Bacterial and protozoal pathogens found in ticks collected from humans in Corum province of Turkey

Karasartova, Djursun; Güreser, Ayşe Semra; Gökçe, Tuncay; Çelebі, Bekіr; Yapar, Derya; Keskin, Adem; Celik, Selim; Ece, Yasemin; Erenler, Ali Kemal; Usluca, Selma; Mumcuoglu, Kosta Y.; Taylan-Özkan, Ayşegül

doi:10.1371/journal.pntd.0006395

Cited by 60 publications

(38 citation statements)

References 79 publications

(108 reference statements)

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“…Hepatozoon canis has been detected in several other tick species, including Amblyomma sculptum (Demoner et al, 2013;Melo et al, 2016), Dermacentor marginatus, (Hornok et al, 2013;Aktas, 2014;Karasartova et al, 2018), Dermacentor reticulatus (Hornok et al, 2013;Najm et al, 2014), Haemaphysalis concinna (Hornok et al, 2013;Andersson et al, 2017), Haemaphysalis parva (Orkun and Nalbantoğlu, 2018), Haemaphysalis punctata (Andersson et al, 2017), Haemaphysalis sulcata (Aktas, 2014), Ixodes canisuga, Ixodes hexagonus (Najm et al, 2014) and Ixodes ricinus (Gabrielli et al, 2010;Reye et al, 2010;Aktas, 2014;Najm et al, 2014;Hamsikova et al, 2016;Andersson et al, 2017). The vector competence of these species for H. canis is unknown, with many collected from H. canis-infected animals.…”

Section: A Better Understanding Of H Canis Vector Competence In Putamentioning

confidence: 99%

An Australian dog diagnosed with an exotic tick-borne infection: should Australia still be considered free from Hepatozoon canis?

Greay

Barbosa

Rees

et al. 2018

International Journal for Parasitology

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Recent molecular and sero-surveillance studies of the tick-borne pathogen Hepatozoon canis have identified new hosts, potential vector species, and have revealed that H. canis is more widespread than previously thought. We report the first diagnosed case of canine hepatozoonosis in Australia from a Maremma Sheepdog in Sarina, Queensland. Hepatozoon canis was detected with blood smear examination and 18S rRNA sequencing. It is unknown when or how the organism was introduced into Australia, which raises questions about border biosecurity policies and the H. canis infection status of its potential vectors and hosts in Australia. Surveillance for this pathogen is required to determine whether H. canis has established in Australia.

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Section: A Better Understanding Of H Canis Vector Competence In Putamentioning

confidence: 99%

An Australian dog diagnosed with an exotic tick-borne infection: should Australia still be considered free from Hepatozoon canis?

Greay

Barbosa

Rees

et al. 2018

International Journal for Parasitology

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“…Our analysis showed a close relationship with R. hoogstrali, a widely distributed bacterium that is still unknown for its pathogenicity in humans. This bacterium has been detected in hard ticks (Haemaphysalis punctata, Haemaphysalis sulcate, and Haemaphysalis parva), and soft ticks (Ornithodoros moubata, Carios capensis, C. sawaii, and Argas persicus) present in domestic animals, bird nests, vegetation, and human dwellings [3,[45][46][47]. A similar situation occurs with R. asemboensis.…”

Section: Discussionmentioning

confidence: 78%

Molecular detection of Rickettsia in fleas from micromammals in Chile

Moreno

Carniglia²,

Schmeisser

et al. 2020

Preprint

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BackgroundRickettsial diseases are considered important in public health due to their dispersal capacity determined by the particular characteristics of their reservoirs and / or vectors. Among the latter, fleas play an important role, since the vast majority of species parasitize wild and invasive rodents, so their detection is relevant to be able to monitor potential emerging diseases. The aim of this study was to detect, characterize, and compare Rickettsia spp. from the fleas of micromammals in areas with different human population densities in Chile.MethodsThe presence of Rickettsia spp. was evaluated by standard polymerase chain reaction (PCR) and sequencing in 1,315 fleas collected from 1,512 micromammals in 29 locations, with different human population densities in Chile. A generalized linear models (GLM) was used to identify the variables that may explain Rickettsia prevalence in fleas.ResultsDNA of Rickettsia spp. was identified in 13.2% (174 of 1,315) of fleas tested. Fifteen flea species were found to be Rickettsia-positive. The prevalence of Rickettsia spp. was higher in winter, semi-arid region and natural areas, and the infections in fleas varied between species of fleas. The prevalence of Rickettsia among flea species ranged from 0%–35.1%. Areas of lower human density have the highest prevalence of Rickettsia. The phylogenetic tree shows two well-differentiated clades. Rickettsia belli is positioned as basal in a clade. Another clade is subdivided into two subclades, and are related to Rickettsia of typhus group.ConclusionsTo our knowledge, this is the first report of the occurrence and molecular characterization of Rickettsia spp. in 15 species of fleas of micromammals in Chile. In this study, fleas were detected carrying Rickettsia DNA with zoonotic potential, mainly in villages and natural areas of Chile. Considering that there are differences in the prevalence of Rickettsia in fleas associated with different factors, more investigations are needed to further understand the ecology of Rickettsia in fleas and their implications for human health.

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“…Although some studies were not successful in isolating T. gondii from ticks collected in natural habitats or in experimental transmission [43,[59][60][61][62]., the differences might be explained with a better understanding of the ecology of ticks and their association with hosts in the different environments, including changes in tick abundance according to climatic conditions, host factors, socio-demographic factors, and agricultural and wildlife management [63]. More information is needed on how T. gondii survives in natural settings.…”

Section: Resultsmentioning

confidence: 99%

Tick transmission of toxoplasmosis

Ben-Harari¹

2019

Expert Review of Anti-infective Therapy

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Introduction: Infection with Toxoplasma gondii (T. gondii) causes the disease toxoplasmosis in humans and animals. Oral transmission alone may not explain the widespread distribution of this parasite over large species of host animals and geographic areas. Areas covered: Limited studies indicate the potential role of ticks in the distribution of T. gondii. The possibility of transmission of T. gondii has been demonstrated in Dermacentor variabilis, Dermacentor andersoni, Amblyomma americanum, Dermacentor reticulatus, Ixodes ricinus, Ixodes amblyomma, Amblyomma cajennense, Ornithodorus moubata and Haemaphysalis longicornis. Tick transmission of T. gondii, spread of ticks and pathogens by migratory birds and presence in the United States (US) of tick vectors of human and animal disease like Haemaphysalis longicornis indigenous to other parts of the world provide a possible mechanism for the widespread distribution of T. gondii, and a potentially expanding disease threat. Expert opinion: The evidence indicates that T. gondii is potentially an unrecognized tick-borne pathogen spreading toxoplasmosis, and that clinicians might consider toxoplasmosis in the differential diagnosis of tickborne diseases.

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Bacterial and protozoal pathogens found in ticks collected from humans in Corum province of Turkey

Cited by 60 publications

References 79 publications

An Australian dog diagnosed with an exotic tick-borne infection: should Australia still be considered free from Hepatozoon canis?

An Australian dog diagnosed with an exotic tick-borne infection: should Australia still be considered free from Hepatozoon canis?

Molecular detection of Rickettsia in fleas from micromammals in Chile

Tick transmission of toxoplasmosis

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