Next Article in Journal
Phylogenomic Analysis of Two Species of Parasenecio and Comparative Analysis within Tribe Senecioneae (Asteraceae)
Previous Article in Journal
Length–Weight Relationships and Diversity Status of Fishes in the Midstream of the Jialing River, a Tributary of the Upper Yangtze River, China
Previous Article in Special Issue
Diversity and Regional Variation of Endosymbionts in the Green Peach Aphid, Myzus persicae (Sulzer)
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Diversity
Volume 15
Issue 4
10.3390/d15040562
diversity-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Review

The Importance and Impact of Francisella-like Endosymbionts in Hyalomma Ticks in the Era of Climate Change

by
Celia Sesmero-García
1,
Marta Dafne Cabanero-Navalon
1,* and
Victor Garcia-Bustos
1,2
1
Department of Internal Medicine and Infectious Diseases, University and Polytechnic Hospital La Fe, 46026 Valencia, Spain
2
Severe Infection Research Group, Health Research Institute La Fe, 46026 Valencia, Spain
*
Author to whom correspondence should be addressed.
Diversity 2023, 15(4), 562; https://doi.org/10.3390/d15040562
Submission received: 27 February 2023 / Revised: 5 April 2023 / Accepted: 12 April 2023 / Published: 17 April 2023
(This article belongs to the Special Issue Bacterial Symbionts of Invertebrates: Diversity, Transmission and Impacts)
Versions Notes

Abstract

:
Ticks are obligatory hematophagous parasites that serve as vectors for a large amount of important human and livestock pathogens around the world, and their distribution and incidence of tick-associated diseases are currently increasing because of environmental biomass being modified by both climate change and other human activities. Hyalomma species are of major concern for public health, due to their important role as vectors of several diseases such as the Crimea–Congo hemorrhagic fever (CCHF) virus in humans or theileriosis in cattle. Characterizing the Hyalomma-associated microbiota and delving into the complex interactions between ticks and their bacterial endosymbionts for host survival, development, and pathogen transmission are fundamental, as it may provide new insights and spawn new paradigms to control tick-borne diseases. Francisella-like endosymbionts (FLEs) have recently gained importance, not only as a consequence of the public health concerns of the highly transmissible Francisella tularensis, but for the essential role of FLEs in tick homeostasis. In this comprehensive review, we discuss the growing importance of ticks associated with the genus Hyalomma, their associated tick-borne human and animal diseases in the era of climate change, as well as the role of the microbiome and the FLE in their ecology. We compile current evidence from around the world on FLEs in Hyalomma species and examine the impact of new molecular techniques in the study of tick microbiomes (both in research and in clinical practice). Lastly, we also discuss different endosymbiont-directed strategies for the control of tick populations and tick-borne diseases, providing insights into new evidence-based opportunities for the future.

1. Introduction

Ticks are obligatory hematophagous ectoparasites that act as vectors for many important human and livestock pathogens worldwide [1]. Like spiders and scorpions, they belong to the class Arachnida. Within the order Ixodida, most species of ticks belong to one of the two main large families, Argasidae or Ixodidae. The latter are known as “hard” ticks since they have a sclerotized dorsal plaque or scutum. In contrast, those belonging to the family Argasidae lack this physical feature and are therefore known as “soft ticks” [2]. Tick-borne infectious diseases spread following the bite of infected ticks, which can carry and be infected by bacteria, viruses, or parasites. Some of the most important bacteria-infecting ticks include species of the genera Rickettsia, Borrelia, Francisella, Anaplasma, and Ehrlichia, as well as viruses such as the Crimea–Congo hemorrhagic fever (CCHF) virus, the West Nile virus, and the tick-borne encephalitis virus, among others.
The population of these parasites has been shown to increase over the last past years, as has the incidence of vector-related animal diseases and human zoonoses [3]. Recently, Hyalomma ticks have been more frequently found in areas where they were not previously reported. This genus, its occurrence, and its potential spread are of major concern for public health due to their important role as vectors of several diseases, such as the CCHF virus in humans or theileriosis in cattle, among others [4].
Characterizing the tick-associated microbiota and delving into the complex interactions between ticks and their bacterial endosymbionts for host survival, development, and pathogen transmission are fundamental. This may give new insights and spawn new paradigms to control tick-borne diseases [5]. Among the different both pathogenic and non-pathogenic bacterial species within the tick microbiome, Francisella-like endosymbionts (FLEs) have recently gained importance, not only as a consequence of the public health concerns of the highly transmissible Francisella tularensis, but also for the essential role of FLEs in tick homeostasis.
Current evidence on the ecology, biology, and pathogenicity of FLEs is limited, as is evidence on the hosts in which they act as endosymbionts. Therefore, the global aim of this review is to gather state-of-the-art knowledge of FLEs and Hyalomma species through a comprehensive analysis of all studies that aim to characterize the endosymbiont–tick relationships, their ecology, and their importance for tick survival, as well as epidemiological evidence based on molecular techniques for species-level identification. Improving our knowledge on these species and their relationship with Hyalomma ticks could prove to be highly beneficial for developing strategies to prevent and control tick-borne diseases and new emerging pathogens.

2. The Increase in Ticks and Tick-Borne Diseases in the Era of Climate Change

In recent years, there has been an increase in the population of these ectoparasites, possibly as a result of the modification of the environmental biomass caused by humans, but also due to climate change and global warming, the altered migration patterns of birds, as well as human migrations due to wars and geopolitical conflicts, among others [3,6,7,8,9].
There are rising reports that advocate for the northward spread of thermophilic ixodid species, such as Hyalomma. In this particular case, there have been many studies that evidence the dwindling success of these Afro-Mediterranean tick species in continental climates in Europe, and with contact with animals and humans.
For example, early in 2012, an adult case of H. marginatum rufipes was reported on cattle under a continental climate in Hungary [10]. Since then, many other studies have also identified other Hyalomma species in animals and humans in Hungary [11], the Netherlands [12], and Germany [13]; in cattle of Corsica in France [14]; in an English horse [15]; and in a migrant in Malta [6]. Furthermore, the first human exposure to a locally acquired adult H. marginatum was recently described in England in 2021 [16]. Most of these reports have detected the successful molting of these Hyalomma species in newly colonized regions of Europe.
Both climate change and other human activities (deforestation, urbanization, and international travel) [17] play a decisive role in the increase in infectious pathogens and their transmission vectors. In a recent study, the impact of climate trends in the distribution of H. marginatum was explored. The authors generated annual models of environmental suitability for the tick in the period 1970–2018, using harmonic regression-derived data of the daily maximum and minimum temperature, soil moisture, and water vapor deficit. It was concluded that climate change could create new areas in Europe with suitable climates for H. marginatum, while keeping its “historical” distribution in the Mediterranean [7]. Moreover, other works have discussed the importance of migratory birds in the international dispersion of Hyalomma ticks. They may play an important role in the changing climatic and environmental conditions in Europe because birds that cover long distances over a short time and stay temporarily in different habitats in the context of climate change can introduce tick and pathogen species in areas where they have never been [8].
This appearance of vectors and zoonotic infectious diseases in areas where no disease had been previously reported so far [2,18] reaffirms the prompt needed for further strategies for dispersion control, especially considering both the impact of tick-borne diseases and also their potential social and economic impact [1].

3. The Impact of Ticks of the Genus Hyalomma on Human and Animal Health

The genus Hyalomma is included in the family Ixodidae and is considered one of the main transmission vectors of the CCHF virus in humans and theileriosis in cattle. This genus comprises more than 20 species, mainly distributed across three continents: Europe, Asia, and Africa [19] (Table 1). Up to half of them are capable of transmitting disease-causing pathogens, and due to their adaptability, they are usually found in tropical or subtropical areas, mainly where arid climates predominate [20]. Despite being transmitters of potentially fatal diseases, ticks from this genus are not particularly anthropophilic, and the risk of transmitting diseases to humans is lower than in other genera, such as Ixodes or Dermacentor [19].
Firstly, Hyalomma aegyptum constitutes one of the best known species within the genus. This species of tick is abundantly distributed throughout the eastern parts of European territory and the northern parts of the African continent. Characteristically, it has been seen to use camels and tortoises of the genus Testudo as hosts [21]. In a study conducted in Qatar, the most frequently identified pathogen in these latter hosts was Hemolivia mauritanica. This justifies the need to increase control over species such as Testudo tortoises in order to reduce the spread of infectious diseases caused by H. mauritanica, Candidatus Midichloria mitochondrii, or Ehrlichia spp. [22]. This same study shows that H. dromedarii uses the same intermediate hosts as H. aegyptum and is also one of the main vectors of the transmission of Q fever and theileriosis among camels in North Africa [29].
Secondly, H. albiparmatum, H. nitidum, and H. truncatum are morphologically very similar species that are differentiated by the identification and comparison of somatic primary or secondary sexual characteristics that they develop throughout adult life [23]. Both H. albiparmatum and H. nitidum extend through the central areas of the African continent (Senegal, Kenya, and the Democratic Republic of Congo), while H. truncatum has been found to be widely distributed [24].
H. brevipunctata, together with H. hussaini, H. anatolicum, H. dromedarii, and H. marginatum, uses the buffalo of northern India as an animal host to transmit diseases such as babesiosis [25]. Babesia has also been identified in other species such as H. rufipes, H. impressum, H. truncatum, H. marginatum, and H. impeltatum. It is worth mentioning that H. brevipunctata is one of the most virulent species, capable of causing otoacariasis and tick paralysis in humans [19]. Surprisingly, despite the fact that H. marginatum and H. impeltatum act as multi-pathogen reservoirs and have a higher prevalence around the world, it is H. rufipes that has the greatest participation and influence in the spread of this disease among Nigerian cattle [38].
H. arabica is the most abundant tick species in the Hyalomma genus in Saudi Arabia. It is restricted to the western parts of this country and the Al-Sarawat mountain range in Yemen, and sheep are its main host [27]. It is the closest phylogenetic species to H. kumari, which ranges from India to western Iran [32].
H. eryathareum has been taxonomically redefined as H. somaliticum. Along with H. impelatum, both are included in the H. asiaticum group [30]. H. somaliticum is one of the main vectors of bovine theileriosis in rural areas of Saudi Arabia [31], whilst H. detritum is one of the main vectors in parts of North Africa, such as Morocco [28].
H. franchinii is one of eight tick species of the Ixodes group that are restricted to the Mediterranean basin [23]. Along with H. lussitanicum, it is one of the species undergoing an explosive population increase and has been identified in Spain as a transmitter of the CCHF virus [33]. Up to 80% of the ticks identified in the Iberian Peninsula belong to the species H. lusitanum. Furthermore, Francisella were the most common genera in H. anatolicum, possibly indicating that some pathogenic species such as F. tularensis may be present in the animal population parasitized by this tick species [26].
H. marginatum is one of the most widespread species worldwide. It is the main known vector of the CCHF virus, and, in recent years, its prevalence has increased in areas of northern Europe such as Sweden [35], England [16], and the Czech Republic [36]. Likewise, H. rufipes has also recently increased since it was unexpectedly found for the first time in Malta in 2020 [6]. Their increasing incidence evidences the prompt need to epidemiologically control and develop screening strategies for tick-borne infectious diseases in Northern Europe.
H. punctata is predominantly distributed in northern Somalia and Ethiopia, while H. rhipicephaloides has been primarily identified round the Dead Sea. Both types of ticks hav goats and gazelles as hosts [37]. H. schulzei is known to be one of the leading species in the transmission of ehrlichiosis and anaplasmosis among cattle on the border between Iran and Pakistan. It poses a serious problem for the economy of rural parts of the country, given that livestock accounts for their principal income source [39].
H. scupense, along with H. anatolicum, stands out as one of the main vectors of theileriosis transmission in Africa [41]. It is mainly distributed in the African Maghreb area [40]. Theileriosis is a disease caused by the apicomplexan protist of the genus Theileria. They are obligatory intracellular parasites that use cattle as their main host. The two best known species are T. parva, which causes East Coast fever, and T. annulata, which causes tropical theileriosis. Only T. annulata, T. lestoquardi, T. ovis, and T. separata have been identified in ticks of the Hyalomma genus. The East Coast fever is characterized by symptoms of generalized lymphadenopathy, fever, anorexia, the appearance of petechiae or ecchymosis on mucous membranes, and neurological signs. Tropical theileriosis also causes the destruction of red blood cells and therefore also causes jaundice, anemia, and hemoglobinuria [43]. In recent years, various strategies have been developed for the control of theileriosis in African cattle. These include vaccination with inactivated T. annulata vaccines or with H. scupense antigens, which have been associated with a reduction in tropical theileriosis in North Africa [44] and China [45].
Finally, H. turanicum and H. truncatum are two species mainly implicated in the spread of the Rift Valley fever virus and the CCHF virus, and the horizontal and vertical transmission of these agents have been previously described. They are distributed worldwide and have been reported as one of the main species that cause this disease in sheep and humans [42].

4. Delving into the Microbiome of Ticks

Since the early 20th century, an association between ticks and non-pathogenic bacteria has been known to exist [46]. Beyond those primitive reports by means of simple histological techniques and light microscopy, currently, molecular and next-generation sequencing methodologies have emerged as important tools to characterize tick microbiome compositions [47]. For some years now, efforts have been focused on determining the role of the microbiome of vector arthropods in pathogen acquisition and transmission, in the life cycle of the host, and its impact on its biology and ecology, but also on delving into both biotic and abiotic factors that model its composition. This growing interest lies in the importance of its understanding in the context of arthropod survival and pathogen transmission for the development of a new generation of arthropod and arthropod-borne pathogen control strategies [46].
Many studies have shown that ticks are closely associated with both pathogenic and non-pathogenic bacterial symbionts, which are tightly implicated in host nutritional adaptation, survival, fitness, vectorial competence, immunity, and reproduction, among others [5,48,49,50]. These bacteria are hence called endosymbionts and can either be obligatory or facultative, depending on their indispensable role in tick physiology [1]. Obligatory endosymbionts are necessary for the tick’s survival, and their depletion can lead to host death; meanwhile, facultative endosymbionts are not obligatory for tick survival but aid in several physiological processes. Almost all endosymbionts are vertically transmitted by the female germ line through the transovarial route [51]. However, evidence on the horizontal transmission of tick symbionts from the genera Midichloria, Coxiella, and Arsenophonus has also been reported [1,52,53,54].
Traditionally, the contribution of tick microbiota was assumed to be limited to providing a source of vitamin B thanks to the presence of vitamin B synthesis genes in the symbionts of the Coxiella or Francisella genera to compensate for its deficiency in the blood [55]. Nevertheless, many genera and species of non-pathogenic bacterial endosymbionts or commensals have been implicated in a wide range of important functions. Coxiella-like endosymbionts (CLEs) have been implicated in nutrient synthesis [56], the regulation of feeding activity [57], and reproductive fitness in females [58]. Rickettsia symbionts play a vital role in tick physiology, fitness, population dynamics, and pathogen transmission [1]. FLEs are important for tick growth and essential for tick nutrition and their life cycle [59]. Wolbachia bacteria are implicated in reproductive functions, vectorial competence, and defense mechanisms [1,60] Midichloria endosymbionts are involved in nutrient biosynthesis and play a role in aiding antioxidative defense and hydric balance [61]. Other genera are also present, yet with largely unknown implications, such as Spiroplasma and Arsenophonus, or even Escherichia coli, Staphylococcus, Enterococcus, and Lysinibacillus, among others [5].

5. What We Know about Francisella-like Endosymbionts

FLEs are facultative intracellular Gram-negative coccobacilli that may be obligatory symbionts of several species of ticks and hematophagous arthropods [62]. Francisella species are almost ubiquitous and are present in many ecosystems and hosts, such as lagomorphs, rodents, insectivores, carnivores, ungulates, marsupials, birds, amphibians, and (as stated) invertebrates [1]. The best known species of the genus is Francisella tularensis, the highly infectious and zoonotic pathogen that causes tularemia, a potentially fatal disease if untreated. F. tularensis as well as other subspecies and even FLEs share a high average nucleotide identity that exceeds 98% similarity [63].
Many species of Francisella find their reservoir in several tissues of ticks, such as reproductive tissues, which facilitates transovarial transmission [19,64,65], but also in salivary glands, where they may be transmitted through tick bites [1,66,67]. Furthermore, trans-stadial transmission has also been confirmed [68].
Whilst FLEs are limitedly pathogenic in small animals, it is thought that FLEs are not pathogenic for humans [69]. However, they are frequently found in many genera of human-biting ticks, such as Amblyomma, Dermacentor, and Ixodes. Hyalomma ticks are one of the main reservoirs for these endosymbionts. The lack of a proper species or even subspecies-level identification limits the information on the pathogenicity of FLEs in humans. This is problematic as there are some reports on the potentially virulent FLEs in smaller mammals [69], and identification limitations may restrict our understanding of these species.

6. The Ecological Importance of Francisella-like Endosymbionts in Ticks as Zoonotic Vectors

The development of new molecular techniques for the study of arthropod-associated microbiota has opened up a whole new field of research, not only in entomology or microbiology, but also for public health and infectious disease scientists. The study of symbiotic relationships and interactions between ticks and their tissue microbiome opens up new opportunities for disease control, as there is a growing body of knowledge on the impact of these symbiotic interactions on host ecology and physiology.
In this regard, an ecological-to-evolutionary continuum has been previously proposed, by which environmental, free-living, and/or host-associated bacteria are able to colonize tick tissues. Later, under certain conditions, they establish a symbiotic relationship with the tick host [1]. After this coevolutionary adaptation, ticks have evolved to harbor two types of endosymbionts, as previously defined: obligatory mutualistic symbionts (mostly vertically transmitted from mother to offspring) [70] and facultative symbionts [1,71] (which participate in reproductive physiology, defense against infections, or thermal adaptation, among others [72]).
Knowledge on both tick-associated pathogens and both types of symbionts is of medical and veterinary importance for the assessment of health risks and strategies. It is also of evolutionary and ecological interest, as many bacteria and their hosts share several million years of evolutionary history. This history leads to a tight interdependence with shared associated risks for obligatory endosymbionts, while facultative microbiota allow for more adaptable host–symbiont interactions [1,71].
To date, FLEs are present in several species of human-biting ticks, such as Amblyomma, Dermacentor, Hyalomma, and Ixodes, but also in many other species of tick-infesting animals, as detailed in Table 2. Despite the fact that their prevalence has been diversely reported, FLEs are homogeneously distributed in many other hosts, such as dogs, cats, sheep, and cattle, but also in wild animals, including many species of migratory birds, tortoises, and even snakes. Furthermore, they have also been found in isolates from all continents, except Antarctica (Table 2).
Several works have been devoted to understanding their role in tick physiology. FLEs have been identified as obligatory mutualists in the life cycle of the African hut tampan or Ornithodoros moubata by providing B vitamins absent in the blood meal of the tick [1,59]. On the one hand, one Francisella type, defined as F-Om by Duron et al., was shown to be maternally transmitted to all maturing ticks’ oocytes, and its experimental elimination ended up causing alteration of tick life history traits and physical abnormalities, which were cured by giving oral supplementation of B vitamins to experimental specimens of O. moubata [59]. On the other hand, another FLE, termed FLE-Am by Gerhart et al. (2016) [75], was shown to have a more extensive metabolic capacity and biosynthetic capability than CLEs in the Gulf Coast tick or Amblyomma maculatum, producing heme, cysteine, tyrosine, tryptophan, phenylalanine, or serine among other cofactors also present in CLE [75].
In both cases, genomic analyses have shown that FLEs likely evolved from a pathogenic strain of Francisella that recently transitioned to an endosymbiotic lifestyle as observed in other Francisella symbionts both related and not related to ticks [59,76,117]. This fact becomes even more interesting, especially considering that the available molecular evidence suggests that the ancestral Francisella species originated in a marine habitat [117]. Further evidence is needed in other species of ticks to keep unraveling their physiological and ecological roles.

7. The Role of Francisella-like Endosymbionts in the Ecology of Ticks of the Genus Hyalomma

Due to upcoming evidence, several studies have delved into the analysis of the prevalence and role of FLEs associated with different species of Hyalomma worldwide, as well as their associations with other pathogens (Table 3).
In a study conducted in the Anatolian region, 280 ticks from 10 different species were analyzed using next-generation sequencing in order to expand current information on tick-associated bacteria and protozoans [107]. Within the 10 selected species, 3 species of the genus Hyalomma (H. aegyptum, H. marginatum, and H. excavatum) were included. Endosymbiont microorganisms were identified in 65% of ticks. The most frequently isolated genus was Coxiella spp. (40%), followed by Francisella spp. (25%) and Rickettsia spp. (17.5%). In their work, most FLEs were associated with the genus Hyalomma, while CLEs seemed to be linked with the genus Rickettsia. According to metagenomic sequencing data, these Francisella species were different from F. tularensis, as has been systematically reported in other similar studies [81,86,99,118]. Furthermore, the FLE sequences formed phylogenetically distinct clusters with a 98% genetic similarity score, which were associated with their tick hosts, suggesting differential evolutionary patterns in various hosts and ecological niches.
These data are supported by the evidence provided by the work of Wang et al. (2018) [84] carried out in China. After analyzing a total of 627 Haemaphysalis longicornis and 88 H. asiaticum ticks, FLEs were detected in 100% of Hyalomma ticks, but in less than 10% of H. longicornis individuals. Phylogenetic analysis indicates that the sequences of FLEs isolated in H. asiaticum and H. longicornis from three regions of northern China shared a consistent 16S rRNA sequence and differed from known FLEs, suggesting genetic heterogeneity in the group, perhaps allowing adaptations to different ecosystems, as in this case of the cold parts of northern China.
However, contrary to the work by Brinkmann and colleagues (2019) [107], other studies have suggested that the evolution of FLEs could be independent of their tick hosts. In a study carried out in Bulgaria [78], it was revealed that the genetic sequences of FLEs in H. m. marginatum and R. sanguineus were identical. Moreover, the identification of two taxa of FLEs was reduced to a fraction of ticks from the same region, which seemed to be facultative secondary endosymbionts of ticks that can adapt to distinct ecological niches and environmental characteristics.
This hypothesis was also posed in an article published in Italy [74], in which the Francisella sequences detected in the study were phylogenetically close to others detected in H. marginatum and H. rufipes from Turkey [118] and Ethiopia [86]. Likewise, the results published by Díaz-Sánchez and colleagues (2021) [34] show that the FLEs identified in H. lusitanicum showed similarities of around 97–99% with other FLEs from H. marginatum, H. truncatum, or Dermacentor auratus, but not with the pathogenic species F. tularensis. Moreover, in the interesting work conducted by Azagi et al. (2017) [62], it was reported that the FLEs and Hyalomma phylogenies show obvious similarities. Through a Procrustes approach to co-phylogeny (PACo) analysis, the apparent dependence of the symbiont phylogeny on the host phylogeny appeared unlikely to be coincidental.
In a study by Szigeti et al. (2014) [86] in Ethiopia, 296 ticks were collected for the genetic sequencing of F. tularensis and FLEs. FLEs were found to cross-react with F. tularensis in basic screening tests. They proposed that the characterization of the tu4 gene could be useful to discern between FLEs and F. tularensis. However, one must take into account that the genome of FLEs includes pseudogenes and inactivated virulence versions of F. tularensis genes, suggesting that both endosymbionts and tularemia-causing pathogens have a common ancestor, as stated by Hoffman et al. (2022) [100]. Of the 296 ticks collected, only 1 belonged to the genus Hyalomma (H. rufipes), which represents a prevalence of 0.34% of the total collection. This prevalence was substantially lower than that reported in articles from North America and Eurasia, but also in Africa. In fact, in a study carried out in Egypt [99], 319 ticks were isolated, of which 249 belonged to the genus H. dromedarii. The prevalence of FLEs obtained was 6% within the genus Hyalomma, significantly lower than the 100% observed in China [82], but higher than those of Turkey (0%) [118] or Bulgaria (2.5%) [78].
One of the most important concerns regarding FLEs in Hyalomma ticks is their participation in the coinfection with pathogens of the genus Rickettsia [62].
Hoffman and colleagues [101] documented the coexistence between Francisella- and Rickettsiae-transmitting avian hemorrhagic fevers in tick-infecting birds from the Palearctic region of West Africa. The results showed a coinfection rate of 47.1% (271/575) of all selected ticks. Within the genus Hyalomma, the prevalence of the coinfection was 48.8% (235/482). Depending on the species, the following results were obtained: H. rufipes—50.6% (226/447) and H. marginatum—29.2% (7/24). This suggests that the presence of FLEs is not a protective factor against infection by other pathogens, but on the contrary, it may favor the presence of potentially virulent microorganisms. In contrast to these results, in a study published in Algeria, the highest rate of coinfection was identified within the genus Ixodes (12/13, 92.3%), followed by Hyalomma (91/113, 80.5%) and Rhipicephalus (39/109, 35.7%) [101].
Regarding coinfections with other pathogens, in a study carried out in Pakistan [97], it was found that the most frequent coinfection was between FLEs and Piroplasma species (15.8%, 37/234), followed by the coexistence of FLEs and Ehrlichia species (9.4%). The most frequent triple coinfection consisted of FLE, Piroplasma, and Ehrlichia spp. (6.8%, 16/234). These coinfections pose a significant risk, especially in veterinary medicine, not only due to the cumulative pathogenic effects of different species, but also due to the increased complexity of the targeted treatment and management of life-threatening diseases. Understanding this symbiosis between ticks, endosymbionts, and other pathogens is crucial to establishing sanitary control strategies, as the interaction between pathogenic and non-pathogenic microorganisms can affect the host’s susceptibility to other bacterial infections.
Finally, the genome of FLEs identified in H. marginatum includes genes that participate in the metabolic pathways of folate and riboflavin synthesis, while it lacks genes involved in biotin synthesis [119]. Its authors maintain that this biotin synthesis deficit is compensated by the presence of Midichloria in such a way that the coexistence between FLEs and Midichloria is a necessary endosymbiosis to meet the vitamin requirements for the host. As is the case in H. marginatum, the coexistence of these two endosymbionts has been demonstrated in the rest of the species of the genus Hyalomma, except in H. asiaticum, which contains a FLE that is capable of autonomously synthesizing biotin [119].

8. Discrimination between Francisella tularensis and Francisella-like Endosymbionts in Clinical Practice

Tularemia is a potentially fatal disease, and F. tularensis is a highly infectious microorganism that is considered a category A agent of bioterrorism [120,121]. However, there is still little data available on the implication of ticks in its transmission, and some studies have suggested that epidemiological studies that aimed to evaluate the prevalence of F. tularensis in ticks are strongly required to better understand their role in the transmission of this pathogen [63,85].
Outside the context of wide experimental studies, in the clinical practice of units of infectious diseases and clinical microbiology laboratories, patients are referred after a tick bite with or without the clinical suspicion of infectious disease and a specimen is provided for analysis. This provides an opportunity to perform molecular testing of ticks possibly implicated in disease and also in clinical practice. However, this has crucial implications for public health.
As has been previously described, the genomes of Francisella species are highly conserved, and FLEs are closely related to clinically important F. tularesis strains, as well as to other species of the genus. With most of the currently available molecular detection techniques based on multiplex panels of PCR, FLEs have been shown to cross-react with F. tularensis, leading to misidentification and misinterpretation [85]. This fact is associated with the erroneous activation of public health alarm systems, leading to an unsuitable waste of resources and the assumption that F. tularensis strains are present in clinically detected tick specimens that are only colonized by FLEs. Therefore, an accurate discrimination between F. tularensis and FLEs is critical, and the interpretation of the results must be reassessed by trained professionals who understand the ecology of ticks and the implication of endosymbionts in their ecology. Furthermore, the used detection methods need to be carefully evaluated to avoid any inaccurate interpretation of epidemiological surveys [85], and positive results in the commercial PCR panels (including tularemia, among other zoonoses) must be further confirmed by molecular techniques that can effectively discriminate between F. tularensis and FLEs.
Several studies have been devoted to analyzing and comparing molecular techniques for adequate identification and typing via real-time PCR [85] and differential insertion sequence amplification [63]. These techniques provide new capabilities for epidemiological investigations and characterizations of tularemia source outbreaks and for the discrimination of cross-reactivity in screening molecular panels. Hence, in the presence and suspicion of a positive result for F. tularensis in the molecular analyses of ticks in clinical practice, the sample must be adequately interpreted and sent to a microbiology reference lab for confirmation, and ideally for sequencing and typing, in order to characterize the Francisella species.

9. Endosymbiont-Directed Strategies for the Control of Ticks and Tick-Borne Diseases

Tick-borne diseases continue to rise and disseminate globally. They are becoming one of the more important threats to human and animal health around the world. Owing to the disruptive impacts of human activity in ecosystems, further biological and regional niches of ticks are growing, and hence the outcomes of management and control programs for tick-borne infectious diseases are difficult to predict. Over the last few years, there has been an increase in the geographical range of Hyalomma ticks, which can be attributed to the global climate changes that affect pathogens, vectors, and their hosts (mainly migratory birds) [7,8,9]. This may increase the incidence and the spread of emerging tick-borne diseases around the world [7,8,9]. Tick control via the application of acaricides has been the centerpiece of control strategies [122]. However, due to their immediate effect and cost-effective profile, the intensive and repeated use of acaricides has led to the appearance of acaricide-resistant ticks.
Due to these limitations, as well as the complex, and, in many cases, unknown biology and life cycle of ticks, the presence of two or more intermediate hosts for some species, and epidemiological changes, due to climate change among other things, multidisciplinary approaches are urgently needed. Since the 1990s, multimodal interventions, including the application of acaricides [123], autocidal control [124], the improved management of wildlife hosts [125], and especially vaccination [126,127,128,129], have proven to be effective.
Targeting vector microbiota with different strategies has been the foundation for several treatments and control measures for arthropod-borne diseases [126], as well as nematode infections such as animal and human filariasis. For instance, in human onchocerciasis and lymphatic filariasis caused by Onchocerca volvulus and Wurchereria bancrofti, respectively, the elimination of the endosymbiont Wolbachia with the use of doxycycline as an anti-Wolbachia antibiotic leads to the death of adult parasitic worms. Contrary to other anthelmintic therapies, they are readily available, cheap, and safe to use in adult patients and in individuals with other parasitic infections such as loiasis [130].
However, anti-microbiota vaccines have recently emerged as a promising tool for the control of ticks and tick-borne infections [1]. During feeding, ticks take up functional host plasma antibodies which may interact with their endosymbionts [128,129,131,132]. The utilization of vaccines that target endosymbionts to control tick populations shows that modifications in their microbiome can alter essential physiological functions, especially if the intervention is effective against obligatory endosymbionts, as previously discussed. Furthermore, several authors have emphasized that new vaccine targets should encompass proteins of the tick immune response involved in the tolerance of microbial populations [131,133].
Despite the fact that these anti-microbiota vaccines are still in their infancy, immunization with keystone tick-associated Enterobacteriaceae caused significant tick mortality. In this study, the vaccination of mice with a live vaccine containing Escherichia coli showed that the production of anti-E. coli and anti-α-Gal IgM and IgG (glycan present in tick bacterial microbiota) was associated with the high mortality rates of I. ricinus nymphs during feeding [128].
The use of microbiota-directed antibiotics has been shown to affect their bacterial symbionts and is associated with a major negative impact on both tick competence and survival [134]. Nevertheless, this approach is limited due to the risk associated with the emergence of antibiotic resistance, a worldwide emerging menace for healthcare systems, human and animal health, the ecosystem, and the food industry, as well as alterations in human and animal microbiomes [1].
Finally, the genetic manipulation of endosymbionts has also been proposed as a possible approach that is used to control vectors and vector-borne diseases [135]. Genetically transformed symbiotic bacteria are able to express molecules with antiparasitic activity may alter the arthropod’s ability to transmit pathogens. This strategy, known as paratransgenesis, has shown promise in controlling the transmission of Trypanosoma cruzi by Rhodnius prolixus [136].

10. Conclusions

In this review, we discussed the growing importance of ticks of the genus Hyalomma, their associated tick-borne human and animal diseases in the era of climate change, as well as the role of the microbiome and FLEs in their ecology. Global current evidence on FLEs in Hyalomma species has been compiled, and the impact of new molecular techniques in the study of the tick microbiome (both in research and in clinical practice) has been examined. Lastly, we also discussed different endosymbiont-directed strategies for the control of tick populations and tick-borne diseases, providing insights into new evidence-based opportunities for the future.

Author Contributions

Conceptualization, V.G.-B. and M.D.C.-N. Resources, V.G.-B. and C.S.-G. Writing—original draft preparation, C.S.-G., V.G.-B. and M.D.C.-N. Writing—review and editing, V.G.-B. and C.S.-G. Visualization, C.S.-G. and V.G.-B. Supervision, V.G.-B. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Hussain, S.; Perveen, N.; Hussain, A.; Song, B.; Aziz, M.U.; Zeb, J.; Li, J.; George, D.; Cabezas-Cruz, A.; Sparagano, O. The Symbiotic Continuum Within Ticks: Opportunities for Disease Control. Front. Microbiol. 2022, 13, 854803. [Google Scholar] [CrossRef]
  2. Estrada-Peña, A. Ticks as vectors: Taxonomy, biology and ecology. Rev. Sci. Tech. 2015, 34, 53–65. [Google Scholar] [CrossRef] [PubMed]
  3. Boulanger, N.; Boyer, P.; Talagrand-Reboul, E.; Hansmann, Y. Ticks and tick-bourne diseases. Med. Mal. Infect. 2019, 49, 87–97. [Google Scholar] [CrossRef] [PubMed]
  4. Duscher, G.G.; Kienberger, S.; Haslinger, K.; Holzer, B.; Zimpernik, I.; Fuchs, R.; Schwarz, M.; Hufnagl, P.; Schiefer, P.; Schmoll, F. Hyalomma spp. in Austria-The Tick, the Climate, the Diseases and the Risk for Humans and Animals. Microorganisms 2022, 10, 1761. [Google Scholar] [CrossRef] [PubMed]
  5. Narasimhan, S.; Swei, A.; Abouneameh, S.; Pal, U.; Pedra, J.H.F.; Fikrig, E. Grappling with the tick microbiome. Trends Parasitol. 2021, 37, 722–733. [Google Scholar] [CrossRef] [PubMed]
  6. Medialdea-Carrera, R.; Melillo, T.; Micaleff, C.; Borg, M.L. Detection of Hyalomma rufipes in a recently arrived asylum seeker to the EU. Ticks Tick Borne Dis. 2021, 12, 101571. [Google Scholar] [CrossRef] [PubMed]
  7. Fernández-Ruiz, N.; Estrada-Peña, A. Towards New Horizons: Climate Trends in Europe Increase the Environmental Suitability for Permanent Populations of Hyalomma marginatum (Ixodidae). Pathogens 2021, 10, 95. [Google Scholar] [CrossRef]
  8. Buczek, A.M.; Buczek, W.; Buczek, A.; Bartosik, K. The Potential Role of Migratory Birds in the Rapid Spread of Ticks and Tick-Borne Pathogens in the Changing Climatic and Environmental Conditions in Europe. Int. J. Environ. Res. Public Health 2020, 17, 2117. [Google Scholar] [CrossRef] [PubMed]
  9. Hoffman, T.; Carra, L.G.; Öhagen, P.; Fransson, T.; Barboutis, C.; Piacentini, D.; Figuerola, J.; Kiat, Y.; Onrubia, A.; Jaenson, T.G.; et al. Association between guilds of birds in the African-Western Palaearctic region and the tick species Hyalomma rufipes, one of the main vectors of Crimean-Congo hemorrhagic fever virus. One Health 2021, 13, 100349. [Google Scholar] [CrossRef] [PubMed]
  10. Hornok, S.; Horváth, G. First report of adult Hyalomma marginatum rufipes (vector of Crimean-Congo haemorrhagic fever virus) on cattle under a continental climate in Hungary. Parasites Vectors 2012, 5, 170. [Google Scholar] [CrossRef]
  11. Földvári, G.; Szabó, É.; Tóth, G.E.; Lanszki, Z.; Zana, B.; Varga, Z.; Kemenesi, G. Emergence of Hyalomma marginatum and Hyalomma rufipes adults revealed by citizen science tick monitoring in Hungary. Transbound. Emerg. Dis. 2022, 69, e2240–e2248. [Google Scholar] [CrossRef] [PubMed]
  12. Uiterwijk, M.; Ibáñez-Justicia, A.; van de Vossenberg, B.; Jacobs, F.; Overgaauw, P.; Nijsse, R.; Dabekaussen, C.; Stroo, A.; Sprong, H. Imported Hyalomma ticks in the Netherlands 2018–2020. Parasites Vectors 2021, 14, 244. [Google Scholar] [CrossRef] [PubMed]
  13. Rubel, F.; Dautel, H.; Nijhof, A.M.; Kahl, O. Ticks in the metropolitan area of Berlin, Germany. Ticks Tick Borne Dis. 2022, 13, 102029. [Google Scholar] [CrossRef]
  14. Grech-Angelini, S.; Stachurski, F.; Lancelot, R.; Boissier, J.; Allienne, J.F.; Gharbi, M.; Uilenberg, G. First report of the tick Hyalomma scupense (natural vector of bovine tropical theileriosis) on the French Mediterranean island of Corsica. Vet. Parasitol. 2016, 216, 33–37. [Google Scholar] [CrossRef]
  15. Hansford, K.M.; Carter, D.; Gillingham, E.L.; Hernandez-Triana, L.M.; Chamberlain, J.; Cull, B.; McGinley, L.; Paul Phipps, L.; Medlock, J.M. Hyalomma rufipes on an untraveled horse: Is this the first evidence of Hyalomma nymphs successfully moulting in the United Kingdom? Ticks Tick Borne Dis. 2019, 10, 704–708. [Google Scholar] [CrossRef]
  16. McGinley, L.; Hansford, K.M.; Cull, B.; Gillingham, E.L.; Carter, D.P.; Chamberlain, J.F.; Hernandez-Triana, L.M.; Phipps, L.P.; Medlock, J.M. First report of human exposure to Hyalomma marginatum in England: Further evidence of a Hyalomma moulting event in north-western Europe? Ticks Tick Borne Dis. 2021, 12, 101541. [Google Scholar] [CrossRef] [PubMed]
  17. Jiménez-Morillas, F.; Gil-Mosquera, M.; García-Lamberechts, E.J. INFURG-SEMES tropical diseases department. Fever in travellers returning from the tropics. Med. Clin. 2019, 153, 205–212. [Google Scholar] [CrossRef] [PubMed]
  18. Palomar, A.M.; Portillo, A.; Santibáñez, S.; García-Álvarez, L.; Muñoz-Sanz, A.; Márquez, F.J.; Romero, L.; Eiros, J.M.; Oteo, J.A. Molecular (ticks) and serological (humans) study of Crimean-Congo hemorrhagic fever virus in the Iberian Peninsula, 2013–2015. Enferm. Infecc. Y Microbiol. Clin. 2017, 35, 344–347. [Google Scholar] [CrossRef]
  19. Kumar, B.; Manjunathachar, H.V.; Ghosh, S. A review on Hyalomma species infestations on human and animals and progress on management strategies. Heliyon 2020, 6, e05675. [Google Scholar] [CrossRef]
  20. Sajid, M.S.; Kausar, A.; Iqbal, A.; Abbas, H.; Iqbal, Z.; Jones, M.K. An insight into the ecobiology, vector significance and control of Hyalomma ticks (Acari: Ixodidae): A review. Acta Trop. 2018, 187, 229–239. [Google Scholar] [CrossRef]
  21. Kar, S.; Rodriguez, S.E.; Akyildiz, G.; Cajimat, M.N.B.; Bircan, R.; Mears, M.C.; Bente, D.A.; Keles, A.G. Crimean-Congo hemorrhagic fever virus in tortoises and Hyalomma aegyptium ticks in East Thrace, Turkey: Potential of a cryptic transmission cycle. Parasit Vectors 2020, 13, 201. [Google Scholar] [CrossRef]
  22. Barradas, P.F.; Lima, C.; Cardoso, L.; Amorim, I.; Gärtner, F.; Mesquita, J.R. Molecular Evidence of Hemolivia mauritanica, Ehrlichia spp. and the Endosymbiont Candidatus Midichloria Mitochondrii in Hyalomma aegyptium Infesting Testudo graeca Tortoises from Doha, Qatar. Animals 2020, 11, 30. [Google Scholar] [CrossRef]
  23. Apanaskevich, D.A.; Santos-Silva, M.M.; Horak, I.G.B. The genus Hyalomma Koch, 1844. IV. Redescription of all parasitic stages of H. (Euhyalomma) lusitanicum Koch, 1844 and the adults of H. (E.) franchinii Tonelli Rondelli, 1932 (acari: Ixodidae) with a first description of its immature stages. Folia Parasitol. 2008, 55, 61–74. [Google Scholar] [CrossRef]
  24. Tomassone, L.; Camicas, J.L.; De Meneghi, D.; Di Giulio, A.; Uilenberg, G. A note on Hyalomma nitidum, its distribution and its hosts. Exp. Appl. Acarol. 2005, 35, 341–355. [Google Scholar] [CrossRef]
  25. Miranpuri, G.S. Ticks parasitising the Indian buffalo (Bubalus bubalis) and their possible role in disease transmission. Vet. Parasitol. 1988, 27, 357–362. [Google Scholar] [CrossRef] [PubMed]
  26. Perveen, N.; Muzaffar, S.B.; Vijayan, R.; Al-Deeb, M.A. Microbial composition in Hyalomma anatolicum collected from livestock in the United Arab Emirates using next-generation sequencing. Parasites Vectors 2022, 15, 30. [Google Scholar] [CrossRef]
  27. Al-Khalifa, M.S.; Al-Asgah, N.A.; Diab, F.M. Hyalomma (Hyalommina) arabica, the Arabian goat and sheep tick) distribution and abundance in Saudi Arabia. J. Med. Entomol. 1986, 23, 220–221. [Google Scholar] [CrossRef] [PubMed]
  28. Flach, E.J.; Ouhelli, H.; Waddington, D.; el Hasnaoui, M. Prevalence of Theileria in the tick Hyalomma detritum detritum in the Doukkala region, Morocco. Med. Vet. Entomol. 1993, 7, 343–350. [Google Scholar] [CrossRef]
  29. Abdullah, H.H.A.M.; El-Shanawany, E.E.; Abdel-Shafy, S.; Abou-Zeina, H.A.A.; Abdel-Rahman, E.H. Molecular and immunological characterization of Hyalomma dromedarii and Hyalomma excavatum (Acari: Ixodidae) vectors of Q fever in camels. Vet. World 2018, 11, 1109–1119. [Google Scholar] [CrossRef] [PubMed]
  30. Apanaskevich, D.A.; Horak, I.G. The genus Hyalomma Koch, 1844. IX. Redescription of all parasitic stages of H. (Euhyalomma) impeltatum Schulze & Schlottke, 1930 and H. (E.) somalicum Tonelli Rondelli, 1935 (Acari: Ixodidae). Syst. Parasitol. 2009, 73, 199–218. [Google Scholar] [CrossRef]
  31. El-Azazy, O.M.; El-Metenawy, T.M.; Wassef, H.Y. Hyalomma impeltatum (Acari: Ixodidae) as a potential vector of malignant theileriosis in sheep in Saudi Arabia. Vet. Parasitol. 2001, 99, 305–309. [Google Scholar] [CrossRef] [PubMed]
  32. Pegram, R.G.; Hoogstraal, H.; Wassef, H.Y. Hyalomma (Hyalommina) arabica sp. n. parasitizing goats and sheep in the Yemen Arab Republic and Saudi Arabia. J. Parasitol. 1982, 68, 150–156. [Google Scholar] [CrossRef]
  33. Vieira Lista, M.C.; Belhassen-García, M.; Vicente Santiago, M.B.; Sánchez-Montejo, J.; Pedroza Pérez, C.; Monsalve Arteaga, L.C.; Herrador, Z.; Del Álamo-Sanz, R.; Benito, A.; Soto López, J.D.; et al. Identification and Distribution of Human-Biting Ticks in Northwestern Spain. Insects 2022, 13, 469. [Google Scholar] [CrossRef]
  34. Díaz-Sánchez, S.; Fernández, A.M.; Habela, M.A.; Calero-Bernal, R.; de Mera, I.G.F.; de la Fuente, J. Microbial community of Hyalomma lusitanicum is dominated by Francisella-like endosymbiont. Ticks Tick Borne Dis. 2021, 12, 101624. [Google Scholar] [CrossRef] [PubMed]
  35. Grandi, G.; Chitimia-Dobler, L.; Choklikitumnuey, P.; Strube, C.; Springer, A.; Albihn, A.; Jaenson, T.G.T.; Omazic, A. First records of adult Hyalomma marginatum and H. rufipes ticks (Acari: Ixodidae) in Sweden. Ticks Tick Borne Dis. 2020, 11, 101403. [Google Scholar] [CrossRef]
  36. Lesiczka, P.M.; Daněk, O.; Modrý, D.; Hrazdilová, K.; Votýpka, J.; Zurek, L. A new report of adult Hyalomma marginatum and Hyalomma rufipes in the Czech Republic. Ticks Tick Borne Dis. 2022, 13, 101894. [Google Scholar] [CrossRef]
  37. Diab, F.M.; Hoogstraal, H.; Wassef, H.Y.; Al Khalifa, M.S.; Al Asgah, N.A. Hyalomma (Hyalommina) arabica: Nymphal and larval identity and spiny mouse hosts in Saudi Arabia (Acarina: Ixodoidea: Ixodidae). J. Parasitol. 1985, 71, 630–634. [Google Scholar] [CrossRef] [PubMed]
  38. Dipeolu, O.O.; Amoo, A. The presence of kinetes of a Babesia species in the haemolymph smears of engorged Hyalomma ticks in Nigeria. Vet. Parasitol. 1984, 17, 41–46. [Google Scholar] [CrossRef]
  39. Choubdar, N.; Karimian, F.; Koosha, M.; Nejati, J.; Oshaghi, M.A. Hyalomma spp. ticks and associated Anaplasma spp. and Ehrlichia spp. on the Iran-Pakistan border. Parasit Vectors 2021, 14, 469. [Google Scholar] [CrossRef]
  40. Gharbi, M.; Darghouth, M.A. A review of Hyalomma scupense (Acari, Ixodidae) in the Maghreb region: From biology to control. Parasite 2014, 21, 2. [Google Scholar] [CrossRef]
  41. Gharbi, M.; Darghouth, M.A.; Elati, K.; Al-Hosary, A.A.T.; Ayadi, O.; Salih, D.A.; El Hussein, A.M.; Mhadhbi, M.; Khamassi Khbou, M.; Hassan, S.M.; et al. Current status of tropical theileriosis in Northern Africa: A review of recent epidemiological investigations and implications for control. Transbound. Emerg. Dis. 2020, 67, 8–25. [Google Scholar] [CrossRef] [PubMed]
  42. Gonzalez, J.P.; Camicas, J.L.; Cornet, J.P.; Faye, O.; Wilson, M.L. Sexual and transovarian transmission of Crimean-Congo haemorrhagic fever virus in Hyalomma truncatum ticks. Res. Virol. 1992, 143, 23–28. [Google Scholar] [CrossRef]
  43. Morrison, W.I. The aetiology, pathogenesis and control of theileriosis in domestic animals. Rev. Sci. Tech. 2015, 34, 599–611. [Google Scholar] [CrossRef]
  44. Galaï, Y.; Canales, M.; Ben Saïd, M.; Gharbi, M.; Mhadhbi, M.; Jedidi, M.; de La Fuente, J.; Darghouth, M.A. Efficacy of Hyalomma scupense (Hd86) antigen against Hyalomma excavatum and H. scupense tick infestations in cattle. Vaccine 2012, 30, 7084–7089. [Google Scholar] [CrossRef]
  45. Yin, H.; Luo, J.; Lu, W. Control of tropical theileriosis with attenuated schizont vaccine in China. Vaccine 2008, 26, G11–G13. [Google Scholar] [CrossRef] [PubMed]
  46. Narasimhan, S.; Fikrig, E. Tick microbiome: The force within. Trends Parasitol. 2015, 31, 315–323. [Google Scholar] [CrossRef] [PubMed]
  47. Andreotti, R.; Pérez de León, A.A.; Dowd, S.E.; Guerrero, F.D.; Bendele, K.G.; Scoles, G.A. Assessment of bacterial diversity in the cattle tick Rhipicephalus (Boophilus) microplus through tag-encoded pyrosequencing. BMC Microbiol. 2011, 11, 6. [Google Scholar] [CrossRef]
  48. Wu-Chuang, A.; Hodžić, A.; Mateos-Hernández, L.; Estrada-Peña, A.; Obregon, D.; Cabezas-Cruz, A. Current debates and advances in tick microbiome research. Curr. Res. Parasitol. Vector-Borne Dis. 2021, 1, 100036. [Google Scholar] [CrossRef]
  49. Dennison, N.J.; Jupatanakul, N.; Dimopoulos, G. The mosquito microbiota influences vector competence for human pathogens. Curr. Opin. Insect. Sci. 2014, 3, 6–13. [Google Scholar] [CrossRef]
  50. Bonnet, S.I.; Pollet, T. Update on the intricate tango between tick microbiomes and tick-borne pathogens. Parasite Immunol. 2021, 43, e12813. [Google Scholar] [CrossRef]
  51. Bright, M.; Bulgheresi, S. A complex journey: Transmission of microbial symbionts. Nat. Rev. Microbiol. 2010, 8, 218–230. [Google Scholar] [CrossRef] [PubMed]
  52. Bazzocchi, C.; Mariconti, M.; Sassera, D.; Rinaldi, L.; Martin, E.; Cringoli, G.; Urbanelli, S.; Genchi, C.; Bandi, C.; Epis, S. Molecular and serological evidence for the circulation of the tick symbiont Midichloria (Rickettsiales: Midichloriaceae) in different mammalian species. Parasit Vectors. 2013, 6, 350. [Google Scholar] [CrossRef]
  53. Kobayashi, T.; Chatanga, E.; Qiu, Y.; Simuunza, M.; Kajihara, M.; Hang’ombe, B.M.; Eto, Y.; Saasa, N.; Mori-Kajihara, A.; Simulundu, E.; et al. Molecular Detection and Genotyping of Coxiella-like Endosymbionts in Ticks Collected from Animals and Vegetation in Zambia. Pathogens 2021, 10, 779. [Google Scholar] [CrossRef]
  54. Edouard, S.; Subramanian, G.; Lefevre, B.; Dos Santos, A.; Pouedras, P.; Poinsignon, Y.; Mediannikov, O.; Raoult, D. Co-infection with Arsenophonus nasoniae and Orientia tsutsugamushi in a traveler. Vector Borne Zoonotic Dis. 2013, 13, 565–571. [Google Scholar] [CrossRef] [PubMed]
  55. Obregón, D.; Bard, E.; Abrial, D.; Estrada-Peña, A.; Cabezas-Cruz, A. Sex-Specific Linkages Between Taxonomic and Functional Profiles of Tick Gut Microbiomes. Front. Cell Infect. Microbiol. 2019, 9, 298. [Google Scholar] [CrossRef] [PubMed]
  56. Douglas, A.E. Symbiotic microorganisms: Untapped resources for insect pest control. Trends Biotechnol. 2007, 25, 338–342. [Google Scholar] [CrossRef]
  57. Zhong, Z.; Zhong, T.; Peng, Y.; Zhou, X.; Wang, Z.; Tang, H.; Wang, J. Symbiont-regulated serotonin biosynthesis modulates tick feeding activity. Cell Host Microbe. 2021, 29, 1545–1557.e4. [Google Scholar] [CrossRef]
  58. Zhong, J.; Jasinskas, A.; Barbour, A.G. Antibiotic treatment of the tick vector Amblyomma americanum reduced reproductive fitness. PLoS ONE 2007, 2, e405. [Google Scholar] [CrossRef]
  59. Duron, O.; Morel, O.; Noël, V.; Buysse, M.; Binetruy, F.; Lancelot, R.; Loire, E.; Ménard, C.; Bouchez, O.; Vavre, F.; et al. Tick-Bacteria Mutualism Depends on B Vitamin Synthesis Pathways. Curr. Biol. 2018, 28, 1896–1902.e5. [Google Scholar] [CrossRef]
  60. Sazama, E.J.; Ouellette, S.P.; Wesner, J.S. Bacterial Endosymbionts Are Common Among, but not Necessarily Within, Insect Species. Environ. Entomol. 2019, 48, 127–133. [Google Scholar] [CrossRef]
  61. Olivieri, E.; Epis, S.; Castelli, M.; Varotto Boccazzi, I.; Romeo, C.; Desirò, A.; Bazzocchi, C.; Bandi, C.; Sassera, D. Tissue tropism and metabolic pathways of Midichloria mitochondrii suggest tissue-specific functions in the symbiosis with Ixodes ricinus. Ticks Tick Borne Dis. 2019, 10, 1070–1077. [Google Scholar] [CrossRef] [PubMed]
  62. Azagi, T.; Klement, E.; Perlman, G.; Lustig, Y.; Mumcuoglu, K.Y.; Apanaskevich, D.A.; Gottlieb, Y. Francisella-like Endosymbionts and Rickettsia Species in Local and Imported Hyalomma Ticks. Appl. Environ. Microbiol. 2017, 83, e01302–e01317. [Google Scholar] [CrossRef] [PubMed]
  63. Larson, M.A.; Sayood, K.; Bartling, A.M.; Meyer, J.R.; Starr, C.; Baldwin, J.; Dempsey, M.P. Differentiation of Francisella tularensis Subspecies and Subtypes. J. Clin. Microbiol. 2020, 58, e01495-19. [Google Scholar] [CrossRef]
  64. Calhoun, E.L.; Alford, H.I. Incidence of tularemia and Rocky Mountain spotted fever among common ticks of Arkansas. Am. J. Trop. Med. Hyg. 1955, 4, 310–317. [Google Scholar] [CrossRef]
  65. Niebylski, M.L.; Peacock, M.G.; Fischer, E.R.; Porcella, S.F.; Schwan, T.G. Characterization of an endosymbiont infecting wood ticks, Dermacentor andersoni, as a member of the genus Francisella. Appl. Environ. Microbiol. 1997, 63, 3933–3940. [Google Scholar] [CrossRef] [PubMed]
  66. Yeni, D.K.; Büyük, F.; Ashraf, A.; Shah, M.S.U.D. Tularemia: A re-emerging tick-borne infectious disease. Folia Microbiol. 2021, 66, 1–14. [Google Scholar] [CrossRef] [PubMed]
  67. Goethert, H.K.; Telford, S.R., 3rd. A new Francisella (Beggiatiales: Francisellaceae) inquiline within Dermacentor variabilis say (Acari: Ixodidae). J. Med. Entomol. 2005, 42, 502–505. [Google Scholar] [CrossRef]
  68. Petersen, J.M.; Mead, P.S.; Schriefer, M.E. Francisella tularensis: An arthropod-borne pathogen. Vet. Res. 2009, 40, 7. [Google Scholar] [CrossRef]
  69. Keim, P.; Johansson, A.; Wagner, D.M. Molecular epidemiology, evolution, and ecology of Francisella. Ann. NY Acad. Sci. 2007, 1105, 30–66. [Google Scholar] [CrossRef]
  70. Bonnet, S.I.; Binetruy, F.; Hernández-Jarguín, A.M.; Duron, O. The Tick Microbiome: Why Non-pathogenic Microorganisms Matter in Tick Biology and Pathogen Transmission. Front. Cell Infect. Microbiol. 2017, 7, 236. [Google Scholar] [CrossRef]
  71. Guizzo, M.G.; Parizi, L.F.; Nunes, R.D.; Schama, R.; Albano, R.M.; Tirloni, L.; Oldiges, D.P.; Vieira, R.P.; Oliveira, W.H.C.; Leite, M.S.; et al. A Coxiella mutualist symbiont is essential to the development of Rhipicephalus microplus. Sci. Rep. 2017, 7, 17554. [Google Scholar] [CrossRef] [PubMed]
  72. Oliver, K.M.; Degnan, P.H.; Burke, G.R.; Moran, N.A. Facultative symbionts in aphids and the horizontal transfer of ecologically important traits. Annu. Rev. Entomol. 2010, 55, 247–266. [Google Scholar] [CrossRef] [PubMed]
  73. Špitalská, E.; Sparagano, O.; Stanko, M.; Schwarzová, K.; Špitalský, Z.; Škultéty, Ľ.; Havlíková, S.F. Diversity of Coxiella-like and Francisella-like endosymbionts, and Rickettsia spp., Coxiella burnetii as pathogens in the tick populations of Slovakia, Central Europe. Ticks Tick Borne Dis. 2018, 9, 1207–1211. [Google Scholar] [CrossRef] [PubMed]
  74. Chisu, V.; Foxi, C.; Masala, G. First molecular detection of Francisella-like endosymbionts in Hyalomma and Rhipicephalus tick species collected from vertebrate hosts from Sardinia island, Italy. Exp. Appl. Acarol. 2019, 79, 245–254. [Google Scholar] [CrossRef] [PubMed]
  75. Gerhart, J.G.; Moses, A.S.; Raghavan, R. A Francisella-like endosymbiont in the Gulf Coast tick evolved from a mammalian pathogen. Sci. Rep. 2016, 6, 33670. [Google Scholar] [CrossRef]
  76. Gerhart, J.G.; Auguste Dutcher, H.; Brenner, A.E.; Moses, A.S.; Grubhoffer, L.; Raghavan, R. Multiple Acquisitions of Pathogen-Derived Francisella Endosymbionts in Soft Ticks. Genome Biol. Evol. 2018, 10, 607–615. [Google Scholar] [CrossRef]
  77. Rakthong, P.; Ruang-Areerate, T.; Baimai, V.; Trinachartvanit, W.; Ahantarig, A. Francisella-like endosymbiont in a tick collected from a chicken in southern Thailand. Southeast Asian J. Trop. Med. Public Health 2016, 47, 245–249. [Google Scholar]
  78. Ivanov, I.N.; Mitkova, N.; Reye, A.L.; Hübschen, J.M.; Vatcheva-Dobrevska, R.S.; Dobreva, E.G.; Kantardjiev, T.V.; Muller, C.P. Detection of new Francisella-like tick endosymbionts in Hyalomma spp. and Rhipicephalus spp. (Acari: Ixodidae) from Bulgaria. Appl. Environ. Microbiol. 2011, 77, 5562–5565. [Google Scholar] [CrossRef]
  79. Hensley, J.R.; Zambrano, M.L.; Williams-Newkirk, A.J.; Dasch, G.A. Detection of Rickettsia Species, and Coxiella-like and Francisella-like Endosymbionts in Amblyomma americanum and Amblyomma maculatum from a Shared Field Site in Georgia, United States of America. Vector Borne Zoonotic Dis. 2021, 21, 509–516. [Google Scholar] [CrossRef]
  80. Kreizinger, Z.; Hornok, S.; Dán, A.; Hresko, S.; Makrai, L.; Magyar, T.; Bhide, M.; Erdélyi, K.; Hofmann-Lehmann, R.; Gyuranecz, M. Prevalence of Francisella tularensis and Francisella-like endosymbionts in the tick population of Hungary and the genetic variability of Francisella-like agents. Vector Borne Zoonotic Dis. 2013, 13, 160–163. [Google Scholar] [CrossRef]
  81. Elbir, H.; Almathen, F.; Elnahas, A. Low genetic diversity among Francisella-like endosymbionts within different genotypes of Hyalomma dromedarii ticks infesting camels in Saudi Arabia. Vet. World 2020, 13, 1462–1472. [Google Scholar] [CrossRef]
  82. Wang, Y.; Mao, L.; Sun, Y.; Wang, Z.; Zhang, J.; Zhang, J.; Peng, Y.; Xia, L. A Novel Francisella-like Endosymbiont in Haemaphysalis longicornis and Hyalomma asiaticum, China. Vector Borne Zoonotic Dis. 2018, 18, 669–676. [Google Scholar] [CrossRef]
  83. Scoles, G.A. Phylogenetic analysis of the Francisella-like endosymbionts of Dermacentor ticks. J. Med. Entomol. 2004, 41, 277–286. [Google Scholar] [CrossRef] [PubMed]
  84. Kaufman, E.L.; Stone, N.E.; Scoles, G.A.; Hepp, C.M.; Busch, J.D.; Wagner, D.M. Range-wide genetic analysis of Dermacentor variabilis and its Francisella-like endosymbionts demonstrates phylogeographic concordance between both taxa. Parasit Vectors 2018, 11, 306. [Google Scholar] [CrossRef] [PubMed]
  85. Michelet, L.; Bonnet, S.; Madani, N.; Moutailler, S. Discriminating Francisella tularensis and Francisella-like endosymbionts in Dermacentor reticulatus ticks: Evaluation of current molecular techniques. Vet. Microbiol. 2013, 163, 399–403. [Google Scholar] [CrossRef]
  86. Szigeti, A.; Kreizinger, Z.; Hornok, S.; Abichu, G.; Gyuranecz, M. Detection of Francisella-like endosymbiont in Hyalomma rufipes from Ethiopia. Ticks Tick Borne Dis. 2014, 5, 818–820. [Google Scholar] [CrossRef]
  87. De Carvalho, I.L.; Santos, N.; Soares, T.; Zé-Zé, L.; Núncio, M.S. Francisella-like endosymbiont in Dermacentor reticulatus collected in Portugal. Vector Borne Zoonotic Dis. 2011, 11, 185–188. [Google Scholar] [CrossRef]
  88. Sumrandee, C.; Hirunkanokpun, S.; Grubhoffer, L.; Baimai, V.; Trinachartvanit, W.; Ahantarig, A. Phylogenetic relationships of Francisella-like endosymbionts detected in two species of Amblyomma from snakes in Thailand. Ticks Tick Borne Dis. 2014, 5, 29–32. [Google Scholar] [CrossRef] [PubMed]
  89. Machado-Ferreira, E.; Piesman, J.; Zeidner, N.S.; Soares, C.A. Francisella-like endosymbiont DNA and Francisella tularensis virulence-related genes in Brazilian ticks (Acari: Ixodidae). J. Med. Entomol. 2009, 46, 369–374. [Google Scholar] [CrossRef] [PubMed]
  90. Dergousoff, S.J.; Chilton, N.B. Association of different genetic types of Francisella-like organisms with the rocky mountain wood tick (Dermacentor andersoni) and the American dog tick (Dermacentor variabilis) in localities near their northern distributional limits. Appl. Environ. Microbiol. 2012, 78, 965–971. [Google Scholar] [CrossRef]
  91. Takhampunya, R.; Kim, H.C.; Chong, S.T.; Korkusol, A.; Tippayachai, B.; Davidson, S.A.; Petersen, J.M.; Klein, T.A. Francisella-like Endosymbiont Detected in Haemaphysalis Ticks (Acari: Ixodidae) From the Republic of Korea. J. Med. Entomol. 2017, 54, 1735–1742. [Google Scholar] [CrossRef]
  92. Kumar, D.; Sharma, S.R.; Adegoke, A.; Kennedy, A.; Tuten, H.C.; Li, A.Y.; Karim, S. Recently Evolved Francisella-like Endosymbiont Outcompetes an Ancient and Evolutionarily Associated Coxiella-like Endosymbiont in the Lone Star Tick (Amblyomma americanum) Linked to the Alpha-Gal Syndrome. Front. Cell Infect. Microbiol. 2022, 12, 787209. [Google Scholar] [CrossRef] [PubMed]
  93. Garcia-Vozmediano, A.; Giglio, G.; Ramassa, E.; Nobili, F.; Rossi, L.; Tomassone, L. Dermacentor marginatus and Dermacentor reticulatus, and Their Infection by SFG Rickettsiae and Francisella-like Endosymbionts, in Mountain and Periurban Habitats of Northwestern Italy. Vet Sci. 2020, 7, 157. [Google Scholar] [CrossRef]
  94. Liu, J.N.; Yu, Z.J.; Liu, L.M.; Li, N.X.; Wang, R.R.; Zhang, C.M.; Liu, J.Z. Identification, Distribution and Population Dynamics of Francisella-like Endosymbiont in Haemaphysalis doenitzi (Acari: Ixodidae). Sci. Rep. 2016, 6, 35178. [Google Scholar] [CrossRef] [PubMed]
  95. Baldridge, G.D.; Scoles, G.A.; Burkhardt, N.Y.; Schloeder, B.; Kurtti, T.J.; Munderloh, U.G. Transovarial transmission of Francisella-like endosymbionts and Anaplasma phagocytophilum variants in Dermacentor albipictus (Acari: Ixodidae). J. Med. Entomol. 2009, 46, 625–632. [Google Scholar] [CrossRef] [PubMed]
  96. Lopes de Carvalho, I.; Toledo, A.; Carvalho, C.L.; Barandika, J.F.; Respicio-Kingry, L.B.; Garcia-Amil, C.; García-Pérez, A.L.; Olmeda, A.S.; Zé-Zé, L.; Petersen, J.M.; et al. Francisella species in ticks and animals, Iberian Peninsula. Ticks Tick Borne Dis. 2016, 7, 159–165. [Google Scholar] [CrossRef] [PubMed]
  97. Ghafar, A.; Cabezas-Cruz, A.; Galon, C.; Obregon, D.; Gasser, R.B.; Moutailler, S.; Jabbar, A. Bovine ticks harbour a diverse array of microorganisms in Pakistan. Parasit Vectors 2020, 13, 1. [Google Scholar] [CrossRef]
  98. Sperling, J.; MacDonald, Z.; Normandeau, J.; Merrill, E.; Sperling, F.; Magor, K. Within-population diversity of bacterial microbiomes in winter ticks (Dermacentor albipictus). Ticks Tick Borne Dis. 2020, 11, 101535. [Google Scholar] [CrossRef]
  99. Ghoneim, N.H.; Abdel-Moein, K.A.; Zaher, H.M. Molecular Detection of Francisella spp. Among Ticks Attached to Camels in Egypt. Vector Borne Zoonotic Dis. 2017, 17, 384–387. [Google Scholar] [CrossRef]
  100. Hoffman, T.; Sjödin, A.; Öhrman, C.; Karlsson, L.; McDonough, R.F.; Sahl, J.W.; Birdsell, D.; Wagner, D.M.; Carra, L.G.; Wilhelmsson, P.; et al. Co-Occurrence of Francisella, Spotted Fever Group Rickettsia, and Midichloria in Avian-Associated Hyalomma rufipes. Microorganisms 2022, 10, 1393. [Google Scholar] [CrossRef]
  101. Boularias, G.; Azzag, N.; Galon, C.; Šimo, L.; Boulouis, H.J.; Moutailler, S. High-Throughput Microfluidic Real-Time PCR for the Detection of Multiple Microorganisms in Ixodid Cattle Ticks in Northeast Algeria. Pathogens 2021, 10, 362. [Google Scholar] [CrossRef]
  102. Gioia, G.V.; Vinueza, R.L.; Marsot, M.; Devillers, E.; Cruz, M.; Petit, E.; Boulouis, H.J.; Moutailler, S.; Monroy, F.; Coello, M.A.; et al. Bovine anaplasmosis and tick-borne pathogens in cattle of the Galapagos Islands. Transbound. Emerg. Dis. 2018, 65, 1262–1271. [Google Scholar] [CrossRef] [PubMed]
  103. Rollins, R.E.; Schaper, S.; Kahlhofer, C.; Frangoulidis, D.; Strauß, A.F.T.; Cardinale, M.; Springer, A.; Strube, C.; Bakkes, D.K.; Becker, N.S.; et al. Ticks (Acari: Ixodidae) on birds migrating to the island of Ponza, Italy, and the tick-borne pathogens they carry. Ticks Tick Borne Dis. 2021, 12, 101590. [Google Scholar] [CrossRef] [PubMed]
  104. Michelet, L.; Joncour, G.; Devillers, E.; Torina, A.; Vayssier-Taussat, M.; Bonnet, S.I.; Moutailler, S. Tick species, tick-borne pathogens and symbionts in an insular environment off the coast of Western France. Ticks Tick Borne Dis. 2016, 7, 1109–1115. [Google Scholar] [CrossRef] [PubMed]
  105. Varela-Stokes, A.S.; Park, S.H.; Stokes, J.V.; Gavron, N.A.; Lee, S.I.; Moraru, G.M.; Ricke, S.C. Tick microbial communities within enriched extracts of Amblyomma maculatum. Ticks Tick Borne Dis. 2018, 9, 798–805. [Google Scholar] [CrossRef]
  106. Ravi, A.; Ereqat, S.; Al-Jawabreh, A.; Abdeen, Z.; Abu Shamma, O.; Hall, H.; Pallen, M.J.; Nasereddin, A. Metagenomic profiling of ticks: Identification of novel rickettsial genomes and detection of tick-borne canine parvovirus. PLOS Negl. Trop. Dis. 2019, 13, e0006805. [Google Scholar] [CrossRef]
  107. Brinkmann, A.; Hekimoğlu, O.; Dinçer, E.; Hagedorn, P.; Nitsche, A.; Ergünay, K. A cross-sectional screening by next-generation sequencing reveals Rickettsia, Coxiella, Francisella, Borrelia, Babesia, Theileria and Hemolivia species in ticks from Anatolia. Parasit Vectors 2019, 12, 26. [Google Scholar] [CrossRef]
  108. Budachetri, K.; Kumar, D.; Crispell, G.; Beck, C.; Dasch, G.; Karim, S. The tick endosymbiont Candidatus Midichloria mitochondrii and selenoproteins are essential for the growth of Rickettsia parkeri in the Gulf Coast tick vector. Microbiome 2018, 6, 141. [Google Scholar] [CrossRef]
  109. Banović, P.; Díaz-Sánchez, A.A.; Galon, C.; Simin, V.; Mijatović, D.; Obregón, D.; Moutailler, S.; Cabezas-Cruz, A. Humans infested with Ixodes ricinus are exposed to a diverse array of tick-borne pathogens in Serbia. Ticks Tick Borne Dis. 2021, 12, 101609. [Google Scholar] [CrossRef]
  110. Tomanović, S.; Chochlakis, D.; Radulović, Z.; Milutinović, M.; Cakić, S.; Mihaljica, D.; Tselentis, Y.; Psaroulaki, A. Analysis of pathogen co-occurrence in host-seeking adult hard ticks from Serbia. Exp. Appl. Acarol. 2013, 59, 367–376. [Google Scholar] [CrossRef]
  111. Sprong, H.; Fonville, M.; Docters van Leeuwen, A.; Devillers, E.; Ibañez-Justicia, A.; Stroo, A.; Hansford, K.; Cull, B.; Medlock, J.; Heyman, P.; et al. Detection of pathogens in Dermacentor reticulatus in northwestern Europe: Evaluation of a high-throughput array. Heliyon 2019, 5, e01270. [Google Scholar] [CrossRef]
  112. Mofokeng, L.S.; Smit, N.J.; Cook, C.A. Molecular Detection of Tick-Borne Bacteria from Amblyomma (Acari: Ixodidae) Ticks Collected from Reptiles in South Africa. Microorganisms 2022, 10, 1923. [Google Scholar] [CrossRef] [PubMed]
  113. Budachetri, K.; Gaillard, D.; Williams, J.; Mukherjee, N.; Karim, S. A snapshot of the microbiome of Amblyomma tuberculatum ticks infesting the gopher tortoise, an endangered species. Ticks Tick Borne Dis. 2016, 7, 1225–1229. [Google Scholar] [CrossRef]
  114. Gehringer, H.; Schacht, E.; Maylaender, N.; Zeman, E.; Kaysser, P.; Oehme, R.; Pluta, S.; Splettstoesser, W.D. Presence of an emerging subclone of Francisella tularensis holarctica in Ixodes ricinus ticks from south-western Germany. Ticks Tick Borne Dis. 2013, 4, 93–100. [Google Scholar] [CrossRef]
  115. Dergousoff, S.J.; Anstead, C.A.; Chilton, N.B. Identification of bacteria in the Rocky Mountain wood tick, Dermacentor andersoni, using single-strand conformation polymorphism (SSCP) and DNA sequencing. Exp. Appl. Acarol. 2020, 80, 247–256. [Google Scholar] [CrossRef] [PubMed]
  116. Gurfield, N.; Grewal, S.; Cua, L.S.; Torres, P.J.; Kelley, S.T. Endosymbiont interference and microbial diversity of the Pacific coast tick, Dermacentor occidentalis, in San Diego County, California. PeerJ 2017, 5, e3202. [Google Scholar] [CrossRef] [PubMed]
  117. Sjödin, A.; Svensson, K.; Ohrman, C.; Ahlinder, J.; Lindgren, P.; Duodu, S.; Johansson, A.; Colquhoun, D.J.; Larsson, P.; Forsman, M. Genome characterisation of the genus Francisella reveals insight into similar evolutionary paths in pathogens of mammals and fish. BMC Genom. 2012, 13, 268. [Google Scholar] [CrossRef]
  118. Duzlu, O.; Yildirim, A.; Inci, A.; Gumussoy, K.S.; Ciloglu, A.; Onder, Z. Molecular Investigation of Francisella-like Endosymbiont in Ticks and Francisella tularensis in Ixodid Ticks and Mosquitoes in Turkey. Vector Borne Zoonotic Dis. 2016, 16, 26–32. [Google Scholar] [CrossRef] [PubMed]
  119. Buysse, M.; Floriano, A.M.; Gottlieb, Y.; Nardi, T.; Comandatore, F.; Olivieri, E.; Giannetto, A.; Palomar, A.M.; Makepeace, B.L.; Bazzocchi, C.; et al. A dual endosymbiosis supports nutritional adaptation to hematophagy in the invasive tick Hyalomma marginatum. eLife 2021, 10, e72747. [Google Scholar] [CrossRef] [PubMed]
  120. Dennis, D.T.; Inglesby, T.V.; Henderson, D.A.; Bartlett, J.G.; Ascher, M.S.; Eitzen, E.; Fine, A.D.; Friedlander, A.M.; Hauer, J.; Layton, M.; et al. Working Group on Civilian Biodefense. Tularemia as a biological weapon: Medical and public health management. JAMA 2001, 285, 2763–2773. [Google Scholar] [CrossRef]
  121. Rotz, L.D.; Khan, A.S.; Lillibridge, S.R.; Ostroff, S.M.; Hughes, J.M. Public health assessment of potential biological terrorism agents. Emerg. Infect. Dis. 2002, 8, 225–230. [Google Scholar] [CrossRef]
  122. De La Fuente, J.; Kocan, K.M.; Contreras, M. Prevention and control strategies for ticks and pathogen transmission. Rev. Sci. Tech. 2015, 34, 249–264. [Google Scholar] [CrossRef] [PubMed]
  123. Pound, J.M.; George, J.E.; Kammlah, D.M.; Lohmeyer, K.H.; Davey, R.B. Evidence for role of white-tailed deer (Artiodactyla: Cervidae) in epizootiology of cattle ticks and southern cattle ticks (Acari: Ixodidae) in reinfestations along the Texas/Mexico border in south Texas: A review and update. J. Econ. Entomol. 2010, 103, 211–218. [Google Scholar] [CrossRef] [PubMed]
  124. Merino, O.; Almazán, C.; Canales, M.; Villar, M.; Moreno-Cid, J.A.; Estrada-Peña, A.; Kocan, K.M.; de la Fuente, J. Control of Rhipicephalus (Boophilus) microplus infestations by the combination of subolesin vaccination and tick autocidal control after subolesin gene knockdown in ticks fed on cattle. Vaccine 2011, 29, 2248–2254. [Google Scholar] [CrossRef] [PubMed]
  125. Porter, R.; Norman, R.A.; Gilbert, L. An alternative to killing? Treatment of reservoir hosts to control a vector and pathogen in a susceptible species. Parasitology 2013, 140, 247–257. [Google Scholar] [CrossRef] [PubMed]
  126. Aželytė, J.; Wu-Chuang, A.; Žiegytė, R.; Platonova, E.; Mateos-Hernandez, L.; Maye, J.; Obregon, D.; Palinauskas, V.; Cabezas-Cruz, A. Anti-Microbiota Vaccine Reduces Avian Malaria Infection Within Mosquito Vectors. Front. Immunol. 2022, 13, 841835. [Google Scholar] [CrossRef]
  127. Carreón, D.; de la Lastra, J.M.; Almazán, C.; Canales, M.; Ruiz-Fons, F.; Boadella, M.; Moreno-Cid, J.A.; Villar, M.; Gortázar, C.; Reglero, M.; et al. Vaccination with BM86, subolesin and akirin protective antigens for the control of tick infestations in white tailed deer and red deer. Vaccine 2012, 30, 273–279. [Google Scholar] [CrossRef]
  128. Mateos-Hernández, L.; Obregón, D.; Maye, J.; Borneres, J.; Versille, N.; de la Fuente, J.; Estrada-Peña, A.; Hodžić, A.; Šimo, L.; Cabezas-Cruz, A. Anti-Tick Microbiota Vaccine Impacts Ixodes ricinus Performance during Feeding. Vaccines 2020, 8, 702. [Google Scholar] [CrossRef] [PubMed]
  129. Mateos-Hernández, L.; Obregón, D.; Wu-Chuang, A.; Maye, J.; Bornères, J.; Versillé, N.; de la Fuente, J.; Díaz-Sánchez, S.; Bermúdez-Humarán, L.G.; Torres-Maravilla, E.; et al. Anti-Microbiota Vaccines Modulate the Tick Microbiome in a Taxon-Specific Manner. Front. Immunol. 2021, 12, 704621. [Google Scholar] [CrossRef]
  130. Wan Sulaiman, W.A.; Kamtchum-Tatuene, J.; Mohamed, M.H.; Ramachandran, V.; Ching, S.M.; Sazlly Lim, S.M.; Hashim, H.Z.; Inche Mat, L.N.; Hoo, F.K.; Basri, H. Anti-Wolbachia therapy for onchocerciasis & lymphatic filariasis: Current perspectives. Indian J. Med. Res. 2019, 149, 706–714. [Google Scholar] [CrossRef]
  131. Maitre, A.; Wu-Chuang, A.; Aželytė, J.; Palinauskas, V.; Mateos-Hernández, L.; Obregon, D.; Hodžić, A.; Valiente Moro, C.; Estrada-Peña, A.; Paoli, J.C.; et al. Vector microbiota manipulation by host antibodies: The forgotten strategy to develop transmission-blocking vaccines. Parasit Vectors 2022, 15, 4. [Google Scholar] [CrossRef]
  132. Noden, B.H.; Vaughan, J.A.; Pumpuni, C.B.; Beier, J.C. Mosquito ingestion of antibodies against mosquito midgut microbiota improves conversion of ookinetes to oocysts for Plasmodium falciparum, but not P. yoelii. Parasitol. Int. 2011, 60, 440–446. [Google Scholar] [CrossRef] [PubMed]
  133. Aguilar-Díaz, H.; Quiroz-Castañeda, R.E.; Cobaxin-Cárdenas, M.; Salinas-Estrella, E.; Amaro-Estrada, I. Advances in the Study of the Tick Cattle Microbiota and the Influence on Vectorial Capacity. Front. Vet. Sci. 2021, 8, 710352. [Google Scholar] [CrossRef]
  134. Wade, D.M.; Hankins, M.; Smyth, D.A.; Rhone, E.E.; Mythen, M.G.; Howell, D.C.; Weinman, J.A. Detecting acute distress and risk of future psychological morbidity in critically ill patients: Validation of the intensive care psychological assessment tool. Crit. Care 2014, 18, 519. [Google Scholar] [CrossRef] [PubMed]
  135. Gupta, J.P.; Shyma, K.P.; Ranjan, S.; Gaur, G.K.; Bhushan, B. Genetic manipulation of endosymbionts to control vector and vector borne diseases. Vet. World 2012, 5, 571–576. [Google Scholar] [CrossRef]
  136. Durvasula, R.V.; Gumbs, A.; Panackal, A.; Kruglov, O.; Aksoy, S.; Merrifield, R.B.; Richards, F.F.; Beard, C.B. Prevention of insect-borne disease: An approach using transgenic symbiotic bacteria. Proc. Natl. Acad. Sci. USA 1997, 94, 3274–3278. [Google Scholar] [CrossRef]
Table
Table 1. Pathogens of human and animal importance transmitted by ticks of the Hyalomma species.
Table 1. Pathogens of human and animal importance transmitted by ticks of the Hyalomma species.
Hyalomma SpeciesHuman PathogensAnimal PathogensContinentReference
H. aegyptium
- Anaplasma phagocitophylum
- Ehrlichia canis
- Coxiella burnetti
- Ricketssia aeschlimannii
- Ricketssia africae
- Borrelia turcica
- Borrelia burgdoferi
- Leishmania infantum
Theileria annulata
Hepatozoon kisrae
Hemolivia mauritanica
Theileria lestoquardi
Candidatus
Midichloria mitochondrii
Africa
Europe		[21,22]
H. albiparmatum
- R.conorii
 Africa[23,24]
H. anatolicum
- Crimea–Congo hemorrhagic fever (CCHF) virus
- Virus Kadam
- Virus Kundal
- Virus Karyana
- Rickettsia spp.
Ehrlichia spp.
Anaplasma spp.
Babesia spp.
Theileria annulata
Theileria equi
Theileria lestoquardi
Theileria ovis
Africa
Asia
Europe		[25,26]
H. arabica Asia[27]
H. brevipunctata
Anaplasma marginale
Babesia bigemina
 Asia[25]
H. detritum
Bhanja virus
Ricketssia aeschlimannii
Theileria annulata
 Africa
Europe		[28]
H. dromedarii
CCHF virus
Dhori virus
Kadam virus
Sindilbis virus
Chick Ross virus
Thogoto virus
Bhanja virus
Coxiella burnetti
Rickettsia aeschlimannii
Rickettsia rickettsii
Babesia spp.
Theileria annulata
Theileria camelensis
Coxiella burnetti
África
Asia
Europa		[29]
H. erythraeum o H. somaliticum Africa
Asia
Europe		[30]
H. excavatum
Rickettsia aeschlimannii
Theileria lestoquardi
Anaplasma marginale
Anaplasma centrale
Theileria annulata
Africa
Europe		[19]
H. franchinii Europe[23]
H. husainii Asia[25]
H. impeltatum
CCHF virus
Dhori virus
Rickettsia aeschlimannii
Rickettsia africae
Babesia ocultans
Theileria lestoquardi
Africa
Asia
Europe		[30,31]
H. impressum
Babesia ocultans
Africa[25]
H. kumari [32]
H. lussitanicum
Rickettsia spp.
Anaplasma phagocytophilum
Borrelia
Coxiella burnetii
Francisella tularensis
 Europe[33,34]
H. marginatum
CCHF virus
Dhori virus
West Nile virus
Bhanja virus
Ricketssia aeschlimannii
Ricketssia sibirica
Ricketssia africae
Babesia spp.
Theileria annulata
Africa
Asia
Europe		[16,35,36]
H. nitidum
Thogoto virus
CCHF virus
 Africa[24]
H. punctata Africa
Asia		[37]
H. rhipicephaloides Africa
Asia		[37]
H. rufipes
Thogoto virus
CCHF virus
Ricketssia aeschlimannii
R.conorii
Babesia ocultans
Africa
Asia
Europe		[6,38]
H. schulzei
Dhori virus
Anaplasma ovis
Anaplasma marginale
Ehrlichia ewingii
Asia [39]
H. scupense
Coxiella burnetii
Theileria annulata
Africa
Asia
Europe		[40,41]
H. truncatum
CCHF virus
Bhanja virus
Rift Valley fever virus
Coxiella burnetti
Rickettsia aeschlimannii
R. sibirica
R. conorii
Venezuelan equine encephalitis
Rift Valley fever virus
Africa
Asia
Europe		[24,42]
H. turanicum
CCHF virus
R. sibirica
B. ocultans
B. caballi
Venezuelan equine encephalitis
Rift Valley fever virus
Africa
Asia
Europe		[38]
Table
Table 2. Current evidence of Francisella-like endosymbionts in ticks and their hosts.
Table 2. Current evidence of Francisella-like endosymbionts in ticks and their hosts.
Species of TickRegionHost or EnvironmentReference
Ixodes ricinus and Dermacentor reticulatusSlovakiaEnvironment[73]
Rhipicephalus sanguineus, Hyalomma marginatum, Hyalomma, and Rhipicephalus bursaSardiniaEnvironment [74]
Hyalomma marginatum, Hyalomma rufipes, Hyalomma dromedarii, Hyalomma aegyptium, and Hyalomma excavatumIsraelEnvironment, camels, horses, tortoises, and migratory birds[62]
Amblyomma maculatumOklahoma, USAOklahoma State University Tick Rearing Facility (OSUTRF)[75]
Ornithodoros moubata and Argus arboreusCzech RepublicLaboratory colony[76]
Rhipicephalus sanguineusSouthern ThailandChicken[77]
Hyalomma marginatum, Hyalomma aegyptium, Rhipicephalus sanguineus, and Dermacentor reticulatusBulgariaHuman and animal hosts (not specified)[78]
Amblyomma americanum, Amblyomma maculatumGeorgia, USAEnvironment, human, and dogs[79]
Ixodes ricinus, Ixodes acuminatus, Dermacentor marginatus, Dermacentor reticulatus, Haemaphysalis inermis, Haemaphysalis concinna, and Haemaphysalis punctataHungaryEnvironment, common hamsters, and dogs[80]
Hyalomma lusitanicumSpainEnvironment[34]
Hyalomma dromedariiSaudi ArabiaCamels[81]
Haemaphysalis longicornis and Hyalomma asiaticumChinaEnvironment[82]
Dermacentor anderson, Dermacentor variabilis, Dermacentor albipictus, Dermacentor occidentalis, Dermacentor hunteri Dermacentor nitens, Amblyomma maculatum, and Ornithodoros porcinusVarious originsSeveral collections: environment, horses, coyote, sheep, and humans[83]
Dermacentor variabilisUSA and CanadaSeveral collections: environment, dogs, humans, raccoons, and cats[84]
Dermacentor reticulatusFranceEnvironment[85]
Hyalomma rufipesEthiopiaEnvironment[86]
Dermacentor reticulatusPortugalEnvironment, wolves, and dogs[87]
Amblyomma varanense, Amblyomma helvolumThailandSnakes[88]
Amblyomma dubitatum, Dermacentor nitens, and Rhipicephalus microplusBrazilHorses, cattle, and dogs[89]
Dermacentor andersoni and Dermacentor variabilisCanadaEnvironment, humans, dogs, horses, skunks, raccoons, deers, mice, and voles[90]
Haemaphysalis flava and Haemaphysalis phasianaKoreaEnvironment[91]
Amblyomma americanumUSALaboratory from OSUTRF and environment[92]
Dermacentor marginatus and Dermacentor reticulatusItalyEnvironment[93]
Haemaphysalis doenitziChinaEnvironment and rabbit[94]
Dermacentor albipictusMinnesota (USA)White-tailed deer[95]
Hyalomma lusitanicum, Dermacentor reticulatus, and Ixodes hexagonusSpain and PortugalEnvironment[96]
Hyalomma anatolicum, Hyalomma hussaini, Hyalomma scupense, Rhipicephalus microplus, and Rhipicephalus annulatusPakistanBuffalo and cattle[97]
Dermacentor albipictusAlberta and CanadaEnvironment[98]
Hyalomma dromedariiEgyptCamels[99]
Hyalomma rufipesSpain, Greece, and IsraelMigratory birds[100]
Dermacentor reticulatus and Ixodes ricinusPolandEnvironment[101]
Rhipicephalus bursa, Rhipicephalus sanguineus, Hyalomma detritum, Hyalomma marginatum, Hyalomma lusitanicum, and Ixodes ricinusAlgeriaEnvironment and cattle
Rhipicephalus microplusGalapagos IslandsCattle[102]
Hyalomma rufipesItalyMigratory birds[103]
Dermacentor reticulatus and Haemaphysalis punctataFranceEnvironment[104]
Amblyomma maculatumMississippi, USAEnvironment[105]
Hyalomma dromedariiPalestineCamels[106]
Hyalomma marginatum, Hyalomma rufipes, Hyalomma aegyptium, Rhipicephalus sanguineus, Dermacentor occidentalis, and Dermacentor variabilisAnatoliaEnvironment, dogs, cattle, and goats[107]
Amblyomma maculatumMississippi, USAEnvironment[108]
Ixodes ricinusSerbiaHumans[109]
Dermacentor reticulatusSerbiaEnvironment[110]
Dermacentor reticulatusEngland, Wales, Belgium, Germany, NetherlandsEnvironment[111]
Amblyomma latumSouth AfricaSpitting cobra[112]
Amblyomma tuberculatumMississippi, USAGopher tortoise[113]
Dermacentor marginatu and Dermacentor reticulatusGermanyEnvironment[114]
Dermacentor andersoniCanadaEnvironment and squirrels[115]
Dermacentor occidentalisCalifornia, USAEnvironment[116]
Dermacentor albipictusAlberta, CanadaWhitetail and mule deers
Table
Table 3. The epidemiology of Francisella-like endosymbionts in Hyalomma tick species.
Table 3. The epidemiology of Francisella-like endosymbionts in Hyalomma tick species.
RegionReferenceTotal Number of Collected TicksHyalomma TicksFLE Prevalence
Anatolia (Turkey)[107]280H. aegyptum
H. marginatum
H. excavatum		25% of the total
Israel[62]310H.marginatum
H. excavatum
H. dromedarii,
H. aegyptium
H. rufipes		90.66% of the total
84.6% H. marginatum
90.5% H. excavatum
89.8% H. dromedarii,
100% H. aegyptium,
90.4% H. rufipes
Argelia[101]23541 H. detritum
15 H. marginatum
4 H. lusitanicum		88.5% of the total
90.2% H. detritum
80% H. marginatum
100% H. lusitanicum
Bulgaria[78]472H. marginatum marginatum (5.9%; n = 28)
H. aegyptium (0.2%; n = 1). 		2.5% of the total
China[82]671H. asiaticum (n 88, 13%)13% of the total
Italy[74]236H. marginatum (8, 3%)
H. lusitanicum (1, 1%)		1.7% of the total
Turkey[118]1115245 H. marginatum marginatum
106 H. anatolicum anatolicum
53 H. anatolicum excavatum
68 H. detritum detritum,		0%
Pakistan[97]234212 Hyalomma anatolicum
2 H. hussaini
1 H. scupense		91.5% of the total
96.2% H. anatolicum
0.45% H. hussaini
0% H. scupense
Occidental Paleartic region [100]575H. rufipes
H. marginatum		77% of the total
H. rufipes: 76.7%
H. marginatum: 75%
Ethiopia[86]296H. rufipes (1/296)0,34% of the total
H. rufipes 0.34%
Egypt[99]319H. dromedarii (249/319)6% of the total
14.94% H. dromedarii
Saudi Arabia[81]151H. dromedari (148/151)
H. impeltatum (2/151)
Hyalomma spp. (1/151)		98.01% of the total
H. dromedari 100%
Cáceres (Spain)[34]48H. lusitanicum (48/48)52–99% of the total
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Sesmero-García, C.; Cabanero-Navalon, M.D.; Garcia-Bustos, V. The Importance and Impact of Francisella-like Endosymbionts in Hyalomma Ticks in the Era of Climate Change. Diversity 2023, 15, 562. https://doi.org/10.3390/d15040562

AMA Style

Sesmero-García C, Cabanero-Navalon MD, Garcia-Bustos V. The Importance and Impact of Francisella-like Endosymbionts in Hyalomma Ticks in the Era of Climate Change. Diversity. 2023; 15(4):562. https://doi.org/10.3390/d15040562

Chicago/Turabian Style

Sesmero-García, Celia, Marta Dafne Cabanero-Navalon, and Victor Garcia-Bustos. 2023. "The Importance and Impact of Francisella-like Endosymbionts in Hyalomma Ticks in the Era of Climate Change" Diversity 15, no. 4: 562. https://doi.org/10.3390/d15040562

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop