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Article

Pathogen Detection in Ornithodoros sonrai Ticks and Invasive House Mice Mus musculus domesticus in Senegal

1
Aix-Marseille University, IRD, SSA, AP-HM, VITROME, 13005 Marseille, France
2
IHU-Méditerranée Infection, 13005 Marseille, France
3
UFR des Sciences Appliquées et de Technologie, Section Informatique, University Gaston Berger, Saint-Louis 32000, Senegal
4
Institut de Recherche Pour le Développement (IRD), VITROME IRD 257, Campus International IRD-UCAD, Hann, Dakar 1386, Senegal
5
Centre de Biologie Pour la Gestion des Populations, Institut de Recherche Pour Développement, Centre de Coopération Internationale en Recherche Agronomique Pour le Développement, Institut National de Recherche Pour l’Agriculture, l’Alimentation et l’Environnement, Institut Agro Montpellier, University Montpellier, Lez CEDEX, 34988 Montferrier, France
*
Author to whom correspondence should be addressed.
Microorganisms 2022, 10(12), 2367; https://doi.org/10.3390/microorganisms10122367
Submission received: 12 October 2022 / Revised: 21 November 2022 / Accepted: 22 November 2022 / Published: 30 November 2022
(This article belongs to the Special Issue Ticks and Tick-Borne Diseases in Animals)

Abstract

:
Ornithodoros sonrai (O. sonrai) ticks are the only known vectors of Borrelia crocidurae, an agent of tick-borne relapsing fever (TBRF) borreliosis. Rodents serve as principal natural reservoirs for Borrelia. Our research objective was to detect TBRF Borrelia and other zoonotic bacterial infections in ticks and in house mice Mus musculus domesticus, an invasive species currently expanding in rural northern Senegal. Real-time and conventional PCR were utilized for detecting Borrelia and other bacterial taxa. The analyses were performed on 253 specimens of O. sonrai and 150 samples of brain and spleen tissue from rodents. Borrelia crocidurae was found in one O. sonrai tick and 18 Mus musculus domesticus samples, with prevalences of 0.39 percent and 12 percent, respectively, as well as Ehrlichia sp. in one Mus musculus domesticus. Further, we were able to detect the presence of a potentially infectious novel species belonging to the Anaplasmataceae family for the first time in O. sonrai ticks. More attention should be paid to the house mouse and O. sonrai ticks, as they can be potential hosts for novel species of pathogenic bacteria in humans.

1. Introduction

Ticks are strict blood-sucking arthropods divided into two families, Ixodidae (about 700 hard tick species) and Argasidae (around 200 soft tick species). The latter comprises the sub-families Argasinae and Ornithodorinae, which include the genus Ornithodoros [1,2]. Ticks can have a negative impact on an animal’s health. They represent the second largest group for the transmission of infectious pathogens to humans after mosquitoes [3]. Tick-borne relapsing fever (TBRF) borreliosis is caused by various species of spirochetes of the genus Borrelia, of which Borrelia crocidurae (Léger, 1917), Borrelia duttonii (Novy and Knapp, 1906) and Borrelia hispanica (de Buen, 1926) occur in Africa. These spirochetes are transmitted by soft ticks of the genus Ornithodoros [4,5,6]. As the name implies, TBRF is characterized by recurrent fever and associated symptoms, and in extreme cases the infection can spread to the neurological and cardiovascular systems [6]. In West Africa, TBRF is endemic in the Sahara, Sahel and Sudano-Sahelian regions [5]. In West and North Africa, small mammals are considered to be the principal reservoirs of Borrelia, particularly of B. crocidurae [7], which has been detected in several rodent species [5,7,8]. Borrelia crocidurae is transmitted via a bite by the tick Ornithodoros sonrai (Sautet and Witkowski, 1943 [5,7]) that lives inside small rodent burrows [9].
In Senegal, TBRF is a major cause of diseases, although it is frequently misdiagnosed (and often confused with malaria) by clinicians due to a lack of diagnostic tools [5]. Several studies conducted in the country have reported the presence of B. crocidurae in ticks and/or small mammals [5,7,8,9,10], with a prevalence ranging from 4.54% to 72.72% for Borrelia spp. and B. crocidurae, respectively [7]. A large-scale screening in North and West Africa detected the presence of B. crocidurae in O. sonrai ticks; B. hispanica in Ornithodoros marocanus (Velu, 1919), Ornithodoros occidentalis (Trape, Diatta, Durand and Renaud, 2013) and Ornithodoros kairouanensis Trape, (Diatta, Bouattour, Durand and Renaud, 2013); and Borrelia merionesi (Blanc and Maurice, 1948) in Ornithodoros merionesi (Trape, Diatta, Belghyti, Sarih, Durand and Renaud, 2013) and Ornithodoros costalis (Diatta, Bouattour, Durand, Renaud and Trape, 2013) [5]. Other recent studies in rural areas of Senegal have also shown the presence of (i) Coxiella burnetii (Derrick, 1939), the causative agent of Q fever, in O. sonrai [11]; (ii) several bacteria in small rodent spleen tissues, namely Bartonella spp. and Anaplasmataceae with potential new species Candidatus “Ehrlichia senegalensis” (Dahmana, Granjon, Diagne, Davoust, Fenollar, Mediannikov, 2020) and Borrelia spp., with a prevalence of 9.35%, 18.12% and 15.2%, respectively [9].
The purpose of this study was to gain a better understanding of the risk associated with the transmission of TBRF and other zoonotic bacteria carried by invasive small rodents in the rural area of Dodel, northern Senegal, and more particularly the domestic mouse Mus musculus domesticus (Schwarz and Scharz, 1943) [12]. We also sought to identify an expanded repertoire of infectious agents in order to increase the awareness of pathogens transmitted by O. sonrai soft ticks, hosted by small rodents, which may have a negative impact on human and animal health.

2. Materials and Methods

2.1. Study Area

The study was conducted in the rural commune of Dodel (16°29′16.7″ N/14°25′19.0″ W), located 531 km northeast of Dakar, in the Saint-Louis region (Figure 1). In this area, the vegetation and climate are typically Sahelian, with a short wet season from July to mid-October. The survey included 60 housing plots visited for rodents and 34 for Ornithodoros ticks in 2018, as well as 77 and 10 others, respectively, in 2021 in Dodel’s central area. These houses accommodate 489 people, the majority of them belonging to the Peulh “Pulaar” ethnic group. The population is more involved in trade than in agriculture and livestock.

2.2. Sampling

Rodents were captured alive using associated sets of locally-made wire-mesh and Sherman (H.B. Sherman Traps, Inc., Tallahassee, FL, USA) folding box traps placed within dwellings (bedrooms, hallways, kitchens, etc.) and shops. Trapping campaigns within private dwellings were conducted with prior explicit oral agreements from the relevant local authority (head of village and mayor) and individual householders after providing a comprehensive presentation of the project and its objectives. The traps were baited daily with groundnut paste and left for one to three days [7,9]. They were checked every morning and afternoon (while re-baiting) for night and day captures, respectively. All specimens caught were identified according to morphological criteria as previously reported [13]. Rodents were euthanized by performing cervical dislocation and handled in accordance with the relevant requirements of Senegalese legislation and the live animal capture guidelines of the American Society of Mammalogists (Animal Care and Use Committee 2011). Body measurements were taken before autopsy and reproductive status was noted. Brain and spleen tissue as well as digestive tracts were preserved in 95% ethanol for further analyses. All protocols used here were conducted following official regulations (Centre de Biologie pour la Gestion des Populations (CBGP)): Agrément pour l’utilisation d’animaux à des fins scientifiques D-34-169-003) of the relevant institutional committee (Regional Head of the Veterinary Service, Hérault, France). All transfer and conservation procedures were performed in accordance with current Senegalese and French legislation.
Overall, 150 rodents (59 in 2018 and 91 in 2021) were captured over 966 trap-nights, leading to an overall trapping success of 15.22%. They belonged to two species of the family Muridae, i.e., Mus musculus domesticus (147 individuals) and Arvicanthis niloticus (É. Geoffroy, 1803) (3 individuals).
Ornithodoros ticks were collected from inside rodent burrows and crevices identified in domestic and peri-domestic environments using a modified portable petrol-powered aspirator [5]. They were kept in cryotubes containing 95% ethanol for the identification of their morphological features and further molecular analyses. A total of 104 rodent burrows were examined in dwellings and peri-domestic areas. The rodent burrow infestation rate was calculated as the ratio of the number of burrows harboring ticks to the total number of burrows sampled.

2.3. Ornithodoros Tick Identification and DNA Extraction

The morphological identification of Ornithodoros ticks was carried out based on a tick identification guide [1]. Observations were carried out using an optical microscope, (Zeiss Axio Zoom V16 (Zeiss, Marly-le-Roi, France)), and a scanning electron microscope (SEM) (Hitachi High-Technologies, Tokyo, Japan).
DNA extraction was performed on a small portion of spleen and brain tissue separately for each rodent, as well as on ticks, using an EZ1 DNA tissue extraction kit (Qiagen, Hilden, Germany), and following a previously described protocol [9,14,15]. All Ornithodoros ticks were subjected to standard PCR and sequencing to confirm morphological identification using the 16S tick gene [14].

2.4. Screening for Bacteria

Bacteria screening was performed on rodent brain and spleen tissue as well as on Ornithodoros ticks using a real-time PCR (qPCR) CFX96 system (Bio-Rad, Marnes-la-Coquette, France). Bacterial detection was applied to each sample to detect the presence of bacteria such as Anaplasma, Borrelia, Bartonella, C. burnetii and Rickettsia using specific primers and probes [16]. Positive and negative controls were used in each molecular reaction as previously described [16]. Samples with a cycle threshold of (Ct) < 36 were considered positive [16,17]. The DNA of samples positive in qPCR was amplified using standard PCR, then sequenced to identify the bacterial species [16,18]. The genes used to target the presence of Anaplasmataceae and Borrelia spp. in rodents and/or O. sonrai ticks were Anaplasmataceae 23S rRNA [16] and Borrelia 16S rRNA [19]. Only the samples from rodents captured in 2018 were tested for Anaplasmataceae. Samples positive for the Anaplasmataceae 23S rRNA gene were tested with an additional PCR specific to the genus Ehrlichia groEL [20] and the Anaplasmataceae 16S rRNA gene [21], and those positive for Borrelia spp. based on 16S_Bor rRNA were subjected to qPCR for the glpQ gene, specific to B. crocidurae, as previously described [10]. Once the PCR products were amplified, electrophoretic migration was performed for each PCR reaction in a 1.5% agarose gel stained with SYBR Safe TM (Thermo Fisher Scientific, Illkirch, France) and visualized using the ultraviolet imager ChemiDoc MP (Bio-Rad, Marnes-la-Coquette, France). The PCR products were purified and sequenced using a Big Dye Terminator (Thermo Fisher Scientific, Illkirch, France) and genetic analyzer ABI PRISM 3130 (Applied Biosystems, Courtaboeuf, France) [16] with ChromasPro software, version 1.34 (Technelysium Pty, Ltd., Tewantin, QL, Australia). The sequences obtained were analyzed and assembled for comparison with sequences from the GenBank database using the BLAST tool, as described previously [9,16]. The phylogenetic analyses were established using MEGA software, version 7.0.21, with 100 bootstrap replications [22]. The accession numbers assigned by GenBank to all our sequences are listed as follows: for the Anaplasmataceae 23S rRNA gene (Anaplasma sp. (MW790939) and Ehrlichia sp. (MW790940)); for the Anaplasmataceae 16S rRNA gene (Anaplasma sp. (MW790941) and Ehrlichia sp. (MW790942)) and finally for the gene Ehrlichia groEL (Ehrlichia sp. (MW791746)).

3. Results

3.1. Sampling of Rodents and Ornithodoros Ticks

A significant difference in the relative abundance of invasive house mice was observed between the two capture sessions in 2018 and 2021, with trapping success values of 11.4% (59 individuals/518 trap-nights) and 20.3% (91/448), respectively (Chi-square test = 10.6175; p = 0.00112). Otherwise, an overall burrow infestation rate of 22.1% was recorded (23/104 rodent burrows were infested with O. sonrai ticks), leading to the collection of 253 specimens of ticks.

3.2. Molecular Identification of Ornithodoros Ticks and Detection of Borrelia spp. and Anaplasma spp. by Using qPCR in O. sonrai

Morphologically, all 253 ticks collected belonged to the species O. sonrai. A random selection of 18 O. sonrai tick specimens was performed for molecular confirmation. Using the tick 16S gene, we were able to amplify the DNA of 33.33% (6/18) of these ticks. These six specimens were successfully sequenced. The blast results confirmed the identity of O. sonrai, with identification percentages ranging from 98.39% to 99.75% (Table 1). Of 253 tick DNA extracts tested using qPCR, one was found positive for B. crocidurae infection, leading to a prevalence of 0.39%. This single tick found infected was collected in a rodent burrow examined inside a store where food goods are sold. The results of the qPCR and the standard PCR of Anaplasma spp. detected in O. sonrai are detailed in Table 2. All ticks studied were negative for Bartonella spp., C. burnetii and Rickettsia spp.

3.3. Detection of B. crocidurae Infection in Rodents

Among the 150 DNA samples from rodent brain and spleen tissues extracted separately and tested with qPCR, 18 Mus musculus domesticus were found to be infected with Borrelia spp., which were later confirmed to be B. crocidurae using qPCR for the B. crocidurae-specific glpQ gene, with a prevalence of 12% (18/150) and a mean Ct of 28.81 (Table 3). Then, we were able to amplify 69% (9/13) of the samples identified as positive for B. crocidurae (CP003426.1/JX292897.1) with standard PCR and sequencing (Table 3). The other 31% (4/13) of samples found positive for Borrelia spp. according to the qPCR results could not be amplified using standard PCR, which may be due to PCR inhibitors [23]. All tested individuals of A. niloticus were negative for Borrelia spp.

3.4. Detection of Anaplasma spp. in Rodents

In Mus musculus domesticus, the qPCR results revealed 10.16% (6/59) and 6.78% (4/59) positive samples for Anaplasma spp. in the spleen and brain tissue of rodents, respectively. Standard PCR and sequencing were performed for the positive samples obtained from the qPCR. Blast showed that 10% (1/10) were identified as Ehrlichia sp. (Table 4). No rodent was found to be positive for Bartonella spp., C. burnetii or Rickettsia spp.

3.5. Phylogenetic Analysis

The phylogenetic analysis based on the Anaplasmataceae 23S rRNA gene shows that our Anaplasma sp. is situated between Anaplasma platys (Dumler, Barbet, Bekker, Dasch, Palmer, Ray, Rikihisa, Rurangirwa, 2001) (M021425.1) and Anaplasma ovis (Lestoquard, 1924) (MT408585.1) (Figure 2). Using the Anaplasmataceae 16S rRNA gene, it forms a separate clade of uncultured Anaplasma sp. (MK041546.1) (Figure 3).
Concerning Ehrlichia sp., its position on the tree was identical to that of Candidatus Ehrlichia sp. (MK484067.1) (Figure 2) and uncultured Ehrlichia sp. (MK041545.1) by targeting the Anaplasmataceae 23S rRNA and Anaplasmataceae 16S rRNA genes, respectively (Figure 3). Finally, with the Ehrlichia groEL gene, a distinct line between uncultured Ehrlichia sp. (MG385128.1) and Ehrlichia ruminantium (Dumler, Barbet, Bekker, Dasch, Palmer, Ray, Rikihisa, Rurangirwa, 2001) was formed (U13638.1) (Figure 4).

4. Discussion

Our study confirms the success of Mus musculus domesticus as an invasive species in rural areas of northern Senegal [12]. In November 2016, this species represented 85% of the small rodents captured in Dodel [24], while this proportion was approximately 98% in 2018 and 2021 (this study). The difference in relative abundance observed between the two years of sampling may be indicative of an increase in the population size of the species in this locality, a hypothesis that will have to be verified by performing further sampling. This expansion of house mice in rural areas of inner Senegal at the expense of native species has been shown to be associated with gastrointestinal helminth patterns, some of which likely favor this invasive success [24].
Using molecular tools, the present results also reveal a respective prevalence of B. crocidurae infection in one O. sonrai tick and 18 Mus musculus domesticus of 0.39% (1/253) and 12% (18/150), associated with an infestation rate of rodent burrows by ticks inside dwellings of 22.1% (23/104). Interestingly, the only O. sonrai tick found to be infected was from a burrow examined inside a shopkeeper’s store that hosted this single individual. The rate of O. sonrai ticks found to be infected with B. crocidurae was quite low compared to previous epidemiological studies conducted further south in western Senegal (the localities of Niakhar and Dielmo-Ndiop, especially) [5,7]. Although the abundance of O. sonrai ticks in some Dodel dwellings was high, the average value of 22.1% of burrows occupied by ticks appears below those recorded elsewhere in Senegal, with infestation percentages of 32%, 37% and 41% in the three regions of the country [5].
In small mammals, the prevalence of Borrelia infection ranges from 1.7% to 27.8% in West Africa [7]. In regions known to be endemic to TBRF in Senegal, such as Dielmo, Dakar, Thies and Richard-Toll, the prevalence of Borrelia infection was in the range of 13.8%-50% in two species of small mammals (A. niloticus and Mus musculus domesticus) [7,25,26,27]. The house mouse, acting as a natural reservoir of Borrelia, is a strictly commensal species in Senegal [13], and its abundant presence in small rodent communities, which maintains infection rates, makes it a risk factor for TBRF transmission [7]. Our survey reveals that B. crocidurae infection was more prevalent in house mice than in O. sonrai ticks. Indeed, the rate of B. crocidurae infection in O. sonrai ticks was particularly low. One may hypothesize that the contact between reservoir hosts and vector ticks may be rare, as O. sonrai ticks are essentially endophilic, while house mice often hide in closets, stacks of items in storerooms or other hiding places rather than in burrows.
The order Rickettsiales currently includes the family Anaplasmataceae [28], which is made up of the following genera: Wolbachia, Ehrlichia, Anaplasma, Neorickettsia and Aegyptianella [9]. The Anaplasma genus comprises Gram-negative intracellular bacteria [29]. These organisms cause anaplasmoses that affect human and animal health and are often transmissible by ticks [2,16,30]. In this work, we also found a potential new species of Ehrlichia in brain and spleen tissues of house mice from northern Senegal (Table 4). This result corroborates that of Dahmana et al. [9], who detected, among several other pathogens (including B. crocidurae), a potential new Candidatus “Ehrlichia senegalensis” in splenic tissue of rodents from the same area.
In Senegal, previous studies have reported the presence of Anaplasmataceae, with a high prevalence in small rodents [31,32]. In our study, we were able to amplify two potential new species, namely Anaplasma sp. and Ehrlichia sp., in O. sonrai ticks. In the phylogenetic trees, our potential new species of Anaplasma forms a separate cluster from other Anaplasma spp. (Figure 2 and Figure 3), which means that it does not conform to any previously recognized species, thus potentially representing a new species. Concerning our amplicon of Ehrlichia sp., based on the two genes Anaplasmataceae rRNA 23S and Anaplasmataceae rRNA 16S, our sequence was 100% identical with Candidatus Ehrlichia sp. and uncultured Ehrlichia sp., respectively. The latter represents a potential new species that has not yet been described (Figure 2 and Figure 3) [9]. With the Ehrlichia groEL gene, our amplicon forms a distinct cluster on the tree that could not be attributed to already recognized species (Figure 3). The detection of Anaplasmataceae in O. sonrai could be the consequence of a bacterial engorgement in ticks following a mixed infestation. This hypothesis has already been proposed for other tick species [33,34]. The vector competence of O. sonrai to transmit Anaplasmataceae cannot yet be confirmed, but there is a risk that it could be potentially a vector of this bacterium. Further studies and experimentation are needed to better understand the epidemiological relationship between Anaplasmataceae and these soft ticks.

5. Conclusions

This study contributes to the identification of an expanded repertoire of zoonotic bacteria hosted in Mus musculus domesticus house mice and O. sonrai ticks in northern Senegal. Ornithodoros sonrai ticks may be a potential vector of Anaplasmataceae. Further in-depth investigation and experimentation should be conducted to understand the potential epidemiological role of these ticks and their impact on human and animal health.

Author Contributions

P.P., G.D., M.S., L.G. and J.L.F. developed the research; G.D., M.S. and J.L.F. collected the samples; B.O. carried out the scientific experiments; B.O., E.H.I.N., A.Z.D., J.M.B. and C.S. analysed data; B.O. wrote the manuscript; P.P. supervised the research. All authors have read and agreed to the published version of the manuscript.

Funding

The field surveys for this study were carried out with funding from the UMR CBGP (Centre de Biologie pour la Gestion des Populations) and the ObsMiCE (West African Observatory of Small Mammals Indicators of Environmental Change) network from UMRs LPED and CBGP. The analyses using PCR standard and qPCR kits were supported by the Institut Hospitalo-Universitaire (IHU) Méditerranée Infection, the French National Research Agency under the “Investissements d’avenir” program, reference ANR-10-IAHU-03, the Provence-Alpes-Côte-d’Azur region and European regional development funding of platforms research and innovation mutualized Mediterranean Infection (FERDF PRIMMI).

Data Availability Statement

Summary data on small mammals can be publicly accessed via http://BPM-CBGP.science (accessed on 11 October 2022).

Acknowledgments

The authors wish to thank M. Kane and Y. Niang for their help in the field survey and the rodent autopsies. We are grateful to the kind population of Dodel for accepting the collection of samples in their homes as well as to the authorities of this municipality for having facilitated the field survey.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Walker, A.R. Ticks of Domestic Animals in Africa: A Guide to Identification of Species; Bioscience Reports; Edinburgh: Scotland, UK, 2003; ISBN 0-9545173-0-X. [Google Scholar]
  2. Kernif, T.; Leulmi, H.; Raoult, D.; Parola, P. Emerging Tick-borne Bacterial Pathogens. Emerg. Infect. 2016, 10, 295–310. [Google Scholar]
  3. de la Fuente, J.; Estrada-Pena, A.; Venzal, J.M.; Kocan, K.M.; Sonenshine, D.E. Overview: Ticks as Vectors of Pathogens That Cause Disease in Humans and Animals. Front Biosci. 2008, 13, 6938–6946. [Google Scholar] [CrossRef] [Green Version]
  4. Elbir, H.; Raoult, D.; Drancourt, M. Relapsing Fever Borreliae in Africa. Am. J. Trop Med. Hyg. 2013, 89, 288–292. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  5. Trape, J.-F.; Diatta, G.; Arnathau, C.; Bitam, I.; Sarih, M.; Belghyti, D.; Bouattour, A.; Elguero, E.; Vial, L.; Mane, Y. The Epidemiology and Geographic Distribution of Relapsing Fever Borreliosis in West and North Africa, with a Review of the Ornithodoros Erraticus Complex (Acari: Ixodida). PLoS ONE 2013, 8, e78473. [Google Scholar] [CrossRef] [Green Version]
  6. Rodino, K.G.; Theel, E.S.; Pritt, B.S. Tick-Borne Diseases in the United States. Clin. Chem. 2020, 66, 537–548. [Google Scholar] [CrossRef]
  7. Diatta, G.; Duplantier, J.-M.; Granjon, L.; Bâ, K.; Chauvancy, G.; Ndiaye, M.; Trape, J.-F. Borrelia Infection in Small Mammals in West Africa and Its Relationship with Tick Occurrence inside Burrows. Acta Trop. 2015, 152, 131–140. [Google Scholar] [CrossRef]
  8. Ndiaye, E.H.I.; Diouf, F.S.; Ndiaye, M.; Bassene, H.; Raoult, D.; Sokhna, C.; Parola, P.; Diatta, G. Tick-Borne Relapsing Fever Borreliosis, a Major Public Health Problem Overlooked in Senegal. PLoS Negl. Trop. Dis. 2021, 15, e0009184. [Google Scholar] [CrossRef]
  9. Dahmana, H.; Granjon, L.; Diagne, C.; Davoust, B.; Fenollar, F.; Mediannikov, O. Rodents as Hosts of Pathogens and Related Zoonotic Disease Risk. Pathogens 2020, 9, 202. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  10. Cutler, S.J.; Abdissa, A.; Trape, J.-F. New Concepts for the Old Challenge of African Relapsing Fever Borreliosis. Clin. Microbiol. Infect. 2009, 15, 400–406. [Google Scholar] [CrossRef] [Green Version]
  11. Mediannikov, O.; Fenollar, F.; Socolovschi, C.; Diatta, G.; Bassene, H.; Molez, J.-F.; Sokhna, C.; Trape, J.-F.; Raoult, D. Coxiella burnetii in Humans and Ticks in Rural Senegal. PLoS Negl. Trop. Dis. 2010, 4, e654. [Google Scholar] [CrossRef] [Green Version]
  12. Dalecky, A.; Bâ, K.; Piry, S.; Lippens, C.; Diagne, C.A.; Kane, M.; Sow, A.; Diallo, M.; Niang, Y.; Konečný, A. Range Expansion of the Invasive House Mouse Mus musculus domesticus in Senegal, W Est A Frica: A Synthesis of Trapping Data over Three Decades, 1983–2014. Mammal Rev. 2015, 45, 176–190. [Google Scholar] [CrossRef]
  13. Granjon, L.; Duplantier, J.-M. Les Rongeurs de l’Afrique Sahélo-Soudanienne; IRD: Marseille, French, 2009; ISBN 2-85653-646-8. [Google Scholar]
  14. Diarra, A.Z.; Kone, A.K.; Niare, S.D.; Laroche, M.; Diatta, G.; Atteynine, S.A.; Coulibaly, M.; Sangare, A.K.; Kouriba, B.; Djimde, A. Molecular Detection of Microorganisms Associated with Small Mammals and Their Ectoparasites in Mali. Am. J. Trop. Med. Hyg. 2020, 103, 2542–2551. [Google Scholar] [CrossRef] [PubMed]
  15. Boucheikhchoukh, M.; Laroche, M.; Aouadi, A.; Dib, L.; Benakhla, A.; Raoult, D.; Parola, P. MALDI-TOF MS Identification of Ticks of Domestic and Wild Animals in Algeria and Molecular Detection of Associated Microorganisms. Comp. Immunol. Microbiol. Infect. Dis. 2018, 57, 39–49. [Google Scholar] [CrossRef]
  16. Ouarti, B.; Mediannikov, O.; Righi, S.; Benakhla, A.; Raoult, D.; Parola, P. Molecular Detection of Microorganisms in Lice Collected from Farm Animals in Northeastern Algeria. Comp. Immunol. Microbiol. Infect. Dis. 2020, 74, 101569. [Google Scholar] [CrossRef] [PubMed]
  17. Gautret, P.; Lagier, J.-C.; Parola, P.; Meddeb, L.; Sevestre, J.; Mailhe, M.; Doudier, B.; Aubry, C.; Amrane, S.; Seng, P. Clinical and Microbiological Effect of a Combination of Hydroxychloroquine and Azithromycin in 80 COVID-19 Patients with at Least a Six-Day Follow up: A Pilot Observational Study. Travel. Med. Infect. Dis. 2020, 34, 101663. [Google Scholar] [CrossRef] [PubMed]
  18. Diarra, A.Z.; Almeras, L.; Laroche, M.; Berenger, J.-M.; Koné, A.K.; Bocoum, Z.; Dabo, A.; Doumbo, O.; Raoult, D.; Parola, P. Molecular and MALDI-TOF Identification of Ticks and Tick-Associated Bacteria in Mali. PLoS Negl. Trop. Dis. 2017, 11, e0005762. [Google Scholar] [CrossRef]
  19. Sadeddine, R.; Diarra, A.Z.; Laroche, M.; Mediannikov, O.; Righi, S.; Benakhla, A.; Dahmana, H.; Raoult, D.; Parola, P. Molecular Identification of Protozoal and Bacterial Organisms in Domestic Animals and Their Infesting Ticks from North-Eastern Algeria. Ticks Tick-Borne Dis. 2020, 11, 101330. [Google Scholar] [CrossRef]
  20. Dahmani, M.; Davoust, B.; Rousseau, F.; Raoult, D.; Fenollar, F.; Mediannikov, O. Natural Anaplasmataceae Infection in Rhipicephalus bursa Ticks Collected from Sheep in the French Basque Country. Ticks Tick-Borne Dis. 2017, 8, 18–24. [Google Scholar] [CrossRef]
  21. Parola, P.; Roux, V.; Camicas, J.-L.; Baradji, I.; Brouqui, P.; Raoult, D. Detection of Ehrlichiae in African Ticks by Polymerase Chain Reaction. Trans. R. Soc. Trop. Med. Hyg. 2000, 94, 707–708. [Google Scholar] [CrossRef]
  22. Kumar, S.; Stecher, G.; Tamura, K. MEGA7: Molecular Evolutionary Genetics Analysis Version 7.0 for Bigger Datasets. Mol. Biol. Evol. 2016, 33, 1870–1874. [Google Scholar] [CrossRef] [Green Version]
  23. Bessetti, J. An Introduction to PCR Inhibitors. J. Microbiol. Methods 2007, 28, 159–167. [Google Scholar]
  24. Diagne, C.; Granjon, L.; Tatard, C.; Ribas, A.; Ndiaye, A.; Kane, M.; Niang, Y.; Brouat, C. Same Invasion, Different Routes: Helminth Assemblages May Favor the Invasion Success of the House Mouse in Senegal. Front. Vet. Sci. 2021, 8, 740617. [Google Scholar] [CrossRef] [PubMed]
  25. Trape, J.-F.; Godeluck, B.; Diatta, G.; Rogier, C.; Legros, F.; Albergel, J.; Pepin, Y.; Duplantier, J.-M. The Spread of Tick-Borne Borreliosis in West Africa and Its Relationship to Sub-Saharan Drought. Am. J. Trop Med. Hyg. 1996, 54, 289–293. [Google Scholar] [CrossRef] [Green Version]
  26. Godeluck, B.; Duplantier, J.-M.; Ba, K.; Trape, J.-F. A Longitudinal Survey of Borrelia crocidurae Prevalence in Rodents and Insectivores in Senegal. Am. J. Trop Med. Hyg. 1994, 50, 165–168. [Google Scholar] [CrossRef]
  27. Vial, L.; Diatta, G.; Tall, A.; Bouganali, H.; Durand, P.; Sokhna, C.; Rogier, C.; Renaud, F.; Trape, J.-F. Incidence of Tick-Borne Relapsing Fever in West Africa: Longitudinal Study. Lancet 2006, 368, 37–43. [Google Scholar] [CrossRef]
  28. Parola, P.; Paddock, C.D.; Socolovschi, C.; Labruna, M.B.; Mediannikov, O.; Kernif, T.; Abdad, M.Y.; Stenos, J.; Bitam, I.; Fournier, P.-E. Update on Tick-Borne Rickettsioses around the World: A Geographic Approach. Clin. Microbiol. Rev. 2013, 26, 657–702. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  29. Said, M.B.; Belkahia, H.; Messadi, L. Anaplasma Spp. in North Africa: A Review on Molecular Epidemiology, Associated Risk Factors and Genetic Characteristics. Ticks. Tick-Borne Dis. 2018, 9, 543–555. [Google Scholar] [CrossRef] [PubMed]
  30. Dahmani, M.; Davoust, B.; Benterki, M.S.; Fenollar, F.; Raoult, D.; Mediannikov, O. Development of a New PCR-Based Assay to Detect Anaplasmataceae and the First Report of Anaplasma phagocytophilum and Anaplasma platys in Cattle from Algeria. Comp. Immunol. Microbiol. Infect. Dis. 2015, 39, 39–45. [Google Scholar] [CrossRef] [PubMed]
  31. Meerburg, B.G.; Singleton, G.R.; Kijlstra, A. Rodent-Borne Diseases and Their Risks for Public Health. Crit. Rev. Microbiol. 2009, 35, 221–270. [Google Scholar]
  32. Diagne, C.; Galan, M.; Tamisier, L.; d’Ambrosio, J.; Dalecky, A.; Bâ, K.; Kane, M.; Niang, Y.; Diallo, M.; Sow, A. Ecological and Sanitary Impacts of Bacterial Communities Associated to Biological Invasions in African Commensal Rodent Communities. Communities. Sci. Rep. 2017, 7, 14995. [Google Scholar] [CrossRef] [Green Version]
  33. Ehounoud, C.B.; Yao, K.P.; Dahmani, M.; Achi, Y.L.; Amanzougaghene, N.; Kacou N’Douba, A.; N’Guessan, J.D.; Raoult, D.; Fenollar, F.; Mediannikov, O. Multiple Pathogens Including Potential New Species in Tick Vectors in Côte d’Ivoire. PLoS Negl. Trop. Dis. 2016, 10, e0004367. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  34. Brown, L.D.; Christofferson, R.C.; Banajee, K.H.; Del Piero, F.; Foil, L.D.; Macaluso, K.R. Cofeeding Intra-and Interspecific Transmission of an Emerging Insect-borne Rickettsial Pathogen. Mol. Ecol. 2015, 24, 5475–5489. [Google Scholar] [CrossRef] [PubMed]
Figure 1. Location of the Dodel commune in the Saint-Louis region in Senegal.
Figure 1. Location of the Dodel commune in the Saint-Louis region in Senegal.
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Figure 2. Anaplasmataceae maximum-likelihood phylogenetic tree targeting the partial 513-bp 23S gene.
Figure 2. Anaplasmataceae maximum-likelihood phylogenetic tree targeting the partial 513-bp 23S gene.
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Figure 3. Anaplasmataceae maximum-likelihood phylogenetic tree targeting the partial 345 bp 16S gene.
Figure 3. Anaplasmataceae maximum-likelihood phylogenetic tree targeting the partial 345 bp 16S gene.
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Figure 4. Ehrlichia spp. maximum-likelihood phylogenetic tree targeting the partial 633-bp groEL gene.
Figure 4. Ehrlichia spp. maximum-likelihood phylogenetic tree targeting the partial 633-bp groEL gene.
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Table 1. Blast analysis results for molecular identification of Ornithodoros sonrai ticks collected in Dodel, Senegal.
Table 1. Blast analysis results for molecular identification of Ornithodoros sonrai ticks collected in Dodel, Senegal.
Individual Samples of Ornithodoros TicksPCR Standard 16S of
O. sonrai Ticks
CoverPer. IdentAccession Number
of the Reference Sequences
Identification
Ornithodoros sonrai(+)99%99.75%KP644213.1O. sonrai
O. sonrai(+)99%99.75%KP644213.1O. sonrai
O. sonrai(+)100%98.87%KP644213.1O. sonrai
O. sonrai(+)95%99.30%KP644213.1O. sonrai
O. sonrai(+)95%98.39%KP644213.1O. sonrai
O. sonrai(+)95%99.53%KP644213.1O. sonrai
Total6/6///O. sonrai
Table 2. Results of qPCR, standard PCR and BLAST from O. sonrai tested by targeting primers Anaplasma spp. 23S rRNA, Anaplasmataceae 16S rRNA and Ehrlichia groEL.
Table 2. Results of qPCR, standard PCR and BLAST from O. sonrai tested by targeting primers Anaplasma spp. 23S rRNA, Anaplasmataceae 16S rRNA and Ehrlichia groEL.
Individual Samples of
Ornithodoros Ticks
qPCR PrimerqPCR (Ct)Bacteria Detected in
O. sonrai Ticks Using qPCR
PCR Standard PrimerMolecular Identification Using BlastPercent Identity %Query Cover %Accession Number
of the Reference Sequences
Ornithodoros sonraiAnaplasmataceae 23S rRNA gene7.23Anaplasmataceae spp.Anaplasmataceae 23S rRNA geneCandidatus Ehrlichia sp.10095MK484067.1
/Anaplasmataceae spp.Anaplasmataceae 16S rRNA geneUncultured Ehrlichia sp.100100MK041545.1
/Anaplasmataceae spp.Ehrlichia groELEhrlichia sp.90.50100HQ697591.1
O. sonrai20.68Anaplasmataceae spp.Anaplasmataceae 23S rRNA geneAnaplasma ovis94.9794MT408585.1
/Anaplasmataceae spp.Anaplasmataceae 16S rRNA geneUncultured Anaplasma sp.98.77100MK041546.1
O. sonrai9.75Anaplasmataceae spp./////
O. sonrai11.12Anaplasmataceae spp./////
O. sonrai29.93Anaplasmataceae spp./////
O. sonrai14.07Anaplasmataceae spp./////
O. sonrai7.05Anaplasmataceae spp./////
O. sonrai21.78Anaplasmataceae spp./////
O. sonrai20.69Anaplasmataceae spp./////
TotalCt m = 15.81/////
Ct m = The threshold value of an average cycle.
Table 3. Results of Borrelia spp. detection in brain and spleen tissue from rodents caught in Dodel using qPCR and standard PCR.
Table 3. Results of Borrelia spp. detection in brain and spleen tissue from rodents caught in Dodel using qPCR and standard PCR.
Rodent Tissue StudiedCt (qPCR)PCR StandardCoverPer. IdentAccession Number of the Reference SequencesIdentification
Mus musculus domesticusb30.29(+)99%97.92%CP003426.1B. crocidurae
M. m. domesticusb33.55/////
M. m. domesticusb10.35/////
M. m. domesticusb23.13(+)100%99.93%CP003426.1B. crocidurae
M. m. domesticusb28(+)100%95.35%JX292897.1B. crocidurae
M. m. domesticusb28.11(+)99%98.95%CP003426.1B. crocidurae
M. m. domesticusb27.16(+)99%98.63CP003426.1B. crocidurae
M. m. domesticusb27.96(+)100%99.41%CP003426.1B. crocidurae
M. m. domesticusb29.28(+)99%98.44%CP003426.1B. crocidurae
M. m. domesticusb24.74(+)99%99.40%CP003426.1B. crocidurae
M. m. domesticuss35.81/////
M. m. domesticuss36.34/////
M. m. domesticuss30.14(+)96%99,85%CP003426.1B. crocidurae
M. m. domesticusb33.47 // /
M. m. domesticusb29.63 ////
M. m. domesticusb24.81 ////
M. m. domesticusb32.19 ////
M. m. domesticusb33.72 ////
Total 28.8169% (9/13)////
b = brain tissue; s = spleen tissue.
Table 4. Results of Anaplasma spp. detection in brain and spleen tissue from mice caught in Dodel using qPCR and standard PCR.
Table 4. Results of Anaplasma spp. detection in brain and spleen tissue from mice caught in Dodel using qPCR and standard PCR.
Small Rodent Tissue Studied Ct (qPCR)PCR StandardCoverPer. IdentAccession NumberIdentification
M. m. domesticuss25.47/////
M. m. domesticus26.13/////
M. m. domesticub29.21/////
M. m. domesticus17.95/////
M. m. domesticusb20.18/////
M. m. domesticuss24.78/////
M. m. domesticuss22.49(+)92%100MK484067.1Candidatus Ehrlichia sp.
M. m. domesticuss27.57/////
M. m. domesticusb18.42/////
M. m. domesticusb20.45/////
Total 23.2610% (1/10)////
b = brain tissue; s = spleen tissue.
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Ouarti, B.; Sall, M.; Ndiaye, E.H.I.; Diatta, G.; Zan Diarra, A.; Berenger, J.M.; Sokhna, C.; Granjon, L.; Le Fur, J.; Parola, P. Pathogen Detection in Ornithodoros sonrai Ticks and Invasive House Mice Mus musculus domesticus in Senegal. Microorganisms 2022, 10, 2367. https://doi.org/10.3390/microorganisms10122367

AMA Style

Ouarti B, Sall M, Ndiaye EHI, Diatta G, Zan Diarra A, Berenger JM, Sokhna C, Granjon L, Le Fur J, Parola P. Pathogen Detection in Ornithodoros sonrai Ticks and Invasive House Mice Mus musculus domesticus in Senegal. Microorganisms. 2022; 10(12):2367. https://doi.org/10.3390/microorganisms10122367

Chicago/Turabian Style

Ouarti, Basma, Moussa Sall, El Hadji Ibrahima Ndiaye, Georges Diatta, Adama Zan Diarra, Jean Michel Berenger, Cheikh Sokhna, Laurent Granjon, Jean Le Fur, and Philippe Parola. 2022. "Pathogen Detection in Ornithodoros sonrai Ticks and Invasive House Mice Mus musculus domesticus in Senegal" Microorganisms 10, no. 12: 2367. https://doi.org/10.3390/microorganisms10122367

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