https://orcid.org/0000-0001-8344-7024
Figures
Abstract
Wolbachia Hertig, 1936 is an intracellular bacterial symbiont colonizing many arthropods. Of the studies done on the bacteria present in the superfamily Gerroidea Leach, 1815, no report of Wolbachia infection had yet been made. Thus, we checked the presence of Wolbachia in six Gerroidea species which colonize tropical aquatic environments by PCR using wsp primer set before sequencing and phylogenetic analyses. Insects were collected in the marine fringe of mangroves, in river estuaries, in swampy mangroves, and in ponds from Guadeloupe islands (Caribbean). Two new strains of Wolbachia were detected in these Gerroidea. They were named wLfran and wRmang. The wsp sequences suggest that the strains belong to the already described E supergroup or similar. wLfran is present in Limnogonus franciscanus Stål, 1859 and Rheumatobates trinitatis (China, 1943) while wRmang appears to be present exclusively in R. mangrovensis (China, 1943). Three other species were analysed, but did not appear to be infected: Brachymetra albinerva (Amyot & Serville, 1843), Halobates micans Eschscheltz, 1822, and Microvelia pulchella Westwood, 1834. The results presented here highlight for the first time the presence of new intracellular Wolbachia strains in Gerroidea colonising tropical aquatic environments like mangrove habitats from inlands to sea shore.
Citation: Conjard S, Meyer DF, Aprelon R, Pagès N, Gros O (2022) Evidence of new strains of Wolbachia symbiont colonising semiaquatic bugs (Hemiptera: Gerroidea) in mangrove environment of the Lesser Antilles. PLoS ONE 17(8): e0273668. https://doi.org/10.1371/journal.pone.0273668
Editor: Olle Terenius, Uppsala University: Uppsala Universitet, SWEDEN
Received: November 9, 2021; Accepted: August 12, 2022; Published: August 30, 2022
Copyright: © 2022 Conjard et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: The data underlying the results presented in the study are available from https://www.ncbi.nlm.nih.gov/nuccore/MW019457 and https://www.ncbi.nlm.nih.gov/nuccore/MW114524.
Funding: This research was funded in the frame of the projects MALIN, grant number 2018-FED-1084, and INSULA, grant number 2020-FED-45, both funded by the European Union and the Guadeloupe Regional Council under the European Research and Development Funds (ERDF) 2014- 2020 program. https://ec.europa.eu/info/research-and-innovation/funding/funding-opportunities/funding-programmes-and-open-calls_en#erdf Suzanne Conjard was supported by a grant from the Guadeloupe Regional Council. https://www.regionguadeloupe.fr/accueil/#_ The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Wolbachia pipientis commonly known as Wolbachia, is an alpha-proteobacterium belonging to the Rickettsiales Gieszczykiewicz, 1939 order. It is mainly present intracellularly in the genital and somatic tissues of more than 60% of arthropods [1] and in nematodes [2]. In arthropods, the Wolbachia bacterium is mainly known for its ability to manipulate reproduction of the infected host, and can lead to production of infected females without males (inducing parthenogenesis), feminization of genetic males (inducing feminization), destruction of infected male offspring (killing males) and cytoplasmic incompatibility between infected males and uninfected (or infected with another strain) females [3].
To detect the presence of Wolbachia, a couple of methods are possible. The FISH (Fluorescence In Situ Hybridization) technic with the use of specific probes to visualize the bacteria within the insect tissues [4,5], or PCR (Polymerase Chain Reaction) targeting specific genes. The first detections of Wolbachia thanks to PCR were made using universal 16S rDNA primer sets and then using the ftsZ gene, which was considered more specific at the time [1,6]. Subsequently, PCR targeting the specific wsp gene (Wolbachia surface protein) which encodes a major protein of the cell surface layer became widespread [7]. Primers encoding wsp allow a preliminary identification of the Wolbachia strain. However, these last two decades the MLST (Multilocus Sequence Typing) method, which combines a set of genes, has become more popular [8]. This technique avoids the high recombination rates found with the wsp technique, which allows for a more reliable phylogeny [9]. More recently though the MLST and wsp typing system has been highly criticized, and whole genome sequencing and phylogenomic approaches seem to be best [10,11].
The phylogeny of Wolbachia is divided in various supergroups. Early phylogenetic analyses done almost 30 years ago determined the presence of two supergroups A and B, grouping together Wolbachia strains infecting different arthropods [1]. Then, Wolbachia strains phylogenetically related to supergroups C and D have been observed in filarial nematode hosts [12]. Today, the use of the MLST technique allows the identification of 19 supergroups up to the letter S [13].
Insects of the super-family Gerroidea are semi aquatic bugs belonging to the order Hemiptera. They live on the surface of the water, in rivers, estuaries or even in the sea. In tropical environments, they are also present in mangroves [14]. These semiaquatic insects move on the surface of the water thanks to a bunch of small bristles at the end of their legs [15]. They are sucking biting insects that feed opportunistically depending on the prey present on the surface of the water [15,16].
Apart from the wealth of publication on Wolbachia in many fields, there are only few studies on aquatic Hemiptera. According to research in Missouri, 52% of aquatic insects are infected with Wolbachia, compared to 60% in terrestrial insects [17]. Few recent studies demonstrated the presence of Wolbachia in semiaquatic bugs. In Cameroon, Esemu et al. (2019) detected Wolbachia in freshwater insects that represent a potential reservoir for the bacterium Mycobacterium ulcerans MacCallum, 1948 causing Buruli ulcer. This research focused on nine species of the Gerridae Leach, 1815 and Veliidae Amyot & Serville, 1843 families including the three genera Limnogonus, Microvelia, and Rhagovelia [18]. More recently, Castillo et al. [19] described the microbiome (including Wolbachia) associated with six species of gerrids belonging to the genera Platygerris, Potamobates, Rheumatobates, and Telmatometra from Panama [19].
Semi-aquatic bugs in the Lesser Antilles are not well known. A few studies confirmed their presence in these islands, the first focusing on Trinidad [20] and the second on Saint Martin [21]. For Guadeloupe, only two recent studies listing the insects of the island confirm the presence of six Gerroidea: Brachymetra albinerva, Limnogonus franciscanus, Microvelia pulchella, Rhagovelia plumbea, Rheumatobates mangrovensis and R. trinitatis [14,22]. Our study on Wolbachia in the Gerroidea of Guadeloupe focuses on six gerrids. Brachymetra albinerva lives in puddles between the roots of Pterocarpus officinalis in the swamp forest. Limnogonus franciscanus has the largest range, occurring on the terrestrial fringe of the mangrove, in the swamp forest and in the freshwater pools of “Grande-Terre” [14]. Halobates micans is exclusively marine, occurring in waves on the coast [23]. Microvelia pulchella is present in freshwater pools [22]. Rheumatobates mangrovensis is only present downstream of the “Grande-Rivière à Goyaves”. Rheumatobates trinitatis is also a marine species but prefers the mangrove waters more protected from wind and swell by mangrove trees, Rhizophora mangle Linnaeus, 1753 [14].
There is a great variability of Wolbachia strains in Arthropods [24]. Depending on geographical isolation or living environment, a host or strain of Wolbachia will change. For example, the fly Bactrocera dorsalis Hendel, 1912 in China is infected by four different strains throughout the country [25] or three species of the same fly genus can share one strain in South Asia [26]. Knowing this, it is interesting to demonstrate the presence of the bacterium in Gerroidea of Guadeloupe in order to have a first idea of the prevalence of the bacterium on the island. In order to detect the presence of Wolbachia symbionts in Gerroidea, we solely use PCR with primers specific for the wsp gene.
Materials and methods
Sampling
Sampling took place between 2019 and 2021, in the mangrove of the “Grand-Cul-de-Sac-Marin”, in the swampy forest of the back mangrove at the “Maison de la Mangrove”, in a pond of Grande-Terre “Étang Fréchou”, and on the shoreline coast of the Atlantic side of Grande-Terre “Anse-Maurice” (Fig 1). The samples were taken by boat in the marine mangrove and by feet for the other sites, using a 1 mm-mesh size nylon net. Apart from the collection sites “Anse-Maurice” and “Étang Fréchou”, all other insect collection sites are located in the marine area adjacent to the “Parc National de la Guadeloupe” or in the case of the “Grande-Rivière à Goyaves” estuary in the heart of the “Parc National de la Guadeloupe” (“permit n°2019–15”).
A total of 60 individuals of Gerroidea were collected and analyzed in different sampling sites according to their habitats (Fig 1 and Table 1). Where possible, for each collection, males, females and juveniles were analyzed.
Identification of insects, PCR amplification, and sequencing
The collected Gerroidea were individually identified using integrative taxonomy with two methods. Taxonomic determination keys [15,23,27–30] and PCR amplification followed by sequencing of the PCR products of the gene encoding COI (Cytochrome Oxidase subunit I) using the primers set LCO1490F and HCO2198R [31]. DNA was extracted using the DNeasy Blood & Tissue Kit following the manufacturer’s protocol. PCR was performed under the following conditions: initial denaturation at 94°C for 4 minutes, 30 denaturation cycles (94°C, 60 seconds), annealing (55°C, 45 seconds), extension (72°C, 45 seconds) and a final extension at 72°C for 1 minute. The expected size of the PCR products was checked after 2% agarose gel electrophoresis before to be directly sequenced by Eurofins (http://www.eurofinsgenomics.eu).
When identified, insects were selected in a representative manner according to species and habitat location. The primer set used for PCR was that corresponding to the Wolbachia wsp-specific surface protein (wsp81F and wsp691R) developped by Duron et al. (2008) [32]. PCR was performed under the following conditions: initial denaturation at 94°C for 3 minutes, 40 denaturation cycles (94°C, 60 seconds), annealing (54°C, 60 seconds), extension (72°C, 1 minute) and a final extension at 72°C for 7 minutes. The expected size of the PCR product is 610 bp. PCR products were verified after electrophoresis on 2% agarose gel electrophoresis. The positive control used is DNA from Rheumatobates mangrovensis that has been shown to be positive. The negative control is ultra-pure water. The PCR products were then directly sequenced (from the both primers used) by Eurofins (http://www.eurofinsgenomics.eu).
Phylogenetic analysis
Wolbachia wsp sequences from gerrids used for phylogenetic analysis were downloaded from NCBI (Table 3 and Fig 2) in addition to the sequences obtained in this study (MW019457 and MW114524). They were all analyzed and aligned with Geneious (Geneious version R10, https://www.geneious.com) and MAFFT [33]. The phylogenetic tree was constructed using PhyML software [34] with a maximum likelihood approach. The bootstrap analysis was performed with 1000 replicates, and the bootstrap values were calculated using a 50% majority rule.
Tree was inferred from maximum likelihood method using PhyML program and drawn using iTOL program. Branches are labelled as Supergroup Letter and specie names followed by GenBank accession numbers. Bootstrap values (1,000 replicates) are indicated, except for branches with a value less than 0.5.
Results
Wolbachia infection in Gerroidea of Guadeloupe
Wolbachia were detected in three of the six species tested: L. franciscanus, R. mangrovensis and R. trinitatis. Wolbachia was detected in all R. mangrovensis and L. fransciscanus individuals while occasionally in R. trinitatis and not detected in B. albinerva, H. micans and M. pulchella tested individuals (Tables 2 and 3).
Sequence and phylogenetic analyses
We amplified and partially sequenced the wsp gene (Table 3). From these sequences, two major Wolbachia strains were detected in Gerroidea from Guadeloupe and registered in the NCBI database: wRmang_isolateGuadeloupe (MW019457) and wLfran_isolateGuadeloupe (MW114524).
The wRmang strain was detected exclusively in Rheumatobates mangrovensis species, from the unique place where they can be found at the mouth of the river “Grande-Rivière à Goyaves” (Fig 1 and Table 1). The wLfran strain is the most prevalent strain and is detected in Limnogonus franciscanus and R. trinitatis. The two species do not share the same habitat. However, they can be found occasionally at sites such as the “Canal des Rotours” (Fig 1), a watercourse that crosses many environments, wet meadows, swamp forest and leads to mangroves. Limnogonus franciscanus is a freshwater species that prefers habitats like puddles or even private fountains in gardens like small or a natural pond at the “Maison de la Mangrove”. Rheumatobates trinitatis is a marine species that will prefer sheltered mangrove environments such as at the “Manche à Eau” or in the “Baie à Chat” (Fig 1). The two strains have 93% homogeneity between them.
The phylogenetic tree, based on wsp gene sequences, shows the distinct presence of wLfran and wRmang strains within the cluster of E-supergroup sequences (Fig 2).
Discussion
In the present study, six species of semi-aquatic bugs were analyzed by PCR and sequenced to detect and identify Wolbachia among Gerroidea from Guadeloupe island (Caribbean, Lesser Antilles). Thus, three Gerroidea species are infected by two new strains (wLfran and wRmang) belonging to E supergroup. This study provides first insight for the prevalence of Wolbachia in Gerroidea in Guadeloupe.
Wolbachia strains have been reported on arthropod pests such as scorpion [35], flies [36], terrestrial isopods [4], and spiders [37]. However, the majority of these studies have focused on insects with an impact on health or agriculture. Wolbachia has been detected in a wide diversity of mosquito species, some of them vectors of medically important arboviruses [38]. The Wolbachia bacterium has been proposed as a regulatory tool for Zika and/or dengue bearing mosquitoes [39–41]. Studies on the occurrence of Wolbachia in insect pests of crops mainly concern Diptera [25,26], Acari [24,42] and phytophagous Hemiptera [43–48]. Of all the studies carried out, very few have been conducted on aquatic insects and even fewer on marine insects. However, two recent studies conducted in Cameroon [18] and Panama [19] looking for the bacterial community in the Gerridae and Veliidae found Wolbachia in these taxa.
In Guadeloupe, Wolbachia has already been studied in some mosquito species: Aedes aegypti Linnaeus, 1762, A. taeniorhynchus (Wiedemann, 1821) and Culex quinquefasciatus Say, 1823 mosquitoes [49,50], Deinocerites sp. Theobald, 1901, Mansonia sp. Blanchard, 1901, Ochlerotatus sp. Reinert, 2000 and Uranotaenia sp. Lynch Arribálzaga, 1891 [51]. While mosquitoes of the genus Aedes are usually free of Wolbachia, this is not the case for Cx. quinquefasciatus, which has a variable infection rate of between 79 to 96% [49]. Mosquitoes, although temporarily aquatic insects, do not appear to share common Wolbachia strains with Gerroidea based on results of the present study.
The low number of Gerroidea samples collected during this study does not allow statistical treatment of data. However, these preliminary results suggest a high presence of Wolbachia in certain species such as L. franciscanus, R. mangrovensis and R. trinitatis and an absence, or very low presence, in B. albinerva, H. micans and M. pulchella. Given that the sampling effort is really different between Gerroidea and Guadeloupean mosquitoes, a pattern of infection appears to be emerging. Like the Aedes mosquitoes from Guadeloupe, B. albinerva and M. pulchella, while sharing the same environment as the other Gerroidea tested, does not appear to be infected. Thus, the presence of Wolbachia seems to be related to the insect species rather than to the environment occupied. Wolbachia infection is known to be variable within a population of the same genus but also within a same species depending on its geography [25,26,44]. Depending on its geographical origin, the frequency of Wolbachia infection can be very variable, ranging from 4–100% in one sampling area to 37–100% in another [44]. Statistically, the intraspecific infection rate can be very high or very low and there is no average infection rate [52]. In some genera, depending on the species, the average infection rate varies from quite low at less than 3% [24] to very high with an infection rate close to 100% [47]. In view of the different forms of infection, it is therefore normal to observe variations in infection among the six species studied in Guadeloupe.
Currently, taking into account all invertebrates and all analytical methods, there are nineteen Wolbachia supergroups named from A to S (G is not included because it is a grouping of A and B supergroups) [13,24,26,42]. In our study, Wolbachia symbionts infecting mangrove Gerroidea belong to E supergroup according to wsp phylogenetic analysis (Fig 2).
The Wolbachia strain colonizing the pirate bug Orius minutus (Linnaeus, 1758) is also part of E supergroup. This Anthochorid belongs to the order Hemiptera, but remains genetically distant from the ones analyzed in this study as is not part of the superfamily Gerroidea. In contrast, Gerris sp. Fabricius, 1794 from temperate habitats has been found to be positive for Wolbachia strains of the B supergroup in England [53] but negative in France [32]. Overall, few studies have been conducted and updated on Wolbachia E supergroup, but it seems that several hosts are possible, including insects, spiders [37] and springtails [54]. Therefore, there is currently little data regarding the occurrence of Wolbachia in the superfamily Gerroidea and the prevalence of E supergroup is not yet known. Typing of strains into supergroups was mainly based on phylogenetic inference of the Wolbachia surface protein (wsp) which is easy to implement and reproducible. However, the small size of this gene and its high recombination rate make it unreliable for precise phylogenetic analyses [8]. Therefore, a full characterization of the MultiLocus Sequence Typing (MLST) is necessary for a correct typing of the strain [8]. MLST analysis is based on the study of several genes. This technique allows refining the analysis by increasing the number of supergroups detected, 16 different supergroups have been described so far, without changing the overall phylogeny [26,55]. However, this technique is nowadays discussed because the markers used are not discriminating enough and are not reliable enough at fine-scale [10].
It is now possible to state that Gerroidea from Guadeloupe mangroves are infected by different Wolbachia strains. However, as the use of wsp gene sequences is not sufficiently discriminating, it would be interesting to strengthen the research with other methods such as the analysis of the whole genome sequence of the strains which remains the most reliable method [10,56]. This later technique would allow us to consolidate the results and possibly confirm the presence of these strains in E supergroup.
Knowledge of aquatic insects in marine, brackish and lacustrine environments in the tropics is poor. In Guadeloupe, other Wolbachia strains have been observed in spiders and ants from swamp and mangrove forests [57]. Increasing our knowledge on the diversity of Wolbachia strains colonizing various insects from similar environments through the island would allow us to demonstrate the strategy used by these symbiotic Wolbachia strains in such tropical Hemiptera to be transmitted to the new host generations.
Nucleotide sequence accession number
Wolbachia wsp gene partial sequences obtained in this study were deposited in the Genebank database under accession numbers MW019457 and MW114524.
References
- 1. Werren JH, Zhang W, Guo LR. Evolution and phylogeny of Wolbachia: reproductive parasites of arthropods. Proc R Soc Lond B. 1995;261(1360):55–63.
- 2. Zug R, Hammerstein P. Still a host of hosts for Wolbachia: analysis of recent data suggests that 40% of terrestrial arthropod species are infected. PLoS ONE. 2012;7(6):e38544.
- 3. Werren JH, Baldo L, Clark ME. Wolbachia: master manipulators of invertebrate biology. Nat Rev Microbiol. 2008;6(10):741–51.
- 4. Le Clec’h W, Chevalier FD, Genty L, Bertaux J, Bouchon D, Sicard M. Cannibalism and predation as paths for horizontal passage of Wolbachia between terrestrial Isopods. Bourtzis K, PLoS ONE. 2013;8(4):e60232.
- 5. Saurav GK, Daimei G, Rana VS, Popli S, Rajagopal R. Detection and localization of Wolbachia in Thrips palmi Karny (Thysanoptera: Thripidae). Indian J Microbiol. 2016;56(2):167–71.
- 6. O’Neill SL, Giordano R, Colbert AM, Karr TL, Robertson HM. 16S rRNA phylogenetic analysis of the bacterial endosymbionts associated with cytoplasmic incompatibility in insects. Proc Natl Acad Sci. 1992;83(7):2699–2702. pmid:1557375
- 7. Phylogeny Zhou W. and PCR-based classification of Wolbachia strains using wsp gene sequences. Proc R Soc Lond B. 1998;265:509–15.
- 8. Baldo L, Dunning Hotopp JC, Jolley KA, Bordenstein SR, Biber SA, Choudhury RR, et al. Multilocus sequence typing system for the endosymbiont Wolbachia pipientis. AEM. 2006;72(11):7098–110.
- 9. Zhao G-Z, Zhu T-R, Zeng Y, Zhu D-H. Wolbachia infection in six species of gall wasps and their parasitoids. J Asia Pac Entomol. 2021;24(1):21–5.
- 10. Bleidorn C, Gerth M. A critical re-evaluation of multilocus sequence typing (MLST) efforts in Wolbachia. FEMS Microbiol Ecol. 2018;94(1):1–11.
- 11. Gerth M, Gansauge MT, Weigert A, Bleidorn C. Phylogenomic analyses uncover origin and spread of the Wolbachia pandemic. Nat Commun. 2014;5(1): 5117.
- 12. Bandi C, Anderson TJC, Genchi C, Blaxter ML. Phylogeny of Wolbachia in filarial nematodes. Proc R Soc Lond B. 1998;265:2407–13.
- 13. Lefoulon E, Clark T, Borveto F, Perriat-Sanguinet M, Moulia C, Slatko BE, et al. Pseudoscorpion Wolbachia symbionts: diversity and evidence for a new supergroup S. BMC Microbiol. 2020;20(1):188.
- 14. Conjard S, Garrouste R, Gustave dit-Duflo S, Gros O. Mangrove semiaquatic bugs (Hemiptera: Gerroidea) from Guadeloupe in Lesser Antilles: first records and new data on species distribution. Aquat Insects. 2021;42(3‑4):239–46.
- 15.
Heckman CW. Encyclopedia of South American aquatic insects: Hemiptera—Heteroptera. Dordrecht: Springer Netherlands; 2011.
- 16. Ditrich T, Papáček M. Differences in prey capture in semiaquatic bugs (Heteroptera: Gerromorpha): Prey capture in semiaquatic bugs. Entomol Sci. 2016;19:34–41.
- 17. Sazama EJ, Bosch MJ, Shouldis CS, Ouellette SP, Wesner JS. Incidence of Wolbachia in aquatic insects. Ecol Evol. 2017;7(4):1165–9.
- 18. Esemu SN, Dong X, Kfusi AJ, Hartley CS, Ndip RN, Ndip LM, et al. Aquatic Hemiptera in Southwest Cameroon: biodiversity of potential reservoirs of Mycobacterium ulcerans and multiple Wolbachia sequence types revealed by metagenomics. Diversity. 2019;11(225):1–26.
- 19. Castillo AM, Saltonstall K, Arias CF, Chavarria KA, Ramírez-Camejo LA, Mejía LC, et al. The microbiome of neotropical Water-striders and its potential role in codiversification. Insects. 2020;11(9):578. pmid:32878094
- 20. Nummelin M. Wing dimorphism of a Water-strider Limnogonus franciscanus (Stål) (Heteroptera: Gerridae) in seasonal tropical climate. Entomol Fennica. 1997;8:167–70.
- 21.
Yokoyama M. The incomplete guide to the wildlife of Saint Martin. Vol. 2. Saint-Martin: Mark Yokoyama; 2013. 131 p.
- 22. Meurgey F, Ramage T. Challenging the Wallacean shortfall: A total assessment of insect diversity on Guadeloupe (French West Indies), a checklist and bibliography. Insecta Mundi. 2020;0786:1–183.
- 23. De Kort-Gommers M, Nieser N. Records of Antillean Water-striders (Heteroptera). Stud Fauna Curaçao other Caribbean isl. 1969;112:72–87.
- 24. Ros VID, Fleming VM, Feil EJ, Breeuwer JAJ. How diverse is the genus Wolbachia? Multiple-gene sequencing reveals a putatively new Wolbachia supergroup recovered from spider mites (Acari: Tetranychidae). Appl Environ Microbiol. 2009;75(4):1036–43.
- 25. Sun X-Y, Cui L, Li Z. Diversity and phylogeny of Wolbachia infecting Bactrocera dorsalis (Diptera: Tephritidae) populations from China. Environ Entomol. 2007;36(5):1283–9.
- 26. Asimakis ED, Doudoumis V, Hadapad AB, Hire RS, Batargias C, Niu C, et al. Detection and characterization of bacterial endosymbionts in Southeast Asian tephritid fruit fly populations. BMC Microbiol. 2019;19(S1):1–18. pmid:31870298
- 27. Herring L. The Genus Halobates (Hemiptera: Gerridae). Pacific Insects. 1961;3(2‑3):223–305.
- 28. Hungerford HB. The Genus Rheumatobates Bergroth (Hemiptera-Gerridae). Univ Kansas Sci Bull. 1954;36(7):529–88.
- 29. Nieser N. Gerridae of Suriname and the Amazon, with additional records of other neotropical species. Stud Fauna Suriname Guyanas. 1970;121(47):94–138.
- 30. Westlake KP, Rowe L, Currie DC. Phylogeny of the Water-strider genus Rheumatobates (Heteroptera: Gerridae). Syst Entomol. 2000;25(2):125–45.
- 31. Folmer O, Black M, Hoeh W, Lutz R, Vrijenhoek R. DNA primers for amplification of mitochondrial cytochrome c oxidase subunit I from diverse metazoan invertebrates. Mol Mar Biol Biotechnol. 1994;3(5):294–9. pmid:7881515
- 32. Duron O, Bouchon D, Boutin S, Bellamy L, Zhou L, Engelstädter J, et al. The diversity of reproductive parasites among arthropods: Wolbachia do not walk alone. BMC Biol. 2008;6(27):1–12.
- 33. Katoh K, Standley DM. MAFFT Multiple Sequence Alignment Software Version 7: Improvements in Performance and Usability. Mol Biol Evol. 2013;30(4):772–80. pmid:23329690
- 34. Guindon S, Dufayard J-F, Lefort V, Anisimova M, Hordijk W, Gascuel O. New algorithms and methods to estimate Maximum-Likelihood phylogenies: assessing the performance of PhyML 3.0. Syst Biol. 2010;59(3):307–21. pmid:20525638
- 35. Baldo L, Prendini L, Corthals A, Werren JH. Wolbachia are present in Southern African scorpions and cluster with supergroup F. Curr Microbiol. 2007;55(5):367–73.
- 36. Madhav M, Parry R, Morgan JAT, James P, Asgari S. Wolbachia endosymbiont of the horn fly (Haematobia irritans irritans): a supergroup A strain with multiple horizontally acquired cytoplasmic incompatibility genes. Appl Environ Microbiol. 2020;86(6):e02589–19.
- 37. Yun Y, Peng Y, Liu F, Lei C. Wolbachia screening in spiders and assessment of horizontal transmission between predator and prey. Neotrop Entomol. 2010;40(2):164–9.
- 38. van den Hurk AF, Hall-Mendelin S, Pyke AT, Frentiu FD, McElroy K, Day A, et al. Impact of Wolbachia on infection with chikungunya and yellow fever viruses in the mosquito vector Aedes aegypti. PLoS Negl Trop Dis. 2012;6(11):e1892.
- 39. Caragata E, Dutra H, Moreira L. Inhibition of zika virus by Wolbachia in Aedes aegypti. Microb Cell. 2016;3(7):293–5.
- 40. Haqshenas G, Terradas G, Paradkar PN, Duchemin J-B, McGraw EA, Doerig C. A role for the insulin receptor in the suppression of dengue virus and zika virus in Wolbachia-infected mosquito cells. Cell Reports. 2019;26(3):529-535.e3.
- 41.
Ryan PA, Turley AP, Wilson G, Hurst TP, Retzki K, Brown-Kenyon J, et al. Establishment of wMel Wolbachia in Aedes aegypti mosquitoes and reduction of local dengue transmission in Cairns and surrounding locations in northern Queensland, Australia. Vol. 3, Gates Open Research. 2020. p. 1547.
- 42. Glowska E, Dragun-Damian A, Dabert M, Gerth M. New Wolbachia supergroups detected in quill mites (Acari: Syringophilidae). Infect Genet Evol. 2015;30(2015):140–6.
- 43. Bing X-L, Zhao D-S, Sun J-T, Zhang K-J, Hong X-Y. Genomic analysis of Wolbachia from Laodelphax striatellus (Delphacidae, Hemiptera) reveals insights into its “Jekyll and Hyde” mode of infection pattern. Genome Biol Evol. 2020;12(2):3818–31.
- 44. Hughes GL, Allsopp PG, Brumbley SM, Woolfit M, McGraw EA, O’Neill SL. Variable infection frequency and high diversity of multiple strains of Wolbachia pipientis in Perkinsiella Planthoppers. Appl Environ Microbiol. 2011;77(6):2165–8.
- 45. Karut K, Castle SJ, Karut ŞT, Karaca MM. Secondary endosymbiont diversity of Bemisia tabaci and its parasitoids. Infect Gene Evol. 2020;78:104104.
- 46. Li F, Li P, Hua H, Hou M, Wang F. Diversity, tissue localization, and infection pattern of bacterial symbionts of the white-backed planthopper, Sogatella furcifera (Hemiptera: Delphacidae). Microb Ecol. 2020;79(3):720–30.
- 47. Pan H, Li X, Ge D, Wang S, Wu Q, Xie W, et al. Factors affecting population dynamics of maternally transmitted endosymbionts in Bemisia tabaci. PLoS ONE. 2012;7(2):e30760.
- 48. Rossitto De Marchi B, Smith HA. Bacterial endosymbiont diversity among Bemisia tabaci (Hemiptera: Aleyrodidae) populations in Florida. Insects. 2020;11(3):179.
- 49. Goindin D, Cannet A, Delannay C, Ramdini C, Gustave J, Atyame C, et al. Screening of natural Wolbachia infection in Aedes aegypti, Aedes taeniorhynchus and Culex quinquefasciatus from Guadeloupe (French West Indies). Acta Tropica. 2018;185:314–7.
- 50. Shi C, Beller L, Deboutte W, Yinda KC, Delang L, Vega-Rúa A, et al. Stable distinct core eukaryotic viromes in different mosquito species from Guadeloupe, using single mosquito viral metagenomics. Microbiome. 2019;7(1):121. pmid:31462331
- 51.
Pagès N, Re J, Aprelon R, Bihan ML, Gardès L, Venail R, et al. Natural Wolbachia infection across Guadeloupe mosquito populations. Caribbean Science and Innovation Meeting, Pointe-à-Pitre, Guadeloupe, France., 2019. hal-02433117.
- 52. Hilgenboecker K, Hammerstein P, Schlattmann P, Telschow A, Werren JH. How many species are infected with Wolbachia?–a statistical analysis of current data: Wolbachia infection rates. FEMS Microbiol Lett. 2008;281(2):215–20.
- 53. Werren JH, Windsor DM. Wolbachia infection frequencies in insects: evidence of a global equilibrium? Proc R Soc Lond B. 2000;267(1450):1277–85.
- 54. Timmermans MJTN, Mariën J, Roelofs D, van Straalen NM, Ellers J. Evidence for multiple origins of Wolbachia infection in springtails. Pedobiologia. 2004;48(2004):469–75.
- 55. Wang G-H, Jia L-Y, Xiao J-H, Huang D-W. Discovery of a new Wolbachia supergroup in cave spider species and the lateral transfer of phage WO among distant hosts. Infect Genet Evol. 2016;41:1–7.
- 56. Gerth M, Bleidorn C. Comparative genomics provides a timeframe for Wolbachia evolution and exposes a recent biotin synthesis operon transfer. Nat Microbiol. 2016;2(16241):1–7.
- 57.
Conjard S, Billard Y, Macal A-M, Manikon M, Romany K, Gros O. Evidence of the presence of intracellular bacterial Wolbachia in insects living in mangrove of Guadeloupe. 22th biennial conference of the Caribbean Academy of Sciences, Georgetown, Guyana.; 2021. hal-03342587.