Molecular characterization of Amblyomma geoemydae using CO1 mitochondrial gene to validate phenotypic taxonomical evaluation

Animal ectoparasites are linked to the spread of serious medical and veterinary important pathogens. Our research intends to close the knowledge gap concerning the numerous ectoparasites that inhabit animals in Wayanad. Ectoparasites in animals brought to the veterinary dispensaries in Wayanad were retrieved and identified morphologically and molecularly. Using a high-quality stereomicroscope, the taxonomic features of the four following species were examined and identified: Haemaphysalis bispinosa, Rhipicephalus annulatus, R. microplus, and Amblyomma geoemydae. The important disease vector A. geoemydae was reported for the first time in Kerala. The important phenotypic characters of the highlighted species A. geoemydae are the edge of the basis capituli is circular without cornua, and the hypostomal dental formula is 2/2. The taxonomically identified four species were subjected to CO1 gene sequence analysis. The evolutionary relationship was inspected through the neighbour-joining method, and the phylogenetic tree was built through the Maximum Likelihood method. The present study has also estimated the diversity index of R. microplus, R. annulatus, H. bispinosa, and A. geoemydae. Among them, R. microplus 0.36638 have reported with the maximum diversity index score. The significance of the study is the presence of Lyme disease vector A. geoemydae, in the Wayanad District of Kerala, and it is the first report of the species from where an outbreak of Lyme disease occurred in 2013.

First zootiological survey of Amblyomma geoemydae ticks (Acari: Ixodidae) infesting a wild turtle (Cuora flavomarginata) in northern Taiwan

The prevalence of Amblyomma geoemydae infesting yellow-margined box turtle (Cuora flavomarginata) was determined for the first time in northern Taiwan. In total, 352 ticks (140 adults, 61 nymphs and 151 larvae) were collected from 56 yellow-margined box turtles. The overall infestation was observed with an average density of 6.3 ticks per turtle and the highest seasonal prevalence was observed on March with an average tick density of 14.3 ticks per turtle. The higher seasonal prevalence was observed on April, May, July and October with an average density of 4.8, 8.3, 5.7 and 8.5 ticks per turtle, respectively. The seasonal activity of these turtles may contribute to the variation in the number of collected ticks. The genetic identity was determined by comparing the sequences of ITS2 genes obtained from seven Taiwan species of A. geoemydae and nine other species representing eight Amblyomma species and Ixodes persulcatus as outgroup. Our results provide the first zootiological survey of A. geoemydae infesting wild turtles in northern Taiwan and highlight the importance of this tick species in the study of parasite dynamics on testudines in Taiwan. Further study focused on the seasonality pattern of turtle ticks will help reveal the ecology of this host-parasite system and its impact on animal/human health.

Molecular and morphological identification of a reptile-associated tick, Amblyomma geoemydae (Acari: Ixodidae), infesting wild yellow-margined box turtles (Cuora flavomarginata) in northern Taiwan

The genetic identity and morphological features of a reptile-associated tick, Amblyomma geoemydae, were examined for the first time in Taiwan. The key morphological characters of male and female Am. geoemydae were photographed using a stereo microscope. The genetic identity was analyzed by comparing the 16S mitochondrial DNA gene sequences obtained from 11 Taiwan Am. geoemydae ticks with other Amblyomma species and three Ixodes species as outgroups. All the Taiwan specimens were genetically affiliated to a monophyletic group of Am. geoemydae and could be discriminated from other Amblyomma species. Our results provide the first distinguished colour figures and first genetic identification of adult Am. geoemydae ticks infesting turtles in Taiwan. The host range and vectorial capacity of Am. geoemydae for various tick-borne pathogens need to be further clarified in Taiwan.

First molecular detection of Hemolivia and Hepatozoon parasites in reptile-associated ticks on Iriomote Island, Japan

Hepatozoon and Hemolivia are members of the haemogregarines and are reported in reptiles and reptile-associated ticks. However, no studies have reported on Hepatozoon and Hemolivia in Japanese reptile-associated ticks. This study aimed to molecularly identify and to characterize Hepatozoon and Hemolivia in Japanese reptile-associated ticks, Amblyomma geoemydae (Cantor, 1847) and Amblyomma nitidum (Hirst & Hirst, 1910). A total of 41 and 75 DNA samples from A. geoemydae and A. nitidum ticks, respectively, were used for screening of Hepatozoon and Hemolivia with polymerase chain reaction targeting 18S rDNA. As a result, Hemolivia and Hepatozoon were detected in two A. geoemydae and one A. nitidum, respectively. The sequences of Hemolivia spp. showed a 99.5% (1,050/1,055 bp) identity with Hemolivia parvula (KR069083), and the Hemolivia spp. were located in the same clade as H. parvula in the phylogenetic tree. The sequences of Hepatozoon sp. showed a 98.4% (1,521/1,545 bp) identity with Hepatozoon colubri (MN723844), and the Hepatozoon sp. was distinct from validated Hepatozoon species in the tree. Our findings highlight the first molecular record of Hemolivia in Japan and present the first detection of Hepatozoon in A. nitidum. Further investigations on these tick-borne protozoa are required to understand their life cycle and pathogenicity.

Rickettsia spp. and Ehrlichia spp. in Amblyomma ticks parasitizing wild amphibious sea kraits and yellow-margined box turtles in Okinawa, Japan

Recently, several tick-borne pathogens were detected in reptile-associated ticks. However, studies on the microorganisms in reptile-associated ticks in Japan are limited. This molecular survey thus aimed to identify and characterize tick-borne pathogens (Rickettsiaceae and Anaplasmataceae) in reptile-associated ticks in Japan. In total, 77 Amblyomma nitidum and 104 Amblyomma geoemydae were collected from wild amphibious sea kraits (Laticauda semifasciata, Laticauda colubrina, and Laticauda laticaudata) and from yellow-margined box turtles (Cuora flavomarginata evelynae), respectively. Conventional polymerase chain reaction was performed using the DNA extracted from the ticks to detect the selected pathogens. Sequencing analysis of four Rickettsia genes (gltA, ompA, ompB, and sca4) led to the identification of a putative novel Rickettsia sp. and Rickettsia aeschlimannii-like rickettsia in A. nitidum and A. geoemydae, respectively. Sequencing analysis of gltA and groEL of Anaplasmataceae revealed that the Ehrlichia spp. in these ticks were novel and related to Candidatus Ehrlichia occidentalis. This is the first study on the microorganisms in A. nitidium and the first record of Rickettsia and Ehrlichia in A. geoemydae. Further studies are required to understand their pathogenicity to humans and animals and their life cycle in the wild.

The complete mitochondrial genome of Amblyomma geoemydae (Ixodida: Ixodidae)

The complete mitochondrial genome of Amblyomma geoemydae is reported for the first time in this study. Its entire mitogenome is 14,780 bp in length, contained 13 protein-coding genes, two ribosomal RNA genes, 22 transfer RNA genes, and two non-coding regions. The phylogenetic analysis by Maximum-likelihood method show that A. geoemydae and the others of genus Amblyomma are in the same clade, indicating that A. geoemydae belongs to the genus Amblyomma.

Long term persistence of introduced Amblyomma geoemydae tick population under indoor conditions in Austria

An indoor terrarium population of Amblyomma geoemydae was established subsequent to the import of a single yellow-marginated box turtle Cuora flavomarginata. This indoor tick population revealed an unexpected resistance against de-ticking trials, with persistence between 2010 and 2015, when the ticks were successfully eliminated. Ticks were collected from the bodies and shells of turtles, as well as from terraria soil. Species diagnosis of ticks was carried out according to distinguishable morphological characters and supported by molecular analysis using DNA-barcoding. Introduced exotic ticks are potential vectors of pathogens and can have an impact on wildlife, domestic animals and the human population. This case emphasizes the need for sharp surveillance and control measures on imported reptiles.