Hostname: page-component-586b7cd67f-r5fsc Total loading time: 0 Render date: 2024-11-23T22:42:28.027Z Has data issue: false hasContentIssue false

Impact of endosymbionts on tick physiology and fitness

Published online by Cambridge University Press:  24 August 2023

Agatha O. Kolo*
Affiliation:
Department of Molecular Microbiology and Immunology, The University of Texas at San Antonio, San Antonio, TX, USA
Rahul Raghavan
Affiliation:
Department of Molecular Microbiology and Immunology, The University of Texas at San Antonio, San Antonio, TX, USA
*
Corresponding author: Agatha O. Kolo; Email: [email protected]

Abstract

Ticks transmit pathogens and harbour non-pathogenic, vertically transmitted intracellular bacteria termed endosymbionts. Almost all ticks studied to date contain 1 or more of Coxiella, Francisella, Rickettsia or Candidatus Midichloria mitochondrii endosymbionts, indicative of their importance to tick physiology. Genomic and experimental data suggest that endosymbionts promote tick development and reproductive success. Here, we review the limited information currently available on the potential roles endosymbionts play in enhancing tick metabolism and fitness. Future studies that expand on these findings are needed to better understand endosymbionts’ contributions to tick biology. This knowledge could potentially be applied to design novel strategies that target endosymbiont function to control the spread of ticks and pathogens they vector.

Type
Review Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press

Introduction

Ticks are haematophagous ectoparasites of vertebrate animals worldwide. There are 2 main tick families Ixodidae (hard ticks), which possesses a sclerotized hard shield called scutum, and Argasidae (soft ticks), which lacks scutum (Anderson and Magnarelli, Reference Anderson and Magnarelli2008). Both types of ticks are found worldwide, but the presence of a specific tick species in a given location is dependent on factors such as temperature, humidity, vegetation, altitude and the availability of reservoir hosts (Jongejan and Uilenberg, Reference Jongejan and Uilenberg2004; Estrada-Pena et al., Reference Estrada-Pena, Ayllon and De La Fuente2012). Ticks have significant impacts on human and animal health because they transmit pathogens that cause Lyme disease, anaplasmosis, babesiosis, ehrlichiosis, theileriosis, tick-borne encephalitis, Rocky Mountain spotted fever and many other diseases (Jongejan and Uilenberg, Reference Jongejan and Uilenberg2004; Piesman and Eisen, Reference Piesman and Eisen2008; Petersen et al., Reference Petersen, Mead and Schriefer2009; Dantas-Torres et al., Reference Dantas-Torres, Chomel and Otranto2012; Sonenshine, Reference Sonenshine2018). Additionally, tick infestations cause considerable blood loss, allergic reactions and tick paralysis that could be fatal (Sonenshine and Roe, Reference Sonenshine and Roe2014). Tick control is generally based on the use of chemical acaricides; however, the frequent and incorrect use of acaricides has resulted in acaricide-resistant ticks and contamination of animal products and the environment (Jongejan and Uilenberg, Reference Jongejan and Uilenberg2004; Obaid et al., Reference Obaid, Islam, Alouffi, Khan, da Silva Vaz, Tanaka and Ali2022; Johnson, Reference Johnson and Johnson2023). As an alternative, an integrated approach that involves the use of tick vaccines, administration of synthetic and plant-based acaricides to animals and the continuous surveillance and management of drug resistance in tick and host populations has been advocated (de La Fuente et al., Reference de La Fuente, Kocan and Contreras2015).

Another potential approach to tick control is the use of ‘anti-microbiota vaccines’ that disrupt the functions of bacteria that enhance tick physiology and fitness (Mateos-Hernández et al., Reference Mateos-Hernández, Obregón, Maye, Borneres, Versille, de la Fuente, Estrada-Peña, Hodžić, Šimo and Cabezas-Cruz2020, Reference Mateos-Hernández, Obregón, Wu-Chuang, Maye, Bornères, Versillé, de la Fuente, Díaz-Sánchez, Bermúdez-Humarán, Torres-Maravilla, Estrada-Peña, Hodžić, Šimo and Cabezas-Cruz2021). Unlike extracellular bacteria found transiently on tick surfaces or midgut, a few lineages of intracellular bacteria have established long-term relationships with ticks. Loss of these so-called endosymbionts reduced tick reproductive success, indicating the potential to target them to control the spread of ticks. For this approach to be successful, a clear understanding of how bacteria promote critical processes in ticks is necessary. With this aim in mind, here we review currently available information that supports beneficial roles for tick endosymbionts.

Intracellular pathogens, reproductive parasites and endosymbionts in ticks

The advent of high-throughput sequencing has revealed a vast array of intracellular bacteria that associate with ticks (Andreotti et al., Reference Andreotti, Pérez de León, Dowd, Guerrero, Bendele and Scoles2011; Carpi et al., Reference Carpi, Cagnacci, Wittekindt, Zhao, Qi, Tomsho, Drautz, Rizzoli and Schuster2011; Qiu et al., Reference Qiu, Nakao, Ohnuma, Kawamori and Sugimoto2014; Narasimhan and Fikrig, Reference Narasimhan and Fikrig2015). In addition to pathogens such as Anaplasma spp., Ehrlichia spp., Rickettsia spp., Francisella tularensis and Coxiella burnetii (Potgieter and Stoltsz, Reference Potgieter, Stoltsz, Coetzer and Tustin1994; Parola and Raoult, Reference Parola and Raoult2001; Bown et al., Reference Bown, Begon, Bennett, Woldehiwet and Ogden2003; Jongejan and Uilenberg, Reference Jongejan and Uilenberg2004; Parola et al., Reference Parola, Paddock and Raoult2005; de la Fuente et al., Reference de la Fuente, Estrada-Pena, Venzal, Kocan and Sonenshine2008; Dantas-Torres et al., Reference Dantas-Torres, Chomel and Otranto2012; Kamani et al., Reference Kamani, Morick, Mumcuoglu and Harrus2013; Latrofa et al., Reference Latrofa, Dantas-Torres, Giannelli and Otranto2014; Ereqat et al., Reference Ereqat, Nasereddin, Vayssier-Taussat, Abdelkader, Al-Jawabreh, Zaid, Azmi and Abdeen2016; Regier et al., Reference Regier, Ballhorn and Kempf2017), ticks occasionally contain bacteria that are assumed to be reproductive parasites (Ahantarig et al., Reference Ahantarig, Trinachartvanit, Baimai and Grubhoffer2013; Narasimhan and Fikrig, Reference Narasimhan and Fikrig2015; Bonnet et al., Reference Bonnet, Binetruy, Hernández-Jarguín and Duron2017; Duron et al., Reference Duron, Binetruy, Noël, Cremaschi, McCoy, Arnathau, Plantard, Goolsby, Pérez de León and Heylen2017). For instance, Wolbachia spp. that are closely related to those that manipulate insect reproduction have been detected in Ixodes and Rhipicephalus (Benson et al., Reference Benson, Gawronski, Eveleigh and Benson2004; Zhang et al., Reference Zhang, Norris and Rasgon2011; Hirunkanokpun et al., Reference Hirunkanokpun, Ahantarig, Baimai and Trinachartvanit2018; Chao et al., Reference Chao, Castillo and Shih2021). However, the impact Wolbachia have on tick reproduction is unknown and requires further investigation. In fact, detection of Wolbachia in I. ricinus has been linked to the presence of an endoparasitoid wasp, suggesting that ticks may not be natural hosts of Wolbachia (Plantard et al., Reference Plantard, Bouju-Albert, Malard, Hermouet, Capron and Verheyden2012; Lejal et al., Reference Lejal, Chiquet, Aubert, Robin, Estrada-Peña, Rue, Midoux, Mariadassou, Bailly, Cougoul, Gasqui, Cosson, Chalvet-Monfray, Vayssier-Taussat and Pollet2021).

Another suspected reproductive parasite present in ticks is Rickettsiella spp., which is prevalent in Ixodes and Ornithodoros ticks and is thought to cause sex ratio distortions in parthenogenetic Ixodes woodi (Kurtti et al., Reference Kurtti, Palmer and Oliver2002; Carpi et al., Reference Carpi, Cagnacci, Wittekindt, Zhao, Qi, Tomsho, Drautz, Rizzoli and Schuster2011; Leclerque and Kleespies, Reference Leclerque and Kleespies2012; Anstead and Chilton, Reference Anstead and Chilton2014; Duron et al., Reference Duron, Noël, Mccoy, Bonazzi, Sidi-Boumedine, Morel, Vavre, Zenner, Jourdain and Durand2015, Reference Duron, Binetruy, Noël, Cremaschi, McCoy, Arnathau, Plantard, Goolsby, Pérez de León and Heylen2017; Bonnet et al., Reference Bonnet, Binetruy, Hernández-Jarguín and Duron2017). Other tick-associated intracellular bacteria include Arsenophonus sp. that may decrease the questing success of Dermacentor variabilis and Amblyomma americanum ticks, and Spiroplasma ixodetis, Cardinium spp. and Lariskella spp. with unknown functions (Kurtti et al., Reference Kurtti, Munderloh, Andreadis, Magnarelli and Mather1996; Grindle et al., Reference Grindle, Tyner, Clay and Fuqua2003; Benson et al., Reference Benson, Gawronski, Eveleigh and Benson2004; Henning et al., Reference Henning, Greiner-Fischer, Hotzel, Ebsen and Theegarten2006; Clay et al., Reference Clay, Klyachko, Grindle, Civitello, Oleske and Fuqua2008; Dergousoff and Chilton, Reference Dergousoff and Chilton2010; Mediannikov et al., Reference Mediannikov, Subramanian, Sekeyova, Bell-Sakyi and Raoult2012; Kagemann and Clay, Reference Kagemann and Clay2013; Qiu et al., Reference Qiu, Nakao, Ohnuma, Kawamori and Sugimoto2014; Bell-Sakyi et al., Reference Bell-Sakyi, Palomar and Kazimirova2015; Duron et al., Reference Duron, Binetruy, Noël, Cremaschi, McCoy, Arnathau, Plantard, Goolsby, Pérez de León and Heylen2017; Aivelo et al., Reference Aivelo, Norberg and Tschirren2019).

Ticks also harbour intracellular bacteria that are thought to improve tick fitness. These ‘endosymbionts’ include Coxiella endosymbionts (CEs), Francisella endosymbionts (FEs), Rickettsia endosymbionts (REs) and Candidatus Midichloria mitochondrii (CMM) (Noda et al., Reference Noda, Munderloh and Kurtti1997; Sun et al., Reference Sun, Scoles, Fish and O'Neill2000; Sassera et al., Reference Sassera, Beninati, Bandi, Bouman, Sacchi, Fabbi and Lo2006; Clay et al., Reference Clay, Klyachko, Grindle, Civitello, Oleske and Fuqua2008). CEs are found in a variety of hard and soft ticks and are the most common endosymbionts identified in ticks worldwide (Andreotti et al., Reference Andreotti, Pérez de León, Dowd, Guerrero, Bendele and Scoles2011; Lalzar et al., Reference Lalzar, Harrus, Mumcuoglu and Gottlieb2012; Qiu et al., Reference Qiu, Nakao, Ohnuma, Kawamori and Sugimoto2014; Duron et al., Reference Duron, Binetruy, Noël, Cremaschi, McCoy, Arnathau, Plantard, Goolsby, Pérez de León and Heylen2017), FEs are present in soft ticks (e.g. Ornithodoros moubata, O. porcinus porcinus) and hard ticks (e.g. Dermacentor sp., Amblyomma sp.) (Noda et al., Reference Noda, Munderloh and Kurtti1997; Sun et al., Reference Sun, Scoles, Fish and O'Neill2000; Gerhart et al., Reference Gerhart, Moses and Raghavan2016, Reference Gerhart, Auguste Dutcher, Brenner, Moses, Grubhoffer and Raghavan2018; Duron et al., Reference Duron, Binetruy, Noël, Cremaschi, McCoy, Arnathau, Plantard, Goolsby, Pérez de León and Heylen2017) and REs are present in hard ticks of the genera Ixodes, Dermacentor, Amblyomma, Haemaphysalis and Rhipicephalus (Clay et al., Reference Clay, Klyachko, Grindle, Civitello, Oleske and Fuqua2008; Ahantarig et al., Reference Ahantarig, Malaisri, Hirunkanokpun, Sumrandee, Trinachartvanit and Baimai2011; Carpi et al., Reference Carpi, Cagnacci, Wittekindt, Zhao, Qi, Tomsho, Drautz, Rizzoli and Schuster2011; Lalzar et al., Reference Lalzar, Harrus, Mumcuoglu and Gottlieb2012; Duron et al., Reference Duron, Binetruy, Noël, Cremaschi, McCoy, Arnathau, Plantard, Goolsby, Pérez de León and Heylen2017; Gall et al., Reference Gall, Scoles, Magori, Mason and Brayton2017). CMM, which replicates within host mitochondria, was first detected in I. ricinus, but recent reports indicate its presence in other tick species as well (Lewis, Reference Lewis1979; Zhu et al., Reference Zhu, Aeschlimann and Gern1992; Sacchi et al., Reference Sacchi, Bigliardi, Corona, Beninati, Lo and Franceschi2004; Epis et al., Reference Epis, Sassera, Beninati, Lo, Beati, Piesman, Rinaldi, McCoy, Torina, Sacchi, Clementi, Genchi, Magnino and Bandi2008; Duron et al., Reference Duron, Binetruy, Noël, Cremaschi, McCoy, Arnathau, Plantard, Goolsby, Pérez de León and Heylen2017). All ticks studied to date contain 1 or more of CE, FE, RE or CMM, suggestive of their importance to tick biology. Data currently available from genomic and experimental studies that support endosymbiont function are discussed below.

Genomic evidence for endosymbiont function

Genomes of bacteria that form long-term associations with eukaryotic hosts tend to lose genes that are not under selection while retaining genes that benefit the bacterium or host (McCutcheon and Moran, Reference McCutcheon and Moran2012; Bennett and Moran, Reference Bennett and Moran2015; McCutcheon et al., Reference McCutcheon, Boyd and Dale2019). Befitting this pattern, tick endosymbionts have degraded genomes with intact pathways for the production of B vitamins, suggesting a role for endosymbionts in provisioning these essential nutrients to ticks (Hunter et al., Reference Hunter, Torkelson, Bodnar, Mortazavi, Laurent, Deason, Thephavongsa and Zhong2015; Smith et al., Reference Smith, Driscoll, Gillespie and Raghavan2015; Gerhart et al., Reference Gerhart, Moses and Raghavan2016, Reference Gerhart, Auguste Dutcher, Brenner, Moses, Grubhoffer and Raghavan2018; Guizzo et al., Reference Guizzo, Parizi, Nunes, Schama, Albano, Tirloni, Oldiges, Vieira, Oliveira, Leite, Gonzales, Farber, Martins, Vaz and Oliveira2017; Tsementzi et al., Reference Tsementzi, Castro Gordillo, Mahagna, Gottlieb and Konstantinidis2018; Olivieri et al., Reference Olivieri, Epis, Castelli, Varotto Boccazzi, Romeo, Desirò, Bazzocchi, Bandi and Sassera2019; Buysse et al., Reference Buysse, Floriano, Gottlieb, Nardi, Comandatore, Olivieri, Giannetto, Palomar, Makepeace, Bazzocchi, Cafiso, Sassera and Duron2021b) (Fig. 1). Reconstruction of the vitamin biosynthesis pathway of CEs in the ixodid tick A. americanum (CLEAA) and the argasid tick O. amblus (CLEOA) revealed that they have complete pathways to produce thiamine (vitamin B1), riboflavin (vitamin B2), niacin (vitamin B3), biotin (vitamin B7) and folate (vitamin B9) (Smith et al., Reference Smith, Driscoll, Gillespie and Raghavan2015; Duron and Gottlieb, Reference Duron and Gottlieb2020). CLEAA also has partial pathways for the synthesis of pantothenic acid (vitamin B5) and pyridoxine (vitamin B6) (Smith et al., Reference Smith, Driscoll, Gillespie and Raghavan2015). The genomes of the CEs in R. turanicus (CRt) and A. sculptum (CeAS-UFV) have complete pathways to synthesize riboflavin, biotin and folate and partial pathways for niacin, pantothenic acid and pyridoxine (Gottlieb et al., Reference Gottlieb, Lalzar and Klasson2015; Duron and Gottlieb, Reference Duron and Gottlieb2020). The genome of CeAS-UFV also possesses a partial pathway for the synthesis of thiamine (Duron and Gottlieb, Reference Duron and Gottlieb2020), and the CE in R. microplus (CERM) has complete pathways for the synthesis of riboflavin, pyridoxine, biotin and folate and a partial pathway for the synthesis of thiamine (Gottlieb et al., Reference Gottlieb, Lalzar and Klasson2015; Smith et al., Reference Smith, Driscoll, Gillespie and Raghavan2015; Guizzo et al., Reference Guizzo, Parizi, Nunes, Schama, Albano, Tirloni, Oldiges, Vieira, Oliveira, Leite, Gonzales, Farber, Martins, Vaz and Oliveira2017).

Figure 1. B vitamin biosynthesis pathways in tick endosymbionts. Pathway for the synthesis of cobalamin (vitamin B12) was not detected in any tick endosymbiont genome. CE, Coxiella endosymbiont; FE, Francisella endosymbiont; CMM, Candidatus Midichloria mitochondrii.

Similar to CEs, analysis of the genomes of the FEs in O. moubata (FLE-Om), A. maculatum (FLE-Am) and F. persica, the endosymbiont of the soft tick Argas arboreus, showed that they possess complete pathways for the synthesis of riboflavin, biotin and folate (Gerhart et al., Reference Gerhart, Auguste Dutcher, Brenner, Moses, Grubhoffer and Raghavan2018; Duron and Gottlieb, Reference Duron and Gottlieb2020) (Fig. 1). Furthermore, FLE-Am and FLE-Om may be able to utilize aspartate to synthesize pantothenic acid (vitamin B5) but F. persica seems to only possess a partial pathway for this process (Gerhart et al., Reference Gerhart, Auguste Dutcher, Brenner, Moses, Grubhoffer and Raghavan2018). In the case of Rickettsia symbionts, metabolic reconstruction suggests that R. buchneri in I. scapularis and Rickettsia sp. phylotype G021 in I. pacificus are likely able to synthesize folate but no other B vitamins (Hunter et al., Reference Hunter, Torkelson, Bodnar, Mortazavi, Laurent, Deason, Thephavongsa and Zhong2015; Bodnar et al., Reference Bodnar, Fitch, Rosati and Zhong2018). For CMM, metabolic reconstructions showed that genomes encode complete pathways for the biosynthesis of riboflavin, biotin and folate suggesting that the intra-mitochondrial symbiont could also provide B vitamins to its tick partner (Sassera et al., Reference Sassera, Lo, Epis, D'Auria, Montagna, Comandatore, Horner, Peretó, Luciano, Franciosi, Ferri, Crotti, Bazzocchi, Daffonchio, Sacchi, Moya, Latorre and Bandi2011; Olivieri et al., Reference Olivieri, Epis, Castelli, Varotto Boccazzi, Romeo, Desirò, Bazzocchi, Bandi and Sassera2019).

Many cofactors and coenzymes that are critical to the functioning of essential enzymes are derived from B vitamins (Douglas, Reference Douglas2017). Several CEs and FEs contain pathways for the production of cofactors and coenzymes from B vitamins (Guizzo et al., Reference Guizzo, Parizi, Nunes, Schama, Albano, Tirloni, Oldiges, Vieira, Oliveira, Leite, Gonzales, Farber, Martins, Vaz and Oliveira2017; Duron et al., Reference Duron, Morel, Noël, Buysse, Binetruy, Lancelot, Loire, Ménard, Bouchez, Vavre and Vial2018; Gerhart et al., Reference Gerhart, Auguste Dutcher, Brenner, Moses, Grubhoffer and Raghavan2018; Nardi et al., Reference Nardi, Olivieri, Kariuki, Sassera and Castelli2020; Brenner et al., Reference Brenner, Muñoz-Leal, Sachan, Labruna and Raghavan2021). For example, CERM, CLEAA and CRt could synthesize flavin mononucleotide (FMN) and flavin adenine dinucleotide (FAD) from riboflavin and coenzyme A from pantothenate (Guizzo et al., Reference Guizzo, Parizi, Nunes, Schama, Albano, Tirloni, Oldiges, Vieira, Oliveira, Leite, Gonzales, Farber, Martins, Vaz and Oliveira2017). In addition, CLEAA encodes genes for the synthesis of nicotinamide adenine dinucleotide phosphate (NADP+) and CLEAA, CLEOA and CERM possess complete pathways to produce lipoic acid (Gottlieb et al., Reference Gottlieb, Lalzar and Klasson2015; Smith et al., Reference Smith, Driscoll, Gillespie and Raghavan2015; Guizzo et al., Reference Guizzo, Parizi, Nunes, Schama, Albano, Tirloni, Oldiges, Vieira, Oliveira, Leite, Gonzales, Farber, Martins, Vaz and Oliveira2017; Duron and Gottlieb, Reference Duron and Gottlieb2020). Analysis also found that the genome of FLE-Om possessed complete pathways for the biosynthesis of lipoic acid, FAD and coenzyme A (Duron et al., Reference Duron, Morel, Noël, Buysse, Binetruy, Lancelot, Loire, Ménard, Bouchez, Vavre and Vial2018; Gerhart et al., Reference Gerhart, Auguste Dutcher, Brenner, Moses, Grubhoffer and Raghavan2018). Additional analysis of FLE-Om and F. persica genomes using tools available in the microbial genome portal BioCyc (Karp et al., Reference Karp, Billington, Caspi, Fulcher, Latendresse, Kothari, Keseler, Krummenacker, Midford, Ong, Ong, Paley and Subhraveti2017) revealed that both symbionts encode complete pathways for the biosynthesis of several other cofactors that could be useful to their tick hosts: iron-sulphur cluster [2Fe-2S], dipyrromethane, FMN, heme, molybdopterin, nicotinamide adenine dinucleotide (NAD+), NADP+, pyridoxal 5′-phosphate, S-adenosyl-L-methionine and thiamine diphosphate (A. Kolo, unpublished).

Apart from provisioning vitamins and cofactors, endosymbionts may also supply amino acids and other metabolites that boost tick fitness (Fig. 2). For instance, in silico flux balance analyses of CRt and CE of R. sanguineus (CRs) identified excessive production of the amino acid proline, which is thought to play a significant role in arthropods due to its involvement in energy production and nitrogen metabolism (O'Donnell and Donini, Reference O'Donnell, Donini, Weihrauch and O'Donnell2017; Tsementzi et al., Reference Tsementzi, Castro Gordillo, Mahagna, Gottlieb and Konstantinidis2018). Similarly, CERM encodes genes for the production of essential amino acids, and FLE-Am appears to have the metabolic capacity to produce the amino acids cysteine, threonine, tyrosine, tryptophan, phenylalanine and serine from pyruvate (Gerhart et al., Reference Gerhart, Moses and Raghavan2016). Additionally, FEs encode enzymes that recycle nitrogen by incorporating ammonia, a metabolic waste product, into the synthesis of glutamine, as done by several insect endosymbionts (Sabree et al., Reference Sabree, Kambhampati and Moran2009; Hansen and Moran, Reference Hansen and Moran2011; Gerhart et al., Reference Gerhart, Auguste Dutcher, Brenner, Moses, Grubhoffer and Raghavan2018).

Figure 2. Putative functions of tick endosymbionts. G represents information based on genome sequences and E indicates data derived from experimental studies. CE, Coxiella endosymbiont; FE, Francisella endosymbiont; RE, Rickettsia endosymbiont; CMM, Candidatus Midichloria mitochondrii.

CMM genome encodes proteins that could assist I. ricinus in its response to oxidative stress and in energy metabolism (Olivieri et al., Reference Olivieri, Epis, Castelli, Varotto Boccazzi, Romeo, Desirò, Bazzocchi, Bandi and Sassera2019) (Fig. 2). These proteins include the cytochrome cbb3 oxidases that may support ATP production with reduced levels of oxygen concentration during oogenesis, heme exporter proteins, a protoheme ferro-lyase, superoxide dismutase, ferrochelatase, nucleotide tlc translocases and a pathway for the synthesis of lipoic acid, a cofactor that forms part of diverse enzyme complexes of electron transport chains in mitochondria (Packer et al., Reference Packer, Witt and Tritschler1995; Sassera et al., Reference Sassera, Lo, Epis, D'Auria, Montagna, Comandatore, Horner, Peretó, Luciano, Franciosi, Ferri, Crotti, Bazzocchi, Daffonchio, Sacchi, Moya, Latorre and Bandi2011; Olivieri et al., Reference Olivieri, Epis, Castelli, Varotto Boccazzi, Romeo, Desirò, Bazzocchi, Bandi and Sassera2019). Proteins such as constituents of the major facilitator superfamily and the drug/metabolite transporter superfamily potentially responsible for the transportation of fluids and ions such as sodium, protons and potassium and the uptake of organic compounds like amino acids were also annotated in the genome of CMM suggesting that the bacterium may play a role in the maintenance of osmoregulation and water balance in I. ricinus during blood feeding (Olivieri et al., Reference Olivieri, Epis, Castelli, Varotto Boccazzi, Romeo, Desirò, Bazzocchi, Bandi and Sassera2019). Lastly, a recently acquired CMM in Hyalomma marginatum seems to compensate for the loss of biotin and heme biosynthesis genes in the co-infecting FE (Buysse et al., Reference Buysse, Floriano, Gottlieb, Nardi, Comandatore, Olivieri, Giannetto, Palomar, Makepeace, Bazzocchi, Cafiso, Sassera and Duron2021b), probably because both endosymbionts together provide critical metabolites to ticks as observed in several insects (Husnik and McCutcheon, Reference Husnik and McCutcheon2016; Santos-Garcia et al., Reference Santos-Garcia, Juravel, Freilich, Zchori-Fein, Latorre, Moya, Morin and Silva2018; Takeshita et al., Reference Takeshita, Yamada, Kawahara, Narihiro, Ito, Kamagata and Shinzato2019).

Experimental evidence for endosymbiont function

Administration of antibiotics that diminish endosymbiont populations leads to reduced reproductive success in ticks, suggesting a fitness-boosting role for endosymbionts (Fig. 2). For instance, exposure of A. americanum to tetracycline and rifampicin led to a decrease in CE load and concomitant reduction in reproductive fitness, as evidenced by a setback in the rate of oviposition and significantly lower number of ticks that emerged from eggs (Zhong et al., Reference Zhong, Jasinskas and Barbour2007). Similarly, injection of tetracycline into R. microplus and its cattle host led to reduced levels of CERM and a delay in the development of the tick at the metanymph phase (Guizzo et al., Reference Guizzo, Parizi, Nunes, Schama, Albano, Tirloni, Oldiges, Vieira, Oliveira, Leite, Gonzales, Farber, Martins, Vaz and Oliveira2017), and administration of ofloxacin to R. sanguineus led to reduced burdens of CRs accompanied by an increase in time for adult females to feed to repletion, a reduced engorgement weight and a decreased capacity to lay eggs (Ben-Yosef et al., Reference Ben-Yosef, Rot, Mahagna, Kapri, Behar and Gottlieb2020; An et al., Reference An, Bhowmick, Liang, Suo, Liao, Zhao and Han2022). Likewise, tetracycline administration to female H. longicornis led to reduced densities of the Coxiella symbiont in the ovaries and malpighian tubules, which led to significant changes in tick engorgement weight, feeding time, number of eggs laid and the length of the oviposition period (Zhang et al., Reference Zhang, Li, Zhang, Qiu, Li, Li and Liu2017).

The reduction in tick fitness associated with endosymbiont loss could be due to the diminished availability of B vitamins that are vital to tick development. Antibiotic treatment of O. moubata reduced the tick's FE burden and interrupted with normal nymph feeding and moulting, which forestalled the development of viable adult female ticks and significantly lowered the emergence of male ticks. Providing a B vitamin mixture (thiamine, riboflavin, niacin, pantothenic acid, pyridoxine, biotin, folate and cobalamin) to O. moubata restored its reproductive fitness, indicating a role for FLE-Om in provisioning B vitamins required for normal tick development and reproduction (Duron et al., Reference Duron, Morel, Noël, Buysse, Binetruy, Lancelot, Loire, Ménard, Bouchez, Vavre and Vial2018).

Experiments also suggest that endosymbionts may contribute to the blood-feeding capacity of ticks (Fig. 2). Treatment of H. longicornis nymphs with tetracycline reduced the levels of the Coxiella symbiont (CHI), which in turn reduced the blood intake of the tick (Zhong et al., Reference Zhong, Zhong, Peng, Zhou, Wang, Tang and Wang2021). Intriguingly, it is the metabolite chorismate produced by CHI rather than B vitamins or cofactors that likely influences tick blood intake. The study showed that chorismate promotes the production of 5-hydroxytryptamine (serotonin), a bioamine whose stability in the midgut and synganglion of the tick regulates the amount of blood ingested by the tick (Zhong et al., Reference Zhong, Zhong, Peng, Zhou, Wang, Tang and Wang2021). Similar to H. longicornis, administration of antibiotics to R. sanguineus and R. microplus also reduced the density of CEs and tick blood intake, and transcriptomic analysis of CERM-free R. microplus metanymphs revealed that genes associated with tick blood-feeding capacity such as DAP-36, lipocalin, trypsin inhibitor-like family, Kunitz-type inhibitors, cystatin and evasins were significantly under-expressed (Guizzo et al., Reference Guizzo, Parizi, Nunes, Schama, Albano, Tirloni, Oldiges, Vieira, Oliveira, Leite, Gonzales, Farber, Martins, Vaz and Oliveira2017; Zhang et al., Reference Zhang, Li, Zhang, Qiu, Li, Li and Liu2017; Ben-Yosef et al., Reference Ben-Yosef, Rot, Mahagna, Kapri, Behar and Gottlieb2020; An et al., Reference An, Bhowmick, Liang, Suo, Liao, Zhao and Han2022). Collectively, these data indicate that CEs improve blood feeding across tick species, but further studies are required to confirm whether endosymbiont-produced chorismate is the key metabolite that drives this process in all ticks.

CMM is the most common endosymbiont associated with I. ricinus and feeding females with tetracycline-containing bovine blood produced CMM-free ticks within 2 generations. Larvae that hatched from eggs laid by CMM-free females consistently performed poorly during blood feeding, suggesting that CMM is required for the emergence of larvae with intact blood-feeding ability (Guizzo et al., Reference Guizzo, Hatalová, Frantová, Zurek, Kopáček and Perner2023). Similar to the above findings, I. ricinus nymphs fed with gentamicin-treated blood had significantly lower engorgement weights, lower moulting proportions and lower weights of moulted unfed adult females in comparison to nymphs fed on antibiotic-free blood (Militzer et al., Reference Militzer, Pinecki Socias and Nijhof2023). These studies show that CMM, in addition to CEs, enhances blood intake by ticks. Interestingly, increased blood feeding by ticks seems to benefit the endosymbionts as well. For example, Francisella symbionts in H. doenitzi significantly increased in number during blood feeding, and Rickettsia sp. phylotype G021 and CMM multiplied massively in I. pacificus and I. ricinus, respectively, following blood meals (Sassera et al., Reference Sassera, Lo, Bouman, Epis, Mortarino and Bandi2008; Cheng et al., Reference Cheng, Lane, Moore and Zhong2013; Liu et al., Reference Liu, Yu, Liu, Li, Wang, Zhang and Liu2016). Thus, improved intake of blood, which nourishes both tick and endosymbiont, seems to be one of the major benefits of long-term symbiosis between ticks and intracellular bacteria.

Finally, D. variabilis and A. americanum larvae infected with Rickettsia symbionts displayed increased motility than uninfected larvae [42]. The locomotive ability of newly hatched larvae was determined on flat and inclined surfaces and Rickettsia-containing larvae displayed increased locomotive speed relative to uninfected larvae. Tick motility plays a role in host-questing success; thus, infection with Rickettsia symbionts may impact the disease risk posed by tick-borne pathogens.

Conclusions and future directions

In summary, a major function of tick endosymbionts seems to be the provisioning of B vitamins, especially riboflavin, biotin and folate (Fig. 1). B vitamins are in short supply in vertebrate blood; hence, maintaining endosymbionts that reliably provide these vital nutrients could be an adaptation that allowed ticks to evolve a strictly blood-dependent lifestyle. Endosymbionts also seem to provide additional functions such as improved blood intake and increased motility that enhance tick physiology and reproductive success (Fig. 2). However, these roles have only been demonstrated in a few tick–endosymbiont systems, so more studies are needed to understand whether these features are lineage-specific or are more widespread. This information is especially relevant given that CE, FE and CMM phylogenies often do not agree with tick phylogenies (Epis et al., Reference Epis, Sassera, Beninati, Lo, Beati, Piesman, Rinaldi, McCoy, Torina, Sacchi, Clementi, Genchi, Magnino and Bandi2008; Cafiso et al., Reference Cafiso, Bazzocchi, De Marco, Opara, Sassera and Plantard2016; Duron et al., Reference Duron, Binetruy, Noël, Cremaschi, McCoy, Arnathau, Plantard, Goolsby, Pérez de León and Heylen2017; Binetruy et al., Reference Binetruy, Buysse, Lejarre, Barosi, Villa, Rahola, Paupy, Ayala and Duron2020). One of the underlying causes for this discordant evolutionary pattern could be that different tick species have acquired endosymbionts belonging to divergent Coxiella, Francisella and Candidatus Midichloria branches (Epis et al., Reference Epis, Sassera, Beninati, Lo, Beati, Piesman, Rinaldi, McCoy, Torina, Sacchi, Clementi, Genchi, Magnino and Bandi2008; Cafiso et al., Reference Cafiso, Bazzocchi, De Marco, Opara, Sassera and Plantard2016; Gerhart et al., Reference Gerhart, Auguste Dutcher, Brenner, Moses, Grubhoffer and Raghavan2018; Brenner et al., Reference Brenner, Muñoz-Leal, Sachan, Labruna and Raghavan2021). Thus, it is possible that depending on the lineages of their ancestors, endosymbionts in different tick species perform divergent functions.

Relatedly, another aspect of tick biology that we do not fully understand is how CEs and FEs evolved from pathogenic ancestors (Gerhart et al., Reference Gerhart, Moses and Raghavan2016; Brenner et al., Reference Brenner, Muñoz-Leal, Sachan, Labruna and Raghavan2021). For example, pathogens such as C. burnetii and F. tularensis are not vertically transmitted (Genchi et al., Reference Genchi, Prati, Vicari, Manfredini, Sacchi, Clementi, Bandi, Epis and Fabbi2015; Buysse et al., Reference Buysse, Duhayon, Cantet, Bonazzi and Duron2021a), but maternal transmission is a critical step in endosymbiosis. Thus, understanding how this process arose and is maintained in ticks would provide new insights into the biology of highly integrated tick–endosymbiont systems.

In addition to vertical transmission, an essential factor that sustains endosymbiosis is the presumed dependence of ticks on nutrients provided by endosymbionts. Going forward, functional studies to identify specific metabolites that sustain tick–endosymbiont relationships should be prioritized. Developing genetically tractable tick–endosymbiont model systems would accelerate this area of research by facilitating the disruption of endosymbiont genes to assess their impact on tick physiology and fitness. Although methodologies to culture and genetically manipulate CEs or FEs have not yet been developed, genetic tools and culture media are available for related pathogens C. burnetii and F. tularensis (Zogaj and Klose, Reference Zogaj and Klose2010; Omsland et al., Reference Omsland, Beare, Hill, Cockrell, Howe, Hansen, Samuel and Heinzen2011). These systems could be adapted to generate mutant CE or FE strains to assay the contributions of specific metabolites to tick physiology and reproductive success.

Future functional studies should also device alternatives to the current practice of using antibiotics to generate endosymbiont-free ticks. This is because antibiotics may eliminate other members of the tick microbiota, thus making it difficult to determine whether any observed effect is solely due to the loss of the endosymbiont. Another key aspect to consider while investigating endosymbiont function is the potential contributions made by the rest of the tick microbiota towards tick physiology. For instance, gut microbiota may modify metabolites present in blood meal to make them amenable for use by tick or endosymbiont. Similarly, antibacterial peptides produced by the tick innate immune system in response to gut bacteria could impact the location and functions of tick endosymbionts (Narasimhan et al., Reference Narasimhan, Swei, Abouneameh, Pal, Pedra and Fikrig2021). Several recent studies have analysed the metabolic capabilities of tick microbiomes (Obregón et al., Reference Obregón, Bard, Abrial, Estrada-Peña and Cabezas-Cruz2019; Estrada-Peña et al., Reference Estrada-Peña, Cabezas-Cruz and Obregón2020). These observations should be integrated with data from endosymbionts to gain a holistic view of how endosymbionts along with rest of the microbiota influence tick biology.

Lastly, targeting keystone taxa among tick microbiota is an innovative approach to inhibit the spread of ticks. Recent studies showed that microbiota were disrupted in ticks fed on blood from mice vaccinated against keystone taxa (Mateos-Hernández et al., Reference Mateos-Hernández, Obregón, Maye, Borneres, Versille, de la Fuente, Estrada-Peña, Hodžić, Šimo and Cabezas-Cruz2020, Reference Mateos-Hernández, Obregón, Wu-Chuang, Maye, Bornères, Versillé, de la Fuente, Díaz-Sánchez, Bermúdez-Humarán, Torres-Maravilla, Estrada-Peña, Hodžić, Šimo and Cabezas-Cruz2021). While the exact physiological consequences of such ‘anti-microbiota’ vaccines are yet to be elucidated, this approach holds promise as an alternative to the use of acaricides to control tick infestation and pathogen transmission. A complementary approach would be to identify/develop molecules that target biochemical processes that are unique to endosymbionts, which are stable members of tick microbiota. For this approach to succeed, it is necessary to gain a deeper understanding of how the enmeshed tick–endosymbiont metabolic pathways function to improve tick physiology and fitness. By developing new molecular tools to manipulate endosymbiont genes and by considering endosymbiont physiology in the context of the whole tick microbiota, future studies should make anti-endosymbiont strategies a reality.

Data availability

Not applicable.

Author's contributions

A. O. K. searched the literature and drafted the manuscript. R. R. revised and edited the manuscript.

Financial support

This work was supported by funds provided by the University of Texas at San Antonio.

Competing interests

None.

Ethical standards

Not applicable.

References

Ahantarig, A, Malaisri, P, Hirunkanokpun, S, Sumrandee, C, Trinachartvanit, W and Baimai, V (2011) Detection of Rickettsia and a novel Haemaphysalis shimoga symbiont bacterium in ticks in Thailand. Current Microbiology 62, 14961502.CrossRefGoogle Scholar
Ahantarig, A, Trinachartvanit, W, Baimai, V and Grubhoffer, L (2013) Hard ticks and their bacterial endosymbionts (or would be pathogens). Folia Microbiologica 58, 419428.CrossRefGoogle ScholarPubMed
Aivelo, T, Norberg, A and Tschirren, B (2019) Bacterial microbiota composition of Ixodes ricinus ticks: the role of environmental variation, tick characteristics and microbial interactions. PeerJ 7, e8217.CrossRefGoogle ScholarPubMed
An, L, Bhowmick, B, Liang, D, Suo, P, Liao, C, Zhao, J and Han, Q (2022) The microbiota changes of the brown dog tick, Rhipicephalus sanguineus under starvation stress. Frontiers in Physiology 13, 932130. doi: 10.3389/fphys.2022.932130CrossRefGoogle ScholarPubMed
Anderson, JF and Magnarelli, LA (2008) Biology of ticks. Infectious Disease Clinics of North America 22, 195215.CrossRefGoogle ScholarPubMed
Andreotti, R, Pérez de León, AA, Dowd, SE, Guerrero, FD, Bendele, KG and Scoles, GA (2011) Assessment of bacterial diversity in the cattle tick Rhipicephalus (Boophilus) microplus through tag-encoded pyrosequencing. BMC Microbiology 11, 6.CrossRefGoogle ScholarPubMed
Anstead, CA and Chilton, NB (2014) Discovery of novel Rickettsiella spp. in ixodid ticks from Western Canada. Applied and Environmental Microbiology 80, 14031410.CrossRefGoogle ScholarPubMed
Bell-Sakyi, L, Palomar, AM and Kazimirova, M (2015) Isolation and propagation of a Spiroplasma sp. from Slovakian Ixodes ricinus ticks in Ixodes spp. cell lines. Ticks and Tick-Borne Diseases 6, 601606.CrossRefGoogle ScholarPubMed
Ben-Yosef, M, Rot, A, Mahagna, M, Kapri, E, Behar, A and Gottlieb, Y (2020) Coxiella-like endosymbiont of Rhipicephalus sanguineus is required for physiological processes during ontogeny. Frontiers in Microbiology 11, 493493.CrossRefGoogle ScholarPubMed
Bennett, GM and Moran, NA (2015) Heritable symbiosis: the advantages and perils of an evolutionary rabbit hole. Proceedings of the National Academy of Sciences of the USA 112, 1016910176.CrossRefGoogle ScholarPubMed
Benson, MJ, Gawronski, JD, Eveleigh, DE and Benson, DR (2004) Intracellular symbionts and other bacteria associated with deer ticks (Ixodes scapularis) from Nantucket and Wellfleet, Cape Cod, Massachusetts. Applied and Environmental Microbiology 70, 616620.CrossRefGoogle ScholarPubMed
Binetruy, F, Buysse, M, Lejarre, Q, Barosi, R, Villa, M, Rahola, N, Paupy, C, Ayala, D and Duron, O (2020) Microbial community structure reveals instability of nutritional symbiosis during the evolutionary radiation of Amblyomma ticks. Molecular Ecology 29, 10161029.10.1111/mec.15373CrossRefGoogle ScholarPubMed
Bodnar, JL, Fitch, S, Rosati, A and Zhong, J (2018) The folA gene from the Rickettsia endosymbiont of Ixodes pacificus encodes a functional dihydrofolate reductase enzyme. Ticks and Tick-Borne Diseases 9, 443449.CrossRefGoogle ScholarPubMed
Bonnet, SI, Binetruy, F, Hernández-Jarguín, AM and Duron, O (2017) The tick microbiome: why non-pathogenic microorganisms matter in tick biology and pathogen transmission. Frontiers in Cellular and Infection Microbiology 7, 236.CrossRefGoogle ScholarPubMed
Bown, KJ, Begon, M, Bennett, M, Woldehiwet, Z and Ogden, NH (2003) Seasonal dynamics of Anaplasma phagocytophila in a rodent-tick (Ixodes trianguliceps) system, United Kingdom. Emerging Infectious Diseases 9, 6370.CrossRefGoogle Scholar
Brenner, AE, Muñoz-Leal, S, Sachan, M, Labruna, MB and Raghavan, R (2021) Coxiella burnetii and related tick endosymbionts evolved from pathogenic ancestors. Genome Biology and Evolution 13(7), evab108.CrossRefGoogle ScholarPubMed
Buysse, M, Duhayon, M, Cantet, F, Bonazzi, M and Duron, O (2021a) Vector competence of the African argasid tick Ornithodoros moubata for the Q fever agent Coxiella burnetii. PLoS Neglected Tropical Diseases 15, e0009008.10.1371/journal.pntd.0009008CrossRefGoogle ScholarPubMed
Buysse, M, Floriano, AM, Gottlieb, Y, Nardi, T, Comandatore, F, Olivieri, E, Giannetto, A, Palomar, AM, Makepeace, BL, Bazzocchi, C, Cafiso, A, Sassera, D and Duron, O (2021b) A dual endosymbiosis supports nutritional adaptation to hematophagy in the invasive tick Hyalomma marginatum. Elife 10, e72747.CrossRefGoogle ScholarPubMed
Cafiso, A, Bazzocchi, C, De Marco, L, Opara, MN, Sassera, D and Plantard, O (2016) Molecular screening for Midichloria in hard and soft ticks reveals variable prevalence levels and bacterial loads in different tick species. Ticks and Tick-Borne Diseases 7, 11861192.CrossRefGoogle ScholarPubMed
Carpi, G, Cagnacci, F, Wittekindt, NE, Zhao, F, Qi, J, Tomsho, LP, Drautz, DI, Rizzoli, A and Schuster, SC (2011) Metagenomic profile of the bacterial communities associated with Ixodes ricinus ticks. PLoS ONE 6, e25604.10.1371/journal.pone.0025604CrossRefGoogle ScholarPubMed
Chao, L-L, Castillo, CT and Shih, C-M (2021) Molecular detection and genetic identification of Wolbachia endosymbiont in Rhipicephalus sanguineus (Acari: Ixodidae) ticks of Taiwan. Experimental and Applied Acarology 83, 115130.CrossRefGoogle ScholarPubMed
Cheng, D, Lane, RS, Moore, BD and Zhong, J (2013) Host blood meal-dependent growth ensures transovarial transmission and transstadial passage of Rickettsia sp. phylotype G021 in the western black-legged tick (Ixodes pacificus). Ticks and Tick-Borne Diseases 4, 421426.CrossRefGoogle ScholarPubMed
Clay, K, Klyachko, O, Grindle, N, Civitello, D, Oleske, D and Fuqua, C (2008) Microbial communities and interactions in the lone star tick, Amblyomma americanum. Molecular Ecology 17, 43714381.CrossRefGoogle ScholarPubMed
Dantas-Torres, F, Chomel, BB and Otranto, D (2012) Ticks and tick-borne diseases: a One Health perspective. Trends in Parasitology 28, 437446.CrossRefGoogle Scholar
de la Fuente, J, Estrada-Pena, A, Venzal, JM, Kocan, KM and Sonenshine, DE (2008) Overview: ticks as vectors of pathogens that cause disease in humans and animals. Frontiers in Bioscience 13, 69386946.10.2741/3200CrossRefGoogle ScholarPubMed
de La Fuente, J, Kocan, KM and Contreras, M (2015) Prevention and control strategies for ticks and pathogen transmission. Revue scientifique et technique (International Office of Epizootics) 34, 249264.Google ScholarPubMed
Dergousoff, SJ and Chilton, NB (2010) Detection of a new Arsenophonus-type bacterium in Canadian populations of the Rocky Mountain wood tick, Dermacentor andersoni. Experimental and Applied Acarology 52, 8591.CrossRefGoogle ScholarPubMed
Douglas, AE (2017) The B vitamin nutrition of insects: the contributions of diet, microbiome and horizontally acquired genes. Current Opinion in Insect Science 23, 6569.CrossRefGoogle Scholar
Duron, O and Gottlieb, Y (2020) Convergence of nutritional symbioses in obligate blood feeders. Trends in Parasitology 36, 816825.CrossRefGoogle ScholarPubMed
Duron, O, Noël, V, Mccoy, KD, Bonazzi, M, Sidi-Boumedine, K, Morel, O, Vavre, F, Zenner, L, Jourdain, E and Durand, P (2015) The recent evolution of a maternally-inherited endosymbiont of ticks led to the emergence of the Q fever pathogen, Coxiella burnetii. PLoS Pathogens 11, e1004892.10.1371/journal.ppat.1004892CrossRefGoogle Scholar
Duron, O, Binetruy, F, Noël, V, Cremaschi, J, McCoy, KD, Arnathau, C, Plantard, O, Goolsby, J, Pérez de León, AA and Heylen, DJ (2017) Evolutionary changes in symbiont community structure in ticks. Molecular Ecology 26, 29052921.CrossRefGoogle ScholarPubMed
Duron, O, Morel, O, Noël, V, Buysse, M, Binetruy, F, Lancelot, R, Loire, E, Ménard, C, Bouchez, O, Vavre, F and Vial, L (2018) Tick-bacteria mutualism depends on B vitamin synthesis pathways. Current Biology 28, 18961902.e1895.CrossRefGoogle Scholar
Epis, S, Sassera, D, Beninati, T, Lo, N, Beati, L, Piesman, J, Rinaldi, L, McCoy, KD, Torina, A, Sacchi, L, Clementi, E, Genchi, M, Magnino, S and Bandi, C (2008) Midichloria mitochondrii is widespread in hard ticks (Ixodidae) and resides in the mitochondria of phylogenetically diverse species. Parasitology 135, 485494.CrossRefGoogle ScholarPubMed
Ereqat, S, Nasereddin, A, Vayssier-Taussat, M, Abdelkader, A, Al-Jawabreh, A, Zaid, T, Azmi, K and Abdeen, Z (2016) Molecular evidence of Bartonella species in ixodid ticks and domestic animals in Palestine. Frontiers in Microbiology 7, 1217.CrossRefGoogle ScholarPubMed
Estrada-Pena, A, Ayllon, N and De La Fuente, J (2012) Impact of climate trends on tick-borne pathogen transmission. Frontiers in Physiology 3, 64.CrossRefGoogle ScholarPubMed
Estrada-Peña, A, Cabezas-Cruz, A and Obregón, D (2020) Behind taxonomic variability: the functional redundancy in the tick microbiome. Microorganisms 8, 1829.10.3390/microorganisms8111829CrossRefGoogle ScholarPubMed
Gall, CA, Scoles, GA, Magori, K, Mason, KL and Brayton, KA (2017) Laboratory colonization stabilizes the naturally dynamic microbiome composition of field collected Dermacentor andersoni ticks. Microbiome 5, 133.CrossRefGoogle ScholarPubMed
Genchi, M, Prati, P, Vicari, N, Manfredini, A, Sacchi, L, Clementi, E, Bandi, C, Epis, S and Fabbi, M (2015) Francisella tularensis: no evidence for transovarial transmission in the tularemia tick vectors Dermacentor reticulatus and Ixodes ricinus. PLoS ONE 10, e0133593.CrossRefGoogle ScholarPubMed
Gerhart, JG, Moses, AS and Raghavan, R (2016) A Francisella-like endosymbiont in the Gulf Coast tick evolved from a mammalian pathogen. Scientific Reports 6, 33670.10.1038/srep33670CrossRefGoogle ScholarPubMed
Gerhart, JG, Auguste Dutcher, H, Brenner, AE, Moses, AS, Grubhoffer, L and Raghavan, R (2018) Multiple acquisitions of pathogen-derived Francisella endosymbionts in soft ticks. Genome Biology and Evolution 10, 607615.CrossRefGoogle ScholarPubMed
Gottlieb, Y, Lalzar, I and Klasson, L (2015) Distinctive genome reduction rates revealed by genomic analyses of two Coxiella-like endosymbionts in ticks. Genome Biology and Evolution 7, 17791796.10.1093/gbe/evv108CrossRefGoogle ScholarPubMed
Grindle, N, Tyner, JJ, Clay, K and Fuqua, C (2003) Identification of Arsenophonus-type bacteria from the dog tick Dermacentor variabilis. Journal of Invertebrate Pathology 83, 264266.CrossRefGoogle ScholarPubMed
Guizzo, MG, Parizi, LF, Nunes, RD, Schama, R, Albano, RM, Tirloni, L, Oldiges, DP, Vieira, RP, Oliveira, WHC, Leite, MdS, Gonzales, SA, Farber, M, Martins, O, Vaz, IdS and Oliveira, PL (2017) A Coxiella mutualist symbiont is essential to the development of Rhipicephalus microplus. Scientific Reports 7, 17554.CrossRefGoogle Scholar
Guizzo, MG, Hatalová, T, Frantová, H, Zurek, L, Kopáček, P and Perner, J (2023) Ixodes ricinus ticks have a functional association with Midichloria mitochondrii. Frontiers in Cellular and Infection Microbiology 12, 1081666.CrossRefGoogle ScholarPubMed
Hansen, AK and Moran, NA (2011) Aphid genome expression reveals host symbiont cooperation in the production of amino acids. Proceedings of the National Academy of Sciences 108, 28492854.CrossRefGoogle ScholarPubMed
Henning, K, Greiner-Fischer, S, Hotzel, H, Ebsen, M and Theegarten, D (2006) Isolation of Spiroplasma sp. from an Ixodes tick. International Journal of Medical Microbiology 296, 157161.CrossRefGoogle ScholarPubMed
Hirunkanokpun, S, Ahantarig, A, Baimai, V and Trinachartvanit, W (2018) A new record of Wolbachia in the elephant ticks from Thailand. Science Asia 44, 4447.10.2306/scienceasia1513-1874.2018.44S.044CrossRefGoogle Scholar
Hunter, DJ, Torkelson, JL, Bodnar, J, Mortazavi, B, Laurent, T, Deason, J, Thephavongsa, K and Zhong, J (2015) The Rickettsia endosymbiont of Ixodes pacificus contains all the genes of de novo folate biosynthesis. PLoS ONE 10, e0144552.CrossRefGoogle ScholarPubMed
Husnik, F and McCutcheon, JP (2016) Repeated replacement of an intrabacterial symbiont in the tripartite nested mealybug symbiosis. Proceedings of the National Academy of Sciences 113, E5416E5424.CrossRefGoogle ScholarPubMed
Johnson, N (2023) Controlling ticks and tick-borne disease transmission. In Johnson, N (ed.), Ticks: Biology, Ecology and Diseases. Netherlands: Elsevier Science. pp. 193215.10.1016/B978-0-323-91148-1.00009-5CrossRefGoogle Scholar
Jongejan, F and Uilenberg, G (2004) The global importance of ticks. Parasitology 129, S3S14.CrossRefGoogle ScholarPubMed
Kagemann, J and Clay, K (2013) Effects of infection by Arsenophonus and Rickettsia bacteria on the locomotive ability of the ticks Amblyomma americanum, Dermacentor variabilis, and Ixodes scapularis. Journal of Medical Entomology 50, 155162.CrossRefGoogle ScholarPubMed
Kamani, J, Morick, D, Mumcuoglu, KY and Harrus, S (2013) Prevalence and diversity of Bartonella species in commensal rodents and ectoparasites from Nigeria, West Africa. PLoS Neglected Tropical Diseases 7, e2246.CrossRefGoogle ScholarPubMed
Karp, PD, Billington, R, Caspi, R, Fulcher, CA, Latendresse, M, Kothari, A, Keseler, IM, Krummenacker, M, Midford, PE, Ong, Q, Ong, WK, Paley, SM and Subhraveti, P (2017) The BioCyc collection of microbial genomes and metabolic pathways. Briefings in Bioinformatics 20, 10851093.10.1093/bib/bbx085CrossRefGoogle Scholar
Kurtti, TJ, Munderloh, UG, Andreadis, TG, Magnarelli, LA and Mather, TN (1996) Tick cell culture isolation of an intracellular prokaryote from the tick Ixodes scapularis. Journal of Invertebrate Pathology 67, 318321.CrossRefGoogle ScholarPubMed
Kurtti, TJ, Palmer, AT and Oliver, JH (2002) Rickettsiella-like bacteria in Ixodes woodi (Acari: Ixodidae). Journal of Medical Entomology 39, 534540.CrossRefGoogle ScholarPubMed
Lalzar, I, Harrus, S, Mumcuoglu, KY and Gottlieb, Y (2012) Composition and seasonal variation of Rhipicephalus turanicus and Rhipicephalus sanguineus bacterial communities. Applied and Environmental Microbiology 78, 41104116.10.1128/AEM.00323-12CrossRefGoogle ScholarPubMed
Latrofa, MS, Dantas-Torres, F, Giannelli, A and Otranto, D (2014) Molecular detection of tick-borne pathogens in Rhipicephalus sanguineus group ticks. Ticks and Tick-Borne Diseases 5, 943946.CrossRefGoogle ScholarPubMed
Leclerque, A and Kleespies, RG (2012) A Rickettsiella bacterium from the hard tick, Ixodes woodi: molecular taxonomy combining multilocus sequence typing (MLST) with significance testing. PLoS ONE 7, e38062.CrossRefGoogle ScholarPubMed
Lejal, E, Chiquet, J, Aubert, J, Robin, S, Estrada-Peña, A, Rue, O, Midoux, C, Mariadassou, M, Bailly, X, Cougoul, A, Gasqui, P, Cosson, JF, Chalvet-Monfray, K, Vayssier-Taussat, M and Pollet, T (2021) Temporal patterns in Ixodes ricinus microbial communities: an insight into tick-borne microbe interactions. Microbiome 9, 153.CrossRefGoogle ScholarPubMed
Lewis, D (1979) The detection of rickettsia-like microorganisms within the ovaries of female Ixodes ricinus ticks. Zeitschrift fur Parasitenkunde 59, 295298.10.1007/BF00927523CrossRefGoogle ScholarPubMed
Liu, JN, Yu, ZJ, Liu, LM, Li, NX, Wang, RR, Zhang, CM and Liu, JZ (2016) Identification, distribution and population dynamics of Francisella-like endosymbiont in Haemaphysalis doenitzi (Acari: Ixodidae). Scientific Reports 6, 35178.CrossRefGoogle ScholarPubMed
Mateos-Hernández, L, Obregón, D, Maye, J, Borneres, J, Versille, N, de la Fuente, J, Estrada-Peña, A, Hodžić, A, Šimo, L and Cabezas-Cruz, A (2020) Anti-tick microbiota vaccine impacts Ixodes ricinus performance during feeding. Vaccines 8, 702.CrossRefGoogle ScholarPubMed
Mateos-Hernández, L, Obregón, D, Wu-Chuang, A, Maye, J, Bornères, J, Versillé, N, de la Fuente, J, Díaz-Sánchez, S, Bermúdez-Humarán, LG, Torres-Maravilla, E, Estrada-Peña, A, Hodžić, A, Šimo, L and Cabezas-Cruz, A (2021) Anti-microbiota vaccines modulate the tick microbiome in a taxon-specific manner. Frontiers in Immunology 12, 704621.CrossRefGoogle Scholar
McCutcheon, JP and Moran, NA (2012) Extreme genome reduction in symbiotic bacteria. Nature Reviews Microbiology 10, 1326.CrossRefGoogle Scholar
McCutcheon, JP, Boyd, BM and Dale, C (2019) The life of an insect endosymbiont from the cradle to the grave. Current Biology 29, R485R495.CrossRefGoogle ScholarPubMed
Mediannikov, O, Subramanian, G, Sekeyova, Z, Bell-Sakyi, L and Raoult, D (2012) Isolation of Arsenophonus nasoniae from Ixodes ricinus ticks in Slovakia. Ticks and Tick-Borne Diseases 3, 367370.CrossRefGoogle ScholarPubMed
Militzer, N, Pinecki Socias, S and Nijhof, AM (2023) Changes in the Ixodes ricinus microbiome associated with artificial tick feeding. Frontiers in Microbiology 13, 1050063.CrossRefGoogle ScholarPubMed
Narasimhan, S and Fikrig, E (2015) Tick microbiome: the force within. Trends in Parasitology 31, 315323.10.1016/j.pt.2015.03.010CrossRefGoogle Scholar
Narasimhan, S, Swei, A, Abouneameh, S, Pal, U, Pedra, JHF and Fikrig, E (2021) Grappling with the tick microbiome. Trends in Parasitology 37, 722733.10.1016/j.pt.2021.04.004CrossRefGoogle ScholarPubMed
Nardi, T, Olivieri, E, Kariuki, E, Sassera, D and Castelli, M (2020) Sequence of a Coxiella endosymbiont of the tick Amblyomma nuttalli suggests a pattern of convergent genome reduction in the Coxiella genus. Genome Biology and Evolution 13(1), evaa253.Google Scholar
Noda, H, Munderloh, UG and Kurtti, TJ (1997) Endosymbionts of ticks and their relationship to Wolbachia spp. and tick-borne pathogens of humans and animals. Applied and Environmental Microbiology 63, 39263932.CrossRefGoogle ScholarPubMed
Obaid, MK, Islam, N, Alouffi, A, Khan, AZ, da Silva Vaz, I Jr., Tanaka, T and Ali, A (2022) Acaricides resistance in ticks: selection, diagnosis, mechanisms, and mitigation. Frontiers in Cellular and Infection Microbiology 12, 941831.CrossRefGoogle ScholarPubMed
Obregón, D, Bard, E, Abrial, D, Estrada-Peña, A and Cabezas-Cruz, A (2019) Sex-specific linkages between taxonomic and functional profiles of tick gut microbiomes. Frontiers in Cellular and Infection Microbiology 9, 298.CrossRefGoogle ScholarPubMed
O'Donnell, MJ and Donini, A (2017) Nitrogen excretion and metabolism in insects. In Weihrauch, D and O'Donnell, M (eds), Acid-Base Balance and Nitrogen Excretion in Invertebrates: Mechanisms and Strategies in Various Invertebrate Groups with Considerations of Challenges Caused by Ocean Acidification. Cham: Springer International Publishing, pp. 109126.10.1007/978-3-319-39617-0_4CrossRefGoogle Scholar
Olivieri, E, Epis, S, Castelli, M, Varotto Boccazzi, I, Romeo, C, Desirò, A, Bazzocchi, C, Bandi, C and Sassera, D (2019) Tissue tropism and metabolic pathways of Midichloria mitochondrii suggest tissue-specific functions in the symbiosis with Ixodes ricinus. Ticks and Tick-Borne Diseases 10, 10701077.CrossRefGoogle ScholarPubMed
Omsland, A, Beare, PA, Hill, J, Cockrell, DC, Howe, D, Hansen, B, Samuel, JE and Heinzen, RA (2011) Isolation from animal tissue and genetic transformation of Coxiella burnetii are facilitated by an improved axenic growth medium. Applied and Environmental Microbiology 77, 37203725.CrossRefGoogle ScholarPubMed
Packer, L, Witt, EH and Tritschler, HJ (1995) Alpha-lipoic acid as a biological antioxidant. Free Radical Biology and Medicine 19, 227250.CrossRefGoogle ScholarPubMed
Parola, P and Raoult, D (2001) Ticks and tickborne bacterial diseases in humans: an emerging infectious threat. Clinical Infectious Diseases 32, 897928.CrossRefGoogle ScholarPubMed
Parola, P, Paddock, CD and Raoult, D (2005) Tick-borne rickettsioses around the world: emerging diseases challenging old concepts. Clinical Microbiology Reviews 18, 719756.CrossRefGoogle ScholarPubMed
Petersen, JM, Mead, PS and Schriefer, ME (2009) Francisella tularensis: an arthropod-borne pathogen. Veterinary Research 40(2), 7.CrossRefGoogle ScholarPubMed
Piesman, J and Eisen, L (2008) Prevention of tick-borne diseases. Annual Review of Entomology 53, 323343.CrossRefGoogle ScholarPubMed
Plantard, O, Bouju-Albert, A, Malard, MA, Hermouet, A, Capron, G and Verheyden, H (2012) Detection of Wolbachia in the tick Ixodes ricinus is due to the presence of the hymenoptera endoparasitoid Ixodiphagus hookeri. PLoS ONE 7, e30692.CrossRefGoogle Scholar
Potgieter, F and Stoltsz, W (1994) Bovine anaplasmosis In Coetzer, JAW and Tustin, RC (eds), Infectious Diseases of Livestock Diseases of Livestock, with Special Reference to Southern Africa. Cape Town, South Africa: Oxford University Press. pp. 408-430.Google Scholar
Qiu, Y, Nakao, R, Ohnuma, A, Kawamori, F and Sugimoto, C (2014) Microbial population analysis of the salivary glands of ticks; a possible strategy for the surveillance of bacterial pathogens. PLoS ONE 9, e103961.CrossRefGoogle ScholarPubMed
Regier, Y, Ballhorn, W and Kempf, VAJ (2017) Molecular detection of Bartonella henselae in 11 Ixodes ricinus ticks extracted from a single cat. Parasites and Vectors 10, 105.10.1186/s13071-017-2042-7CrossRefGoogle ScholarPubMed
Sabree, ZL, Kambhampati, S and Moran, NA (2009) Nitrogen recycling and nutritional provisioning by Blattabacterium, the cockroach endosymbiont. Proceedings of the National Academy of Sciences 106, 1952119526.CrossRefGoogle ScholarPubMed
Sacchi, L, Bigliardi, E, Corona, S, Beninati, T, Lo, N and Franceschi, A (2004) A symbiont of the tick Ixodes ricinus invades and consumes mitochondria in a mode similar to that of the parasitic bacterium Bdellovibrio bacteriovorus. Tissue and Cell 36, 4353.CrossRefGoogle Scholar
Santos-Garcia, D, Juravel, K, Freilich, S, Zchori-Fein, E, Latorre, A, Moya, A, Morin, S and Silva, FJ (2018) To B or not to B: comparative genomics suggests Arsenophonus as a source of B vitamins in whiteflies. Frontiers in Microbiology 9, 2254.CrossRefGoogle Scholar
Sassera, D, Beninati, T, Bandi, C, Bouman, EAP, Sacchi, L, Fabbi, M and Lo, N (2006) Candidatus Midichloria mitochondrii’, an endosymbiont of the tick Ixodes ricinus with a unique intramitochondrial lifestyle. International Journal of Systematic and Evolutionary Microbiology, 56, 25352540.CrossRefGoogle ScholarPubMed
Sassera, D, Lo, N, Bouman, EAP, Epis, S, Mortarino, M and Bandi, C (2008) Candidatus Midichloria endosymbionts bloom after the blood meal of the host, the hard tick Ixodes ricinus. Applied and Environmental Microbiology 74, 61386140.CrossRefGoogle ScholarPubMed
Sassera, D, Lo, N, Epis, S, D'Auria, G, Montagna, M, Comandatore, F, Horner, D, Peretó, J, Luciano, AM, Franciosi, F, Ferri, E, Crotti, E, Bazzocchi, C, Daffonchio, D, Sacchi, L, Moya, A, Latorre, A and Bandi, C (2011) Phylogenomic evidence for the presence of a flagellum and cbb(3) oxidase in the free-living mitochondrial ancestor. Molecular Biology and Evolution 28, 32853296.CrossRefGoogle ScholarPubMed
Smith, TA, Driscoll, T, Gillespie, JJ and Raghavan, R (2015) A Coxiella-like endosymbiont is a potential vitamin source for the Lone Star tick. Genome Biology and Evolution 7, 831838.10.1093/gbe/evv016CrossRefGoogle ScholarPubMed
Sonenshine, DE (2018) Range expansion of tick disease vectors in North America: implications for spread of tick-borne disease. International Journal of Environmental Research and Public Health 15(3), 478.CrossRefGoogle ScholarPubMed
Sonenshine, DE and Roe, RM (2014) Biology of Ticks, In Sonenshine DE and Roe RM (eds). Volume 2. New York, NY: Oxford University Press, pp. 316.Google Scholar
Sun, LV, Scoles, GA, Fish, D and O'Neill, SL (2000) Francisella-like endosymbionts of ticks. Journal of Invertebrate Pathology 76, 301303.10.1006/jipa.2000.4983CrossRefGoogle ScholarPubMed
Takeshita, K, Yamada, T, Kawahara, Y, Narihiro, T, Ito, M, Kamagata, Y and Shinzato, N (2019) Tripartite symbiosis of an anaerobic scuticociliate with two hydrogenosome-associated endosymbionts, a Holospora related alphaproteobacterium and a methanogenic archaeon. Applied and Environmental Microbiology 85, e00854–e00819.CrossRefGoogle Scholar
Tsementzi, D, Castro Gordillo, J, Mahagna, M, Gottlieb, Y and Konstantinidis, KT (2018) Comparison of closely related, uncultivated Coxiella tick endosymbiont population genomes reveals clues about the mechanisms of symbiosis. Environmental Microbiology 20, 17511764.CrossRefGoogle ScholarPubMed
Zhang, X, Norris, DE and Rasgon, JL (2011) Distribution and molecular characterization of Wolbachia endosymbionts and filarial nematodes in Maryland populations of the lone star tick (Amblyomma americanum). FEMS Microbiology Ecology 77, 5056.CrossRefGoogle ScholarPubMed
Zhang, C-M, Li, N-X, Zhang, T-T, Qiu, Z-X, Li, Y, Li, L-W and Liu, J-Z (2017) Endosymbiont CLS-HI plays a role in reproduction and development of Haemaphysalis longicornis. Experimental and Applied Acarology 73, 429438.10.1007/s10493-017-0194-yCrossRefGoogle Scholar
Zhong, J, Jasinskas, A and Barbour, AG (2007) Antibiotic treatment of the tick vector Amblyomma americanum reduced reproductive fitness. PLoS ONE 2, e405.CrossRefGoogle ScholarPubMed
Zhong, Z, Zhong, T, Peng, Y, Zhou, X, Wang, Z, Tang, H and Wang, J (2021) Symbiont-regulated serotonin biosynthesis modulates tick feeding activity. Cell Host & Microbe 29, 15451557.e1544.CrossRefGoogle ScholarPubMed
Zhu, Z, Aeschlimann, A and Gern, L (1992) Rickettsia-like microorganisms in the ovarian primordial of molting Ixodes ricinus (Acari: Ixodidae) larvae and nymphs. Annales de parasitologie humaine et comparée 67, 99110.10.1051/parasite/199267499CrossRefGoogle Scholar
Zogaj, X and Klose, KE (2010) Genetic manipulation of Francisella tularensis. Frontiers in Microbiology 1, 142.Google ScholarPubMed
Figure 0

Figure 1. B vitamin biosynthesis pathways in tick endosymbionts. Pathway for the synthesis of cobalamin (vitamin B12) was not detected in any tick endosymbiont genome. CE, Coxiella endosymbiont; FE, Francisella endosymbiont; CMM, Candidatus Midichloria mitochondrii.

Figure 1

Figure 2. Putative functions of tick endosymbionts. G represents information based on genome sequences and E indicates data derived from experimental studies. CE, Coxiella endosymbiont; FE, Francisella endosymbiont; RE, Rickettsia endosymbiont; CMM, Candidatus Midichloria mitochondrii.