hatching, it took more than one month for larvae at room temperature before they were able to attach to a host, and then took a total of 24–42 days for blood–sucking larvae to become engorged third instar nymphs (28). Engorged third instar nymphs molted into males and females for 113–149 days and 110–147 days, respectively. Newly molted adults needed 1–1.5 months before attaching to hosts. Engorged females laid eggs between June to August, peaking in July. In Xinjiang, adults and third-instar nymphs could overwinter in the wall crevices of a sheep fold. The larvae infested sheep in late September and October. Zhao et al. (56) reported that O. lahorensis ticks infested livestock from late February to early April in southern Xinjiang.

Ornithodoros papillipes (Birula, 1895)

Local distribution

Palearctic (Shanxi, Xinjiang, Inner Mongolia, and Shaanxi) (40, 44, 48, 51, 53, 72).

The species is widely distributed in the Mediterranean and Central Asian subregions of the Palearctic, including Kazakhstan, Uzbekistan, Turkmenistan, Kyrgyzstan, Tajikistan, eastern Libya, western Egypt, Turkey, Cyprus, Syria, Lebanon, Israel, Early Jordan, Iraq, Saudi Arabia, Iran, Afghanistan, Pakistan (Kashmir and western Punjab), and China (8). However, owing to confusion in systematics, some of these data require clarification (8).

Natural host

Carnivora: dog (Canis spp.), fox (Vulpes spp.); Artiodactyla: sheep (Ovis spp.); Lagomorpha: hare (Lepus spp.); Erinaceomorpha: hedgehog (Erinaceus spp.); Soricomorpha: scilly shrew (Crocidura suaveolens); Anura: toad (Bufo viridis) (40, 44, 48, 51, 53, 72).

Habitats

It usually selects caves, grottoes, and burrows inhabited by small and medium-sized animals in desert and semi-desert areas along its distribution. In some regions, it often occurs in livestock stables and human houses.

Life cycle

In China, many studies on the biology of O. papillipes have been carried out by early researchers (48), which will be very important for distinguishing O. papillipes from O. tholozani. Engorged females oviposit eggs in summer and autumn (48). Feng et al. (48) reported that there were three to six nymphal instars for this species using mice (Mus musculus) and guinea pigs (Cavia porcellus) as hosts. A few engorged third instar nymphs molted to adults with the number of males > females; most engorged fourth instar nymphs molted to adults with the number of females > males; a few engorged fifth instar nymphs molted to adults and very few fifth instar nymphs still molted to sixth instar nymphs. The whole process from egg to adult took 5 months to 1 year, which was determined by external temperature and other conditions (48). Additionally, guinea pig (Cavia porcellus), chicken (Gallus gallus domesticus) and grassland tortoise (Testudo horsfieldii) were used as hosts. The results showed that tick development was different under the same laboratory conditions. According to the average weight and volume of engorged ticks, guinea pig is the best host, followed by chicken and then turtle (48).

Molecular data

China: No record.

Czech: Defensin (FJ222575–FJ222577).

Tick-borne pathogens

Borrelia persica (40).

In the 1950–1980s, many cases of tick-borne relapsing fever were reported in Xinjiang. In southern part of this province, the pathogen was Borrelia persica transmitted by O. papillipes (40, 48, 142). Feng et al. (48) stated that the natural infection rate of spirochetes was very high in O. papillipes with spirochetes isolated from 12 of 13 tick groups collected from wall crevices of human houses and burrows of Bufo viridis. Additionally, the authors collected many Bufo viridis from the same habitats as O. papillipes. They then dissected the internal organs (liver, spleen, etc.) of Bufo viridis, prepared a suspension emulsion with normal saline, and injected intraperitoneally into guinea pigs. Spirochetes were found in the blood of guinea pigs, which proved that Bufo viridis was the natural carrier of tick-borne relapsing fever pathogen (48). Another clinical experiment indicated that 13 guinea pigs suffered from relapsing fever after being bitten by naturally infected O. papillipes ticks (80–150 ticks per guinea pig). The incubation period was 4 to 6 days, and the course of the disease lasted 15–20 days. Spirochetes appeared in large numbers in the peripheral blood of these animals. On average, more than 20 spirochetes were observed per field in thick blood smears and in some cases, they were so abundant that could not be reliably counted. During the course of the disease, two guinea pigs died when a large number of spirochetes appeared (48). Shao (40) stated that O. papillipes is in close contact with human beings in Xinjiang. They surveyed 50 households in a village and found 49 households were infested by this species. Therefore, in the 1980s, the harm caused by tick-borne relapsing fever in Xinjiang was notable.

Filippova (8) stated that O. papillipes was the main vector of tick-borne relapsing fever in the republics of Central Asia and Kazakhstan as well as in neighboring foreign countries. By testing spontaneous carriage, experimental infection and the precipitation reaction a wide range of wild, domestic, and farm animals, carriers of spirochetes in natural and village foci have been established. However, some domestic animals, such as sheep and goats, were characterized by low spirochetemia, resulting in these animals serving only as secondary sources of spirochetes (8). Ticks are capable of taking up spirochetes at any phase and stage, and transmitting them both transstadial and transovarial. The bite of a single infected tick is sufficient to infect humans with spirochetosis (8).

Under experimental conditions, O. papillipes can acquire C. burnetii, store it for a long time period, transmit the pathogen transstadially, and infect healthy animals during subsequent feeding (8).

Remarks

This species is considered a synonym of O. tholozani (Laboulbène and Mégnin, 1882) by Neumann (143, 144), which was subsequently accepted by many Western scientists (3, 5). Currently, O. tholozani is reported from India, Kazakhstan, Kyrgyzstan, Tajikistan, Turkmenistan, Uzbekistan, Afghanistan, Iran, Iraq, Syria, Jordan, Turkey, Greece, Israel, Egypt, Cyprus, Libya, and Lebanon (51, 145147). Nuttall et al. (77) considered O. papillipes a dubious species, but noted that Birula's figures were difficult to reconcile with the description of O. tholozani, especially with regard to the sides of the camerostome and the tarsi, thus they inserted the original description of O. papillipes in their book. Filippova (8) indicated that from the diagnosis and drawings of Laboulbene and Mégnin (1882), it follows that when establishing this species, they had an admixture of species among the type specimens. Indeed, the absenece of cheeks, the structure of the peritremes, hypostome, chelicerae, and legs, as well as larval morphology, suggests that the second species could have been an Alveonasus sp. (8). Moreover, Filippova (8) did recognize differences between O. tholozani and O. papillipes, and thought that Neumann's synonymy relied on the examination of more than one species, likely O. tholozani and O. lahorensis. She also pointed out that in the literature the species O. tholozani should be morphologically similar species O. papillipes, O. verrucosus, O. lahorensis, and other West Asian species (8). In Russian literature, the most common name is papillipes. Therefore, Eastern European workers strongly defend the validity of the name O. papillipes with scientifically sound arguments. Guglielmone et al. (3) pointed out that the uncertain status of these taxa led them to treat O. tholozani and O. papillipes both as provisionally valid.

Ornithodoros tartakovskyi Olenev, 1931

Local distribution

Palearctic (Xinjiang, Inner Mongolia, and Shaanxi) (40, 48, 5153, 72).

This species is distributed in the Palearctic region including Kazakhstan, Uzbekistan, Turkmenistan, Kyrgyzstan, Tajikistan, Iran and China (8, 148).

Natural host

Rodentia: Rhombomys opimus; Testudines: tortoise (Testudo horsfieldii) (40, 48, 5153, 72).

Habitats

Mainly inhabit desert and semi-desert areas.

Molecular data

China: No record.

Other countries

Czech: Defensin (FJ222581, FJ222582).

Tick-borne pathogens

Borrelia latyschewii (40).

The pathogen Borrelia latyschewii is spread by O. tartakovskyi in northern Xinjiang of China (40, 48, 142). Ornithodoros tartakovskyi plays a much smaller role in the spread of spirochetosis among humans than O. papillipes and O. verrucosus, due to its confinement almost exclusively to natural habitats, particularly to burrows of small diameter (8). This species also transmits Coxiella burnetii and Acanthocheilonema viteae (8, 149).

Conclusions

With the increasing number of new emerging and reemerging tick-borne diseases over the past 20 years, an increasing number of people are paying attention to ticks and tick-borne pathogens. Geographically, China is located in the southeastern part of the vast Eurasian continent, including the Palearctic and Oriental realms and has a variety of ecological types. However, soft ticks and their associated pathogens remain largely unstudied in China. Toward the end of 2021, the argasid tick fauna of China comprised 15 valid species (6.88% of the world's argasid species). Four species are endemic from China: A. (Argas) assimilis, A. (Argas) beijingensis, A. (Carios) sinensis and O. (Ornithodoros) huajianensis. Although there are currently no reports of these Chinese endemic argasid species in other countries and regions, it is still possible for those species to be distributed in adjacent regions. Except for O. capensis, all other Ornithodoros species in China are found in the Palearctic region. Except for A. vulgaris, which is limited to the Palearctic Region, the greatest number of Argas species is present in the Oriental Region or the Oriental + Palearctic Region. A. persicus and O. lahorensis most often inhabit nearby human houses and commonly attacks people that makes them the two most thoroughly studied argasid ticks in China.

In total, 47 vertebrate species have been recorded as hosts for Argasidae in China. The most commonly reported hosts of soft ticks in China are birds, followed by mammals. Anurans are rare hosts for O. papillipes; however, they can harbor infectious relapsing fever Borrelia spp. transmitted by this soft tick (48, 51). The fact that amphibians are implicated as reservoirs of relapsing fever spirochetes is interesting, unprecedented in the eco–epidemiology of these agents, and highlights the need to re–study the disease in China. Additionally, A. japonicus and A. persicus are always reported to infest birds and domestic fowl abroad, while these two species are often found in livestock in China, which might be because domestic animals are often mixed and housed with poultry in Chinese rural areas. Nine species (60%) were recorded parasitizing humans in China (A. beijingensis, A. japonicus, A. persicus, A. sinensis, A. vespertilionis, A. vulgaris, O. lahorensis, O. tartakovskyi, and O. papillipes). Therefore, soft ticks are no less harmful to humans than hard ticks are.

It is worth noting that some clinical cases have been reported in China. These cases were caused by ticks or tick-borne pathogens such as A. japonicus, A. persicus, O. lahorensis, O. tartakovskyi, and O. papillipes. However, the pathogens in each case have seldom been investigated. Additionally, molecular research and investigation of soft ticks and their pathogens, especially on species parasitizing birds and bats remains scarce in China. Except for studies on their morphological characters, research in other areas has not been done for A. assimilis, A. beijingensis, A. pusillus, A. vulgaris, O. capensis, O. tartakovskyi, and O. huajianensis in China. Therefore, it is necessary to carry out comprehensive research on soft ticks and associated pathogens in the future.

Author contributions

ZC and JL conceived, designed, and drafted the manuscript. Both authors read and approved the submitted manuscript.

Funding

This review was supported by the Natural Science Foundation of Hebei Province (C20220516), Science Foundation of Hebei Normal University (L2020B17), and Science and Technology Project of Hebei Education Department (QN2020162).

Acknowledgments

We greatly appreciate editor Sebastián Muñoz–Leal and the two reviewers for their positive and constructive comments and suggestions. We are also grateful to Wei Pei from Guangdong Testing Institute of Product Quality Supervision for providing literature of ticks in Japan.

Conflict of interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Publisher's note

All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.

References

1. Chen Z, Liu J. Recent progress in tick taxonomy and a global list of tick species. Chin J Appl Entomol. (2020) 57:1009–45. doi: 10.7679/j.issn.2095-1353.2020.104

CrossRef Full Text | Google Scholar

2. Peñalver E, Arillo A, Delclòs X, Peris D, Grimaldi DA, Anderson S, et al. Ticks parasitised feathered dinosaurs as revealed by Cretaceous amber assemblages. Nat Commun. (2017) 8:1924. doi: 10.1038/s41467-017-01550-z

PubMed Abstract | CrossRef Full Text | Google Scholar

3. Guglielmone AA, Robbins RG, Apanaskevich DA, Petney TN, Estrada-Peña A, Horak IG. The argasidae, ixodidae and nuttalliellidae (Acari: Ixodida) of the world: a list of valid species names. Zootaxa. (2010) 2528:1–28. doi: 10.11646/zootaxa.2528.1.1

PubMed Abstract | CrossRef Full Text | Google Scholar

4. Clifford CM, Kohls GM, Sonenshine DE. The systematics of the subfamily ornithodorinae (Acarina: Argasidae). I. The genera and subgenera. Ann Entomol Soc Am. (1964) 57:429–37. doi: 10.1093/aesa/57.4.429

PubMed Abstract | CrossRef Full Text | Google Scholar

5. Hoogstraal H. Argasid and nuttalliellid ticks as parasites and vectors. Adv Parasit. (1985) 24:135–238. doi: 10.1016/S0065-308X(08)60563-1

PubMed Abstract | CrossRef Full Text | Google Scholar

6. Camicas JL, Hervy JP, Adam F, Morel PC. Les Tiques du Monde: Nomenclature, Stades Décrits, Hôtes, Répartition (Acarida, Ixodida). Paris: Orstom (1998).

Google Scholar

7. Camicas JL, Morel P. Position systématique et classification des tiques (Acarida: Ixodida). Acarologia. (1977) 18:410–20.

Google Scholar

8. Filippova NA. Argasid ticks (Argasidae). Fauna SSSR. (1966) 4:1–255.

Google Scholar

9. Pospelova–Shtrom MV. On the system of classification of ticks of the family Argasidae Can., 1890. Acarologia. (1969) 11:1–22.

PubMed Abstract | Google Scholar

10. Pospelova–Shtrom MV. On the Argasidae system (with description of two new subfamilies, three new tribes and one new genus). Med Parazitol. (1946) 15:47–58.

Google Scholar

11. Klompen J, Oliver JH. Systematic relationships in the soft ticks (Acari: Ixodida: Argasidae). Syst Entomol. (1993) 18:313–31. doi: 10.1111/j.1365-3113.1993.tb00669.x

CrossRef Full Text | Google Scholar

12. Mans BJ, Featherston J, Kvas M, Pillay K, de Klerk DG, Pienaar R, et al. Argasid and ixodid systematics: implications for soft tick evolution and systematics, with a new argasid species list. Ticks Tick Borne Dis. (2019) 10:219–40. doi: 10.1016/j.ttbdis.2018.09.010

PubMed Abstract | CrossRef Full Text | Google Scholar

13. Burger TD, Shao R, Labruna MB, Barker SC. Molecular phylogeny of soft ticks (Ixodida: Argasidae) inferred from mitochondrial genome and nuclear rRNA sequences. Tick Borne Dis. (2014) 5:195–207. doi: 10.1016/j.ttbdis.2013.10.009

PubMed Abstract | CrossRef Full Text | Google Scholar

14. Mans BJ, Kelava S, Pienaar R, Featherston J, Castro MH, Quetglas J, et al. Nuclear (18S−28S rRNA) and mitochondrial genome markers of Carios (Carios) vespertilionis (Argasidae) support Carios Latreille, 1796 as a lineage embedded in the Ornithodorinae: re–classification of the Carios sensu Klompen and Oliver (1993) clade into its respective subgenera. Ticks Tick Borne Dis. (2021) 12:101688. doi: 10.1016/j.ttbdis.2021.101688

PubMed Abstract | CrossRef Full Text | Google Scholar

15. Wen T, Chen Z. The world list of ticks. 1. Argasidae and Nuttallielidae (Acari: Ixodida). Chin J Parasitol and Parasitic Dis. (2016) 34:58–74.

PubMed Abstract | Google Scholar

16. Sun Y, Xu R, Liu Z, Wu M, Qin T. Ornithodoros (Ornithodoros) huajianensis sp. nov. (Acari, argasidae), a new tick species from the Mongolian marmot (Marmota bobak sibirica), Gansu province in China. Int J Parasitol Parasites Wildl. (2019) 9:209–17. doi: 10.1016/j.ijppaw.2019.05.001

PubMed Abstract | CrossRef Full Text | Google Scholar

17. Li C. The presence of Argas persicus Oken, 1818 in Chapchar, Sinkiang. Acta Entomol Sin. (1960) 10:142.

Google Scholar

18. Nuer K, Jin Y, Liu Z, Lin T, Ailixire M, Wusiman D, et al. Investigation and identification of ticks from sheep in Shanshan Xingjiang. Grass Feed Livest. (2015) 5:51–3. doi: 10.16863/j.cnki.1003-6377.2015.05.013

CrossRef Full Text | Google Scholar

19. Zhao Q, Gao L, Tang Z, Zhang Y. Investigation of species, temporal and spatial distribution of ticks in Henan province, China. Chin J Vector Control. (2015) 26:75–7. doi: 10.11853/j.issn.1003.4692.2015.01.020

CrossRef Full Text | Google Scholar

20. Xu Q. Diagnosis and treatment of sheep tick disease in the Yellow River Delta. Agric Knowl. (2014) 43:52–3.

Google Scholar

21. Liu Y, Huang X, Du Y, Wang H, Xu B. Survey on ticks and detection of new bunyavirus in some vect in endemic areas of fever, thrombocytopenia and leukopenia syndrome (FTLS) in Henan province. Chin J Pre Med. (2012) 46:500–4. doi: 10.1039/A700330G

PubMed Abstract | CrossRef Full Text | Google Scholar

22. Yang Y, Cao J, Zhao HB, Zhang J, Di W, Gao X. Investigation on species and nature geographic distribution of ticks in Shaanxi province. Chin J Hyg Insectic Equip. (2008) 14:97–9. doi: 10.3969/j.issn.1671-2781.2008.02.007

CrossRef Full Text | Google Scholar

23. Yang Y, Di W, Cao J, Zhang J, Luo X, Gao X, et al. Investigation on kinds and nature geographic distribution of ticks in Qinghai province. Chin J Hyg Insectic Equip. (2008) 14:201–3. doi: 10.3969/j.issn.1671-2781.2008.03.018

CrossRef Full Text | Google Scholar

24. Liao F, Li W. A case of Argas persicus disease. Chin J Parasit Dis Con. (2003) 16:342. doi: 10.3969/j.issn.1673-5234.2003.06.035

CrossRef Full Text | Google Scholar

25. Da N, Su Y, Liu T, Wu G, Wang Y, Zhang S. Experiment on killing ticks of Argas persicus in chicken with nitrophenol. Mod J Anim Husb Vet Med. (2001) 16:30. doi: 10.3969/j.issn.1672-9692.2001.06.024

CrossRef Full Text | Google Scholar

26. Liu F, Yu G, Du Y. Diagnosis and treatment of ticks of Argas persicus in laying hens. Rural Sci Technol. (1999) 4:28. doi: 10.19777/j.cnki.issn1002-6193.1999.04.034

PubMed Abstract | CrossRef Full Text | Google Scholar

27. Wang X, Liu S, Zhang L. Diagnosis and treatment of chicken borreliosis in Hami area. Xinjiang Anim Husb. (1995) 2:31–2. doi: 10.16795/j.cnki.xjxmy.1995.02.009

CrossRef Full Text | Google Scholar

28. Shao G. Studies on biology and chemical control of Alveonasu lahorensis (Neumenann), 1908. Chin J Vector Biol Control. (1991) 2:25–7.

Google Scholar

29. Moussa MI, Main AJ, Shuan K. A member of the Dera Ghazi Khan serogroup (Bunyaviridae: Nairovirus) from Argas (Persicargas) robertsi (Acari: Argasidae) in Taiwan and Indonesia. J Med Entomol. (1989) 26:425–9. doi: 10.1093/jmedent/26.5.425

CrossRef Full Text | Google Scholar

30. Tian Q. Study on the life cycle of Argas persicus (Oken). Acta Vet Zootech Sin. (1989) 20:160–1.

Google Scholar

31. Qi Z, Liu L, Liu L, Kuang M. Preliminary report on observation results of life history of Argas persicus. J Med Pest Control. (1988) 4:13–5.

Google Scholar

32. Lu D. Chicken tick and its control. Xinjiang Farm Res Sci Technol. (1988) 5:16–9.

Google Scholar

33. Wang G, Shi F. Argas japonicus found in Hinggan League. Chin J Prev Med. (1987) 31:169.

Google Scholar

34. Li W, Du X, Zhong D. Investigation on human dermatitis caused by Argas japonicus in bedroom. Parasites Parasit Dis. (1986) 4:77.

Google Scholar

35. Lv F. First discovery of Apoplasmosis and its vector Ornithodoros in China. Mod J Anim Husb Vet Med. (1986) 3:19–21.

Google Scholar

36. Jeu M. Studies on the life history of Argas (Carios) sinensis Jeu et Zhu (Ixodoidea: Argasidae). Henan J Prev Med. (1983) 4:73.

Google Scholar

37. Lei M. A case of human invasion by Argas. Henan J Pre Med. (1983) 4:73.

Google Scholar

38. Jeu M, Zhu C. A new species of bat ticks from China. Acta Entomol Sin. (1982) 25:328–31. doi: 10.16380/j.kcxb.1982.03.019

CrossRef Full Text | Google Scholar

39. Di K. Preliminary observation on the living habits and growth and decline of Argas persicus. Shandong Agric Sci. (1982) 2:53–4, 28.

Google Scholar

40. Shao G. Investigation method of tick relapsing fever foci. People's Mil Surg. (1982) 3:17–9.

Google Scholar

41. Zhang Z, Yang J, Zhang G, Zhang Z. Investigation on Ornithodoros lahorensis in Minghua district, Sunan county, Gansu province. J Vet Sci Technol. (1981) 11: 25–7. doi: 10.16656/j.issn.1673-4696.1981.11.007

CrossRef Full Text | Google Scholar

42. Xia L, Liu C, Wang Z, Du J. Preliminary notes on ticks in Anhui. J Anhui Med College. (1981) 16:32–5.

Google Scholar

43. Di K. Chicken tick (Argas persicus). Poult Sci. (1980) 1:34–6.

Google Scholar

44. Huang K. A New discovery of Ornithodoros papillipes in Shanxi Province. Shanxi Med J. (1979) 5:16–8, 66.

Google Scholar

45. Teng K, Song J. A new species of Argas from Jiangxi, China (Acarina: Argasidae). Acta Zootaxonomica Sin. (1983) 8:153–6.

Google Scholar

46. Chen Z, Yang X, Liu J. Research report of medical ticks and mites in Hebei province. Chin J Pest Control. (2006) 22:238–40.

PubMed Abstract | Google Scholar

47. Chen Z, Yang X, Liu J. Geographical distribution and fauna of Chinese ticks. Sichuan J Zool. (2008) 27:820–3.

Google Scholar

48. Feng C, Shao G, Zhu J. Investigation and study on infection vectors of tick–borne relapsing fever. Mil Med Res. (1960) 2:47–52.

Google Scholar

49. Qin Z, Zhou H, Meng Y. Advances in karyotype of ticks. Acta Pharmacol Sin. (1997) 6:74–80.

PubMed Abstract | Google Scholar

50. Li W, Huang Y, Yuan J. Preliminary study on SDS polyacrylamide gel electrophoresis for the determination of proteins in ticks. J Parasit Dis. (1988) 6:150.

Google Scholar

51. Chen Z, Yang X. Systematics and Taxonomy of Ixodida. Beijing: Science Press (2021).

Google Scholar

52. Chen Z, Yang X, Bu F, Yang X, Yang X, Liu J. Ticks (Acari: Ixodoidea: Argasidae, Ixodidae) of China. Exp Appl Acarol. (2010) 51:393–404. doi: 10.1007/s10493-010-9335-2

PubMed Abstract | CrossRef Full Text | Google Scholar

53. Sun Y, Xu R, Wu M. Systematics of Argasid ticks (Ixodida: Argasidae) in China with a pictorial key to species. Acta Parasitol Et Med Entomol Sin. (2019) 26:231–50. doi: 10.3969/j.issn.1005-0507.2019.04.005

CrossRef Full Text | Google Scholar

54. Dun W. Taxonomy Study on Ticks From China (Acari: Ixodida). University of Chinese Academy of Sciences (2013).

Google Scholar

55. Teng K. Notes on Chinese ticks of the subgenus Argas (Acarina: Argasidae: Argas). Acta Zootaxonomica Sin. (1983) 8:255–61.

Google Scholar

56. Zhao L, Lin X, Li F, Li K, He B, Zhang L, et al. A survey of argasid ticks and tick–associated pathogens in the Peripheral Oases around Tarim Basin and the first record of Argas japonicus in Xinjiang, China. PloS ONE. (2018) 13:e208615. doi: 10.1371/journal.pone.0208615

PubMed Abstract | CrossRef Full Text | Google Scholar

57. Yan P, Qiu Z, Zhang T, Li Y, Wang W, Li M, et al. Microbial diversity in the tick Argas japonicus (Acari: Argasidae) with a focus on Rickettsia pathogens (Article). Med Vet Entomol. (2019) 33:327–35. doi: 10.1111/mve.12373

PubMed Abstract | CrossRef Full Text | Google Scholar

58. Hu X, Liu J, Bao R. Redescription and molecular characterization of the tick Argas japonicus Yamaguti, Clifford & Tipton, 1968 (Ixodida: Argasidae). Parasitol Res. (2021) 120:3645–51. doi: 10.1007/s00436-021-07320-7

PubMed Abstract | CrossRef Full Text | Google Scholar

59. Yamaguti N, Tipton V, Keegan HL, Toshioka S. Ticks of Japan, Korea, and the Ryukyu Islands. Brigham Young University Science Bulletin Biological (1971).

Google Scholar

60. Kobayashi D, Komatsu N, Faizah AN, Amoa–Bosompem M, Isawa H. A novel nyavirus lacking matrix and glycoprotein genes from Argas japonicus ticks. Virus Res. (2021) 292:198254. doi: 10.1016/j.virusres.2020.198254

PubMed Abstract | CrossRef Full Text | Google Scholar

61. Yamauchi T. A bibliographical survey on Ixodid fauna of Shimane Prefecture, Japan (Acari: Ixodoidea). Bull Hoshizaki Green Found. (2005) 8:289–301.

Google Scholar

62. Uchikawa K. A membrane feeding method for Argas japonicus (Ixodoidea: Argasidae) and applications of this method for culturing the tick and for oral infection of Japanese encephalitis virus. Appl Entomol Zool. (1976) 27:207–16. doi: 10.7601/mez.27.207

CrossRef Full Text | Google Scholar

63. Kitaoka S, Fujisaki K. Accumulating process and concentration ratios of ingested blood meals in larvae and nymphs of ten species of ticks. Natl Inst Anim Health Q. (1976) 16:114–21.

PubMed Abstract | Google Scholar

64. Uchikawa K. Biological data for Argas japonicus Yamaguti, Clifford and Tipton under natural conditions (Ixodoidea: Argasidae). Jpn J Sanit Zool. (1975) 26:207–12. doi: 10.7601/mez.26.207

CrossRef Full Text | Google Scholar

65. Chunikhin SP, Takahashi M. An attempt to establish the chronic infection of pigeons with Japanese encephalitis virus. Med Entomol Zool. (1971) 22:155–60. doi: 10.7601/mez.22.155

CrossRef Full Text | Google Scholar

66. Uchikawa K, Sato A. Tarsal chaetotaxy of Argas japonicus Yamaguti, Clifford and Tipton, 1968 (Ixodoidea: Argasidae). Med Entomol Zool. (1968) 19:157–61. doi: 10.7601/mez.19.157

CrossRef Full Text | Google Scholar

67. Uchikawa K, Sato A. The occurrence of Argas japonicus and Ixodes lividus in Nagano Prefecture, Japan (Ixodoidea: Argasidae; Ixodidae). J Med Entomol. (1969) 6:95–7. doi: 10.1093/jmedent/6.1.95

PubMed Abstract | CrossRef Full Text | Google Scholar

68. Saito K, Iijima T, Minai M. Studies on the effect of several insecticides aganist Argas japonicus. Med Entomol Zool. (1969) 20:39–41. doi: 10.7601/mez.20.39

CrossRef Full Text | Google Scholar

69. Fujita H, Yano Y, Takada N, Ando S, Fujita N. Tick species and tick–borne rickettsiae confirmed by the year of 2012 in Fukushima Prefecture, Japan. Med Entomol Zool. (2013) 64:37–41. doi: 10.7601/mez.64.37

CrossRef Full Text | Google Scholar

70. Takada N, Fujita H, Yamaguch T. Studies on ixodid fauna in the northern part of Honshu, Japan: 2. Human cases of tick infestation, especially many cases with a large species Ixodes acutitarsus (Karsh, 1880). Med Entomol Zool. (1978) 29:216–8. doi: 10.7601/mez.29.216

CrossRef Full Text | Google Scholar

71. Sun M. First Discovery of Argas Persicus and Ornithodorus lahorensis in Minqin County of Gansu Province. China Anim Health Inspect. (2016)33:1–3.

Google Scholar

72. Teng K. Economic Insect Fauna of China. Fasc 15 Acari: Ixodoidea. Beijing: Science Press (1978).

Google Scholar

73. Yu X, Ye R, Gong Z. The Tick Fauna of Xinjiang. Urumqi: Xinjiang Scientific, Technological and Medical Publishing House (1997).

Google Scholar

74. Wang H, Gan J, Li L, Zhang F. Preliminary investigation on ticks in Hexi region of Gansu Province. Chinese J Hyg Insecticides Equip. (2018) 24:386–7.

Google Scholar

75. Lu Z, Di K. Preliminary observation on the relationship between tick fluctuation and seasonal temperature in chickens. Chinese J Vet Med. (1982) 8:19.

Google Scholar

76. Hao Y, Xu Z, Ma C. A report of Argas persicus infestation in man. Chinese J Parasitol Parasitic Dis. (1995) 13:137.

Google Scholar

77. Nuttall GH, Warburton C, Cooper WF, Robinson LE. Ticks: A Monograph of the Ixodoidea. Cambridge University Press (1908).

Google Scholar

78. Pantaleoni RAA, Baratti MA, Barraco L, Contini CC, Cossu CSA, Filippelli MTA, et al. Argas (Persicargas) persicus (Oken, 1818) (Ixodida: Argasidae) in sicily with considerations about its italian and west–mediterranean distribution (Article). Parasite J Soc Francaise Parasitol. (2010) 17:349–55. doi: 10.1051/parasite/2010174349

PubMed Abstract | CrossRef Full Text | Google Scholar

79. Basu AK, Charles RA. Chapter 3–tick species present in Trinidad and Tobago. In: Ticks of Trinidad and Tobago–An Overview. London: Academic Press (2017). p. 39–77.

Google Scholar

80. Mu Oz–Leal SA, Venzal JMB, Nava SC, Reyes MA, Martins TFA, Leite RCD, et al. The geographic distribution of Argas (Persicargas) miniatus and Argas (Persicargas) persicus (Acari: Argasidae) in America, with morphological and molecular diagnoses from Brazil, Chile and Cuba (Article). Ticks Tick Borne Dis. (2018) 9:44–56. doi: 10.1016/j.ttbdis.2017.10.009

PubMed Abstract | CrossRef Full Text | Google Scholar

81. Prasad V, Bindra O, Miranpuri G. Tick fauna of north–western India (Acarina: Metastigmata). Int J Acarol. (1975) 1:31–54. doi: 10.1080/01647957508683735

CrossRef Full Text | Google Scholar

82. Barker SC, Walker AR. Ticks of Australia. The species that infest domestic animals and humans. Zootaxa. (2014) 3816:1–144. doi: 10.11646/zootaxa.3816.1.1

PubMed Abstract | CrossRef Full Text | Google Scholar

83. Ali A, Khan MA, Zahid H, Yaseen PM, Ibrahim M. Seasonal dynamics, record of ticks infesting humans, wild and domestic animals and molecular phylogeny of Rhipicephalus microplus in Khyber Pakhtunkhwa Pakistan. Front Physiol. (2019) 10:793. doi: 10.3389/fphys.2019.00793

PubMed Abstract | CrossRef Full Text | Google Scholar

84. Duan D, Liu Y, Liu L. Microbiome analysis of the midguts of different developmental stages of Argas persicus in China. Ticks Tick Borne Dis. (2021) 13:101868. doi: 10.1016/j.ttbdis.2021.101868

PubMed Abstract | CrossRef Full Text | Google Scholar

85. Zhang F, Wang X. Molecular epidemiology of tick–borne pathogens along Hexi corridor of Gansu province. J Third Mil Med Univ. (2021) 43:1598–602. doi: 10.16016/j.1000-5404.202103029

CrossRef Full Text | Google Scholar

86. Feng J, Wu M, Wu L, Huang T, Zhang J, Renbatu N, et al. Identification of two genotypes of Argas persicus and associated rickettsia–specific genes from different regions of Inner Mongolia. J Parasitol. (2019) 105:92–101. doi: 10.1645/18-27

PubMed Abstract | CrossRef Full Text | Google Scholar

87. Liu K, Ding X, Chen L, Zhai L. Diagnosis and treatment report of a gosling spirochetes disease. Jilin Anim Husb Vet Med. (2006) 4:42–3.

Google Scholar

88. Komarov A. On the recovery of Egyptionella pullorum carpano from wild Argas persicus Oken. Trans R Soc Trop Med Hyg. (1934) 27:525–6. doi: 10.1016/S0035-9203(34)90020-1

CrossRef Full Text | Google Scholar

89. Sarwar M. Status of Argasid (Soft) Ticks (Acari: Parasitiformes: Argasidae) in relation to transmission of human pathogens. Int J Vaccines Vaccin. (2017) 4:00089. doi: 10.15406/ijvv.2017.04.00089

CrossRef Full Text | Google Scholar

90. Labuda M, Nuttall PA. Tick–borne viruses. Parasitol. (2004) 129:S221–45). doi: 10.1017/S0031182004005220

PubMed Abstract | CrossRef Full Text | Google Scholar

91. Singh KR, Goverdhan MK, Bhat UK. Transmission of Kyasanur Forest disease virus by soft tick, Argas persicus (Ixodoidea: Argasidae). Indian J Med Res. (1971) 59:213–8.

PubMed Abstract | Google Scholar

92. Suitor EC, Weiss E. Isolation af a Rickettsia like Microorganism (Wolbachia Persica, n. sp.) from Argas Persicus (Oken). J Infect Dis. (1961) 108:95–106. doi: 10.1093/infdis/108.1.95

CrossRef Full Text | Google Scholar

93. Robbins RG. The ticks (Acari: Ixodida: Argasidae, Ixodidae) of Taiwan: a synonymic checklist. Proc Entomol Soc Washington. (2005) 107:245–53.

Google Scholar

94. Maa TC, Kuo JS. Catalogue and bibliography of ticks and mites parasitic on vertebrates in Taiwan. Q J Taiwan Mus. (1966) 19:373–413.

Google Scholar

95. Shimada TL, Trager W, Adams CT. Provisional List of the Medically Important Fauna of Taiwan (Formosa). 5th Epidemiological Flight. San Francisco, CA: Pacific Air Forces (1961).

Google Scholar

96. Luh PL, Woo WC. A list of Chinese ticks. Chin J Entomol. (1950) 1:195–222.

Google Scholar

97. Anonymous. Epidemiology of Diseases of Naval Importance in Formosa. NavMed 266, Bureau of Medicine and Surgery, Navy Department, Washington, DC (1944).

Google Scholar

98. Kishida K. Notes on the Acarina–mites and ticks (including Amblyomma yajimai sp. n., on water buffalo) from the island of Formosa, collected in August, 1935. Lansania. (1935) 7:129–44.

Google Scholar

99. Zhou H, Meng Y. Studies on the karyotypes of Argas persicus Oken (Argasidae) in connection with its cytotaxonomy (Acari: Argasidae). Acta Zootaxon Sin. (1988) 13:356–62.

Google Scholar

100. Goroschenko yes. (1962) 41:358–363. doi: 10.1049/tpe.1962.0053

CrossRef Full Text | Google Scholar

101. Petney TN, Saijuntha W, Boulanger N, Chitimia–Dobler L, Pfeffer M, Eamudomkarn C, et al. Ticks (Argasidae, Ixodidae) and tick–borne diseases of continental Southeast Asia. Zootaxa. (2019) 4558:1–89. doi: 10.11646/zootaxa.4558.1.1

PubMed Abstract | CrossRef Full Text | Google Scholar

102. Kimito U, Tsuneaki K. A Contribution to the Ectoparasite Fauna of Bats in Thailand II. Blood–Sucking Acari (Argasidae, Spinturnicidae and Macronyssidae). Contributions from the Biological Laboratory, Kyoto University (1978)25:249.

Google Scholar

103. Kwak ML. Ticks in the Lion City: a preliminary review of the tick fauna of Singapore. Exp Appl Acarol. (2018) 76:263–7. doi: 10.1007/s10493-018-0305-4

PubMed Abstract | CrossRef Full Text | Google Scholar

104. Leong TM, Shunari M, Lim K. The narrow–winged Pipisterelle, Pipistrellus Stenopterus (Dobson) in Singapore (Mammalia: Chiroptera: Vespertilionidae). Nat Singapore. (2010) 3:159–65.

Google Scholar

105. Kazim AR, Houssaini J, Ehlers J, Tappe D, Heo CC. Soft ticks (Acari: Argasidae) in the island nations of Southeast Asia: a review on their distribution, associated hosts and potential pathogens. Acta Trop. (2021) 223:106085. doi: 10.1016/j.actatropica.2021.106085

PubMed Abstract | CrossRef Full Text | Google Scholar

106. de la Fuente J, Estrada–Pena A, Venzal JM, Kocan KM, Sonenshine DE. Overview: ticks as vectors of pathogens that cause disease in humans and animals. Front Biosci. (2008) 13:6938–46. doi: 10.2741/3200

PubMed Abstract | CrossRef Full Text | Google Scholar

107. Sugimoto. Ticks of Taiwan. Taihoku Imperial University, Taipei (1939).

Google Scholar

108. Pfäffle MP, Petney TN. Argas reflexus (Fabricius, 1794) (Figs. 4 and 5). In: Estrada–Peña A, Mihalca AD, Petney TN, editors. Ticks of Europe and North Africa. Cham: Springer (2017). p. 21–4.

Google Scholar

109. Lvov DK, Shchelkanov MY, Alkhovsky SV, Deryabin PG. Single–stranded RNA viruses. Zoonotic Viruses Northern Eurasia. (2015) 2015:135–392. doi: 10.1016/B978-0-12-801742-5.00008-8

CrossRef Full Text | Google Scholar

110. Hoogstraal H, Kohls GM. Observations on the Subgenus Argas (Ixodoidea, Argasidae, Argas) 1. Study of A. reflexus reflexus (Fabricius, 1794), the European Bird Argasid. Ann Entomol Soc Am. (1960) 53:611–8. doi: 10.1093/aesa/53.5.611

CrossRef Full Text | Google Scholar

111. Chang H, Yang P, Bai X, Yang S, Wei H, Tian T, et al. Preliminary investigation of gamasid mites and tickes in nest of Pyrrhocoax pyrrhocoax at Lingwu, Ningxia plague foci. Acta Arach Sin. (2016) 25:109–10. doi: 10.3969/j.issn.1005-9628.2016.02.012

CrossRef Full Text | Google Scholar

112. Fan S, Li YH Xu Z, Zhao S, Wang S. Argas reflexus found in the student dormitory of Harbin Medical University and its investigation on the Spot. J Harbin Med Univ. (1998) 32:18–20.

Google Scholar

113. Hillyard PD. Ticks of North–West Europe. Emerg Pests Vector Borne Dis Eur. (1996) 3:320–1. doi: 10.1016/S1684-1182(10)60083-7

PubMed Abstract | CrossRef Full Text | Google Scholar

114. Jongejan F, Uilenberg G. The global importance of ticks. Parasitol. (2004) 129:S3–14. doi: 10.1017/S0031182004005967

PubMed Abstract | CrossRef Full Text | Google Scholar

115. Tahmasebi F, Ghiasi SM, Mostafavi E, Moradi M, Piazak N, Mozafari A, et al. Molecular epidemiology of Crimean–Congo hemorrhagic fever virus genome isolated from ticks of Hamadan province of Iran. J Vector Borne Dis. (2010) 47:211–6.

Google Scholar

116. Nuttall PA, Jones LD, Labuda M, Kaufman WR. Adaptations of Arboviruses to Ticks. J Med Entomol. (1994) 31:1–9. doi: 10.1093/jmedent/31.1.1

PubMed Abstract | CrossRef Full Text | Google Scholar

117. Petney TN, Skuballa MPPF. An annotated checklist of the ticks (Acari: Ixodida) of Germany. Syst Appl Acarol. (2012) 17:115–70. doi: 10.11158/saa.17.2.2

CrossRef Full Text | Google Scholar

118. Vermeil C, Marjolet M, Chastel C. Argas et arbovirus actualités. Bull Soc Pathol Exot. (1996) 89:363–5.

Google Scholar

119. Hoogstraal H, Guirgis SS, Khalil GM, Kaiser MN. The subgenus Persicargas (Ixodoidea: Argasidae: Argas). 27. The life cycle of A. (P.) robertsi population samples from Taiwan, Thailand, Indonesia, Australia, and Sri Lanka. Southeast Asian J Trop Med Public Health. (1975) 6:532–9.

PubMed Abstract | Google Scholar

120. Khalil GM, Hoogstraal H, Oliver JH. Biological evaluation of the systematic validity of the African Argas (Persicargas) arboreus and the Asian–Australian A.(P.) robertsi (Ixodoidea: Argasidae). Int J Parasitol. (1980) 10:253–9. doi: 10.1016/0020-7519(80)90005-3

PubMed Abstract | CrossRef Full Text | Google Scholar

121. Liu X, Yan B, Wang Q, Jiang M, Tu C, Chen C, et al. Babesia vesperuginis in common Pipistrelle (Pipistrellus pipistrellus) and the bat soft tick Argas vespertilionis in the People's Republic of China. J Wildl Med. (2018) 54:419–21. doi: 10.7589/2017-08-206

PubMed Abstract | CrossRef Full Text | Google Scholar

122. He C, Wan D, Zhong Y, Lan Y, Liao C, Long S, et al. Investigation on ticks and their ASFV carrying situation in China–Vietnam border regions in Guangxi. China Anim Health Inspect. (2021) 38:31–4, 43. doi: 10.3969/j.issn.1005-944X.2021.06.007

CrossRef Full Text | Google Scholar

123. Hornok S, Szoke K, Gorfol T, Foldvari G, Vuong TT, Takacs N, et al. Molecular investigations of the bat tick Argas vespertilionis (Ixodida: Argasidae) and Babesia vesperuginis (Apicomplexa: Piroplasmida) reflect 'bat connection' between Central Europe and Central Asia. Exp Appl Acarol. (2017) 72:69–77. doi: 10.1007/s10493-017-0140-z

PubMed Abstract | CrossRef Full Text | Google Scholar

124. Zhao S, Yang M, Liu G, Hornok S, Zhao S, Sang C, et al. Rickettsiae in the common pipistrelle Pipistrellus pipistrellus (Chiroptera: Vespertilionidae) and the bat soft tick Argas vespertilionis (Ixodida: Argasidae). Parasit Vectors. (2020) 13:10. doi: 10.1186/s13071-020-3885-x

PubMed Abstract | CrossRef Full Text | Google Scholar

125. Petney TN, Jaenson TGT, Pfäffle MP. Argas vespertilionis (Latreille, 1796) (Figs. 8 and 9). In: Estrada–Peña A, Mihalca AD, Petney TN, editors. Ticks of Europe and North Africa. Cham: Springer (2017). p. 33–6.

Google Scholar

126. Borel M. Note sur la presence d'Argas vespertilionis (Latreille) 1796 au Cambodge. Bull Soc Pathol Exot. (1928) 21:328.

Google Scholar

127. L'Vov DK, Al'Khovskii SV, Shchelkanov MI, Shchetinin AM, Deriabin PG, Aristova VA, et al. Taxonomic status of the Tyulek virus (TLKV) (Orthomyxoviridae, Quaranjavirus, Quaranfil group) isolated from the ticks Argas vulgaris Filippova, 1961 (Argasidae) from the birds burrow nest biotopes in the Kyrgyzstan. Vopr Virusol. (2014) 59:28–32.

PubMed Abstract | Google Scholar

128. Gordeeva ZE, Kostiukov MA, Kuima AU, Daniiarov OA, Bulychev VP, Nemova NV, et al. The Hissar virus–a new virus of the family Bunyaviridae–isolated from the argasid tick Argas vulgaris Fil. in Tadzhikistan. Med Parazitol. (1990) 6:34–5.

Google Scholar

129. Kleinerman G, Baneth G.Ornithodoros (Alectorobius) capensis Neumann, 1901 (Figs. 12 and 13). In: Estrada–Peña A, Mihalca AD, Petney TN, editors. Ticks of Europe and North Africa. Cham: Springer (2017). p. 45–9.

Google Scholar

130. Hoogstraal H, Kaiser MN, Easton ER. Ornithodoros (Alectorobius) capensis Neumann (Ixodoidea: Argasidae) parasitizing a human and birds nesting on islands in East African lakes. J Med Entomol. (1976) 12:703–4. doi: 10.1093/jmedent/12.6.703

PubMed Abstract | CrossRef Full Text | Google Scholar

131. Kohls GM, Sonenshine DE, Clifford CM. The Systematics of the subfamily Ornithodorinae (Acarina: Argasidae). II. identification of the larvae of the western hemisphere and descriptions of three new species1. Ann Entomol Soc Am. (1965) 58:331–64. doi: 10.1093/aesa/58.3.331

PubMed Abstract | CrossRef Full Text | Google Scholar

132. Manzanoromán R, Díazmartín V. Soft ticks as pathogen vectors: distribution, surveillance and control. Parasitology. (2012) 7:125–62. doi: 10.5772/32521

CrossRef Full Text | Google Scholar

133. Dupraz M, Toty C, Noël V, Estrada–Pena A, González–Solís J, Boulinier T, et al. Linking morphometric and genetic divergence with host use in the tick complex, Ornithodoros capensis sensu lato. Infect Genet Evol. (2016) 46:12–22. doi: 10.1016/j.meegid.2016.10.005

PubMed Abstract | CrossRef Full Text | Google Scholar

134. Kim HC, Park CU, Kim M, Kim YM, Cho SY, Choi KH, et al. Ticks (Acari: Ixodida: Ixodidae) collected from nest soil and litter of Synthliboramphus antiquus on Chilbal Island, Jeollanam Province, Republic of Korea, with the first Korean record of Ixodes uriae White. Syst Appl Acarol. (2017) 22:962–7. doi: 10.11158/saa.22.7.5

CrossRef Full Text | Google Scholar

135. Ailixire M, Bayinchahan, Wu H, Wusiman D, Nuer K, Liu Z. Identification of Ornithodoros lahorensis and its infectious investigation on sheep. Chin J Vet Med. (2017) 53:6–8.

Google Scholar

136. Lv J, Zhao L, Zhao Y, Han X, Wang H, Wu S. Morphological and molecular biology identification of Ornithodoros lahorensis. China Ani Husb Vet Med. (2017) 44:1149–58. doi: 10.27431/d.cnki.gxnyu.2017.000099

CrossRef Full Text | Google Scholar

137. Hoogstraal H, Wassef HY, Diab FM, Al–Asgah NA, Al–Khalifa MS. Acarina of Saudi Arabia Ornithodoros (Alveonasus) lahorensis (Fam. Argasidae) in Saudi Arabia. Bio Vet Med Impli. (1984) 6:165–9.

Google Scholar

138. Parrish DW. The ticks (Argasidae and Ixodidae) of Turkey. J Econ Entomol. (1961) 54:91–2. doi: 10.1093/jee/54.1.91

CrossRef Full Text | Google Scholar

139. Sonenshine DE, Clifford CM, Kohls GM. The systematics of the subfamily Ornithodorinae (Acarina: Argasidae). III. identification of the larvae of the eastern hemisphere. Ann Entomol Soc Am. (1966) 59:92–122. doi: 10.1093/aesa/59.1.92

PubMed Abstract | CrossRef Full Text | Google Scholar

140. Estrada–Pe AA, Jongejan F. Ticks feeding on humans: a review of records on human–biting Ixodoidea with special reference to pathogen transmission. Exp Appl Acarol. (1999) 23:685–715. doi: 10.1023/A:1006241108739

PubMed Abstract | CrossRef Full Text | Google Scholar

141. Kleinerman G, Baneth G. Ornithodoros (Alectorobius) lahorensis Neumann, 1908 (Figs. 19 and 20). In: Estrada-Peña A, Mihalca AD, Petney TN, editors. Ticks of Europe and North Africa. Cham: Springer (2018). p. 63–6.

Google Scholar

142. Xie J. Clinical observations on 12 cases of tick relapsing fever. People's Mil Surg. (1959) 2:109–10.

Google Scholar

143. Neumann LG. Revision de la famille des Ixodides. I. Argasines. Memoirs Soc Zool France. (1896) IX:1–44. doi: 10.5962/t.173870

CrossRef Full Text | Google Scholar

144. Neumann LG. Revision de la famille des Ixodides. 4e Metnoire. Memoirs Soc Zool France. (1901) xiv:249–372.

Google Scholar

145. Assous MV, Wilamowski A. Relapsing fever borreliosis in Eurasia–forgotten, but certainly not gone! Clin Microbiol Infect. (2009) 15:407–14. doi: 10.1111/j.1469-0691.2009.02767.x

PubMed Abstract | CrossRef Full Text | Google Scholar

146. Avivi A, Warburg M, Galun R. Ecological studies on the cave tick Ornithodoros tholozani and its distribution in Israel. Israel J Entomol. (1973) 3:109–1929.

Google Scholar

147. Kleinerman G, Baneth G. Ornithodoros (Pavlovskyella) tholozani (Laboulbène and Mégnin, 1882) (Figs. 21 and 22). In: Estrada–Peña A, Mihalca AD, Petney TN, editors. Ticks of Europe and North Africa. Cham: Springer (2017). p. 67–70.

Google Scholar

148. Vial L, Ducheyne E, Filatov S, Gerilovych A, McVey DS, Sindryakova I, et al. Spatial multi–criteria decision analysis for modelling suitable habitats of Ornithodoros soft ticks in the Western Palearctic region. Vet Parasitol. (2018) 249:2–16. doi: 10.1016/j.vetpar.2017.10.022

PubMed Abstract | CrossRef Full Text | Google Scholar

149. Zhmaeva ZM, Pchelkina AA, Karulin BE, Zubkova BI, Mishchenko NK. The Characterisation of a natural Nidus of Tick–borne Rickettsiosis in the South of Central Asia (1955).

Google Scholar

Keywords: Argasidae, host and distribution, molecular characters, tick-borne pathogens, China

Citation: Chen Z and Liu J (2022) A review of argasid ticks and associated pathogens of China. Front. Vet. Sci. 9:865664. doi: 10.3389/fvets.2022.865664

Received: 30 January 2022; Accepted: 27 June 2022;
Published: 26 July 2022.

Edited by:

Sebastián Muñoz-Leal, University of Concepcion, Chile

Reviewed by:

Serhii Filatov, Baylor College of Medicine, United States
Carmen Guzmán, National Autonomous University of Mexico, Mexico

Copyright © 2022 Chen and Liu. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

*Correspondence: Jingze Liu, bGl1amluZ3plJiN4MDAwNDA7aGVidHUuZWR1LmNu

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