J Arthropod-Borne Dis, June 2013, 7(1): 46–55 P Parvizi et al.: Detection of a New … http://jad.tums.ac.ir Published Online: April 10, 2013 Original Article Detection of a New Strain of Wolbachia pipientis in Phlebotomus perfiliewi transcaucasicus, a Potential Vector of Visceral Leishmaniasis in North West of Iran, by Targeting the Major Surface Protein Gene *Parviz Parvizi 1, Farzaneh Fardid 1, 2, Somaieh Soleimani 1,2 1Molecular Systematics Laboratory, Department of Parasitology, Pasteur Institute of Iran, Tehran, Iran 2Department of Microbiology, Islamic Azad University of Qom-Branch, Qom, Iran (Received 18 Jan 2012; accepted 7 July 2012) Abstract Background: Wolbachia pipientis is maternally inherited endoparasitic bacterium belonging to the α-proteobacteria, infecting 20–75% of all insect species including sand flies. The Wolbachia surface protein (wsp) was employed as an appropriate marker for strain typing. The objective of our research was to find the possibility of detection of W. pipientis in Phlebotomus perfiliewi transcaucasicus. Methods: Individual sand flies were screened for the presence of W. pipientis. The obtained sequences were edited and aligned with database sequences to identify W. pipientis haplotypes. Results: Two haplotypes of W. pipientis were found in P. perfiliewi transcaucasicus. The common haplotype of W. pipientis was found to be identical to the sequences of those submitted in GenBank. New strain (haplotype) of W. pipientis was found novel. The sequence of new strain of W. pipientis occurs in P. perfiliewi transcaucasicus is very different from those already submitted in GenBank. Conclusion: Finding one genetically modified new strain of W. pipientis in P. perfiliewi transcaucasicus, now we can conclude that further documents and studies need to reach the role of cytoplasmic incompatibility of W. pipientis through wild sand fly populations to drive a deleterious gene into and to reduce the density of natural populations of Sand flies. Keywords: Wolbachia pipientis, Phlebotomus perfiliewi transcaucasicus, Leishmania infantum, Kala-azar, Iran Introduction Phlebotomus perfiliewi transcaucasicus transmits ‘infantile visceral leishmaniasis’ (IVL) in northwest of Iran to the east of Turkey which has a Mediterranean climate (Nadim et al. 1978, Parvizi et al. 2008, Fran- co et al. 2011, Mahamdallie et al. 2011). The intracellular Rickettsia-like bacterium Wolbachia pipientis Hertig has been de- tected in phlebotomine sand flies (Diptera: Psychodidae, Phlebotominae) using PCR to amplify a fragment of the major Wolbachia surface protein (wsp) gene (Zhou et al. 1998, Cui et al. 1999, Ono et al. 2001, Benlarbi and Ready 2003, Kassem et al. 2003, Parvizi et al. 2003). Wolbachia, are gram negative, polymor- phic and wide spread bacteria belonging to the family Anaplasmataceae within the order Rickettsiaceae, related to α-proteobacteria that infect reproductive tissues of many arthro- pods and nematodes. In addition, these bac- teria have been found in approximately 80% of insect species all over the world (Zhou et al. 1998, Cui et al. 1999, Benlarbi and Ready 2003, Kassem et al. 2003, Parvizi et al. 2003). Wolbachia are unique endosymbionts that is maternally inherited, intracellular Rickett- sia like bacteria which spread themselves to next generation, by transovarian transmission (Weeks et al. 2002, Benlarbi and Ready 2003). 46*Corresponding author: Dr Parviz Parvizi, E-mail: parp@pasteur.ac.ir J Arthropod-Borne Dis, June 2013, 7(1): 46–55 P Parvizi et al.: Detection of a New … http://jad.tums.ac.ir Published Online: April 10, 2013 This transmission is known as vertical transmission. Wolbachia has been implicated in causing reproductive manipulations on its hosts. They induce a number of reproduc- tive abnormalities that appear in their host phenotypes including cytoplasmic incompat- ibility (CI), parthenogenesis, feminization, male killing (Curtis and Sinkins 1998, Cui et al. 1999, Ono et al. 2001, Weeks et al. 2002). Cytoplasmic incompatibility is a common observed phenotype of Wolbachia, when in- fected populations of same species cross to each other, results may appear to be signs of incompatibility, unidirectional incompat- ibility or bidirectional incompatibility that can be completed or partial (Curtis and Sinkins 1998, Kassem et al. 2003). In case of an infected male mates with an uninfected female (or infected with an- other strain of Wolbachia, this cross is in- compatible and no offspring will be pro- duced (Unidirectional CI). In case of male and female pop- ulations are infected with more than one strain of Wolbachia, Bidirec- tional incompatibility will be observed (Braig et al. 1998, Werren 1998, Cui et al. 1999, Weeks et al. 2002, Kassem et al. 2003). There are four known forms of parthe- nogenesis that have been observed in dif- ferent types of insect species (Thelytoky, Pseudogamy, Automixis, Apomixis). They have different aspects but there was the same one in which female individual produc- es offspring without participation of male partner in mating. Parthenogenesis in insects can cover a wide range of mechanisms. Wolbachia induces a particular type of parthenogenesis in some species, called Thelytoky Parthenogenesis. By this action, Wolbachia causes duplication in gametes in some insects therefore the resulting off spring would be all female, they also carry the Wolbachia infection (Anonymous 1997). In addition, Wolbachia causes embryonic mortality of male zygotes in some arthro- pods. In addition, Wolbachia has horizontal transmission between different species of arthropods (O’ Neill et al. 1992, Breeuwer and Jacobs 1996, Braig et al. 1998). This transmission has been observed in groups of parasitic wasps that they were not infected with Wolbachia naturally, due to predating and feeding from a species of Drosophila, after a short period of time within the host cells of mentioned wasps, they have be- come infected with the same strain that was present in Drosophila species (Rousset and Solignac 1995). In addition, Wolbachia was found in Iso- pods, mites and nematodes. The following reasons can describe research on Wolbachia: the wide spread of bacteria, manipulations on its hosts and its role to make speciation, the affect of bacteria of host’s fertility and being a potential natural enemy or a vector. Useful genes can be synthesized by genetic engineering and then transferring both into Wolbachia and insect populations for bio- logical control which might cause decreas- ing arthropod transmitted diseases in human as a secondary reservoir (Curtis and Sinkins 1998, Turelli and Hoffmann 1999). The selection of Wolbachia surface pro- tein (wsp) gene has been due to free availa- bility of this protein at the surface of the bac- teria, ease of its identification, diversity of this gene in various genus and the possibility of usage of this gene for the purpose of stud- ying the evolutional relationship and phylo- genetic proximity of these groups of bacte- ria (Werren 1997, Bandi et al. 1998, Werren 1998, Sinkins and O’Neill 2000). The Wolbachia surface protein (wsp) gene is useful marker for strain typing (Stouthamer et al. 1999, Baldo et al. 2006). There are no reports of the bacterial wsp gene being iso- lated and being sequenced from the same in- dividual specimens of Phlebotomus perfiliewi transcaucasicus, in order to investigate the number of strains of W. pipientis infecting wild 47 J Arthropod-Borne Dis, June 2013, 7(1): 46–55 P Parvizi et al.: Detection of a New … http://jad.tums.ac.ir Published Online: April 10, 2013 populations of this insect. We have reached to beneficial consequences. This is now re- ported of P. perfiliewi transcaucasicus from an endemic of (IVL) in Iran, and it is an es- sential piece of information for detecting W. pipientis through the wild populations of this sand fly (BenIsmail et al. 1987, Seccombe et al. 1993, Benlarbi and Ready 2003, Parvizi et al. 2009). Materials and Methods Sand flies were collected from three lo- cations of Sarab and Kaleybar in the north- west of Iran in Azerbaijan Province as well as Meshkin Shahr in Ardabil Province us- ing CDC traps and sticky papers. Sand flies were dissected, head and genital termina- tion were kept for identifying of species based on morphological characters, thorax and abdomen were stored at -80 °C until fur- ther operations for DNA extraction fol- lowed PCR assays (Parvizi et al. 2003, Parvizi and Ready 2008). About 550 base-pairs (bp) (minus pri- mers) of the wsp fragment of Wolbachia Surface Protein were amplified by PCR using the primer pair wsp 81F (Forward) (5´TGGTCCAATAAGTGATGAAGAAA C3´) and wsp 691R (Reverse) (5´AAAAA TTAAACGCTACTCCA3´), PCR amplifi- cation was carried out according to the protocol of Benlarbi and Ready (2003). A 20l PCR reaction mixture consisted of 2l 1x Promega buffer, 2l MgCl2, 0.5l of each dNTP, 1l of each primer, 0.2l Taq DNA polymerase (Promega) and 2l of sand fly genomic DNA. The PCR amplification was carried out with the following thermal profile using a GeneAmp® PCR System 9700 thermal cycler (PE Applied Bio- systems): 2 min denaturation at 94 °C, 35 cycles of denaturation at 94 °C for 30 sec, annealing at 50 °C for 30 sec, extension at 72 °C for 1.5 min, and a final extension at 72 °C for 10 min (Benlarbi and Ready 2003, Parvizi et al. 2003). After amplification, the samples were fractionated by horizontal submerged gel electrophoresis, using 1.5% agarose gels and DNA size markers (Promega PCR markers G316A, or Bioline Hyper ladder IV). DNA fragments were visualized by ethidium bro- mide staining, then excised and purified using a Geneclean II Kit (BIO 101 Inc) be- fore cycle sequencing each strand. The se- quences obtained were edited and aligned with database sequences using Sequencher TM v. 3.1 software (Gene Codes Corp.) to identify unique sequences (=haplotypes), which were analyzed phylogenetically using PAUP* software (Swofford 2002). Results Five species of Larrossius subgenus and six species of Adlerius subgenus identified from three locations of Sarab, Kaleybar in north eastern of Azerbaijan province and Meshkin Shahr in Ardabil Province in north- west of Iran. Majority of sand fly species identified in these locations belonged to Phlebotomus and Paraphlebotomus subgen- era and Sergentomyia genus. Abundance of some species of Larrossius subgenus and Adlerius subgenus were very low but due to their importance in IVL transmission we tried to detect wsp gene of Wolbachia to all sand fly species (Table 1). In total 12 out of 183 sand flies were found infected with Wolbachia including 11 out of 41 P. perfiliewi transcaucasicus and one P. kandelakii. Two out of seven P. perfiliewi transcau- casicus were found infected with wsp gene in Sarab region in north east of Azerbaijan Prov- ince. Seventy three sandflies species belonged to other Larrossius and Adlerius species were examined for Wolbachia but no positive spec- imen was found for wsp gene in this focus. 48 J Arthropod-Borne Dis, June 2013, 7(1): 46–55 P Parvizi et al.: Detection of a New … http://jad.tums.ac.ir Published Online: April 10, 2013 Nine out of 24 P. perfiliewi trans- caucasicus were found infected with wsp gene in Kaleybar region in north east of Azerbaijan Province. Twenty two sandflies species were be longed to other Larrossius and Adlerius species which were tried to detect Wolbachia but no positive wsp gene was found in this region. Three of P. perfiliewi transcaucasicus were examined but no infection found with wsp gene in Meshkin Shahr in Ardabil Province in North West of Iran. One out 26 P. kandelakii was found infected with wsp gene in Meshkin Shahr in Ardabil Province but the band of PCR product in agarose gel was too weak to sequence. In total (12/183) 6.5% of all screened sand flies were positive with Wolbachia wsp gene that (2/81) 2.5% of these speci- mens were male and (10/102) 9.8% were female (Table 2). Only 9/11 (80%) positive PCR products of Wolbachia wsp gene in P. perfiliewi transcaucasicus contained enough DNA for direct sequencing. One haplotype of the wsp gene were recognized by aligning of new se- quences comparison with homologous ones from GenBank. The common haplotype of W. pipientis was found to be identical to the sequences of those submitted in GenBank (GenBank accession number EU780684), and it predom- inated in Iranian sand flies in- fected with this species (7/11 infections). New strain of W. pipientis (GenBank acces- sion number (JX488735) was found novel (2/11 infections). This new strain differs pairwise by 36 to 120 bp nucleotide posi- tions from those haplotypes of W. pipientis submitted in GenBank (GenBank Acces- sion Numbers AF237882, AY288297, HM 563686, HM775090) (Fig. 2). Fig. 1. Locations of Iranian provinces, cities and villages where Larrossius and Adlerius group sand fly species were sampled. (Villages: 1- Sheghlan, 2- Bastam lou, 3- Safar lou, 4- Aslanbagh lou, 5- Sarma lou, 6- Aylily, 7- Shekhm lou, 8- Olou gheshlagh, 9- Oliurdy, 10- Abdolrazagh, 11- Aghamir lou, 12- Molan, 13- Jou aghaj, 14- Ajoudan abad, 15- Agh miun, 16- Sahzab, 17- Hasan jan, 18- Sanzigh, 19- Razligh, 20- Ghalajough, 21- Dowlat abad, 22- Arzanagh, 23- Alni, 24- Ourkandi, 25- Mizan, 26- Mouyil, 27- Ghassabeh, 28- Aghbolagh, 29- Ghourt tappeh) 49 J Arthropod-Borne Dis, June 2013, 7(1): 46–55 P Parvizi et al.: Detection of a New … http://jad.tums.ac.ir Published Online: April 10, 2013 A rd ab il P ro vi n ce E as t A za rb ay ej a n P ro v in ce M es h k in sh ah r K al ey b ar S ar ab P .k an de la ki i P .t ob bi P .p er fi li ew i tr an sc au ca si cu s P .k es h is h ia n i P .m aj or P .s im ic i P .b re vi s P .h al ep en si s P .l on gi do ct u s P .b al ca n ic u s C h in en si s G ro u p Table 1. Wolbachia infections in two subgenus species using wsp gene in three endemic visceral leishmaniasis lo- cati- ons in North West of Iran Province / Region Subgenus Larrossius Adlerius Region Species Total Ghalajough 5 2 2 1 3 13 Razligh 2 2 6 10 Sahzab 1 6 (2+ve) 7 (2+ve) Sanzigh 2 3 1 6 Agh miun 1 3 4 Arzanagh 1 5 5 6 17 Hasan jan 2 2 4 8 Dowlat abad 4 2 7 1 1 15 Total 14 5 14 (2+ve) 0 2 7 1 21 0 1 15 80 (2+ve) Sheghlan 2 1 1 1 5 Bastam lou 1 1 Safar lou 1 1 Aslanbagh lou 3 4 7 Sarma lou 1 1 2 Aylily 6 (4+ve) 6 (4+ve) Shekhm lou 1 (1+ve) 3 4 (1+ve) Olou gheshlagh 4 (2+ve) 4 (2+ve) Oliurdy 2 1 3 Abdolrazagh 4 (2+ve) 2 6 (2+ve) Aghamir lou 1 1 Molan 1 2 1 4 Jou aghaj 1 1 Ajoudan abad 1 1 Total 10 0 24 (7+ve) 0 0 0 0 0 1 0 11 (2+ve) 46 (9+ve) Alni 1 3 2 6 Ourkandi 2 3 5 10 Mizan 3 5 3 11 Mouyil 9 9 Ghassabeh 2 1 3 Aghbolagh 4 (1+ve) 2 6 (1+ve) Ghourt tappeh 6 3 3 12 Total 26 (1+ve) 0 3 0 5 0 0 7 6 0 10 57 (1+ve) Total 29 Village 50 (1+ve) 5 41 (9+ve) 0 7 7 1 28 7 1 36 (2+ve) 183 (12+ve) 50 J Arthropod-Borne Dis, June 2013, 7(1): 46–55 P Parvizi et al.: Detection of a New … http://jad.tums.ac.ir Published Online: April 10, 2013 P. papatasi (EU780683) AGCTACTACGTTCGTTTGCAATACAACGGTGAATTTTTACCTCTTT-TCACAAAAGTTGA 59 P. perfiliewi AGCTACTATGTTCGTTTGCAATACAACGGTGAAATTTTACCTCTTTAT-ACAAAAGTTGA ********.************************.************.*.*********** P. papatasi (EU780683) TGGTGCTACAGGTGCTAAGAAGACTGCAGATACTGCTACAACTACT-GACCTTTATA-AA 117 P. perfiliewi TGGTATTACAAATG-TAA-CAG---GTA-A-A--G--AAAAGGA-TAGTCCCTTA-ACAA ****..****..**.***..**...*.*.*.*..*..*.**..*.*.*.**.***.*.** P. papatasi (EU780683) GCTTCTTTTATGGCTGGTGGTGGTGCATTTGGTTATAAAATGGACGACATCAGGGTTGAC 177 P. perfiliewi G-ATCTTTTATAGCTGGTGGTGGTGCATTTGGTTATAAAATGGACGACATTAGAGTTGAT *..********.**************************************.**.*****. P. papatasi (EU780683) GTTGAAGGGCTTTATTCGCAGCTAAGC-AAGGATGCA-CTTGCT-GTAGCTCCTACTCCA 234 P. perfiliewi GTTGAAGGGCTTTACTCACAATTG-GCTAAAGATACAGCT-G-TAGTAAATACTTCTGAA **************.**.**..*..**.**.***.**.**.*.*.***..*.**.**..* P. papatasi (EU780683) GCAA-T-T-GCAGACAGTTTAACAGCAATTTCAGGGCTAGTTAACGTTTATTACGATATA 291 P. perfiliewi ACAAATGTTGCAGACAGTTTAACAGCATTTTCAGGATTGGTTAACGTTTATTACGATATA .***.*.*.******************.*******..*.********************* P. papatasi (EU780683) GCAATTGAAGATATGCCTATCACTCCATACATTGGTGTTGGTGTTGGTGCAGCATATATT 351 P. perfiliewi GCGATTGAAGATATGCCTATCACTCCATACGTTGGTGTTGGTGTTGGTGCAGCATATATC **.***************************.****************************. P. papatasi (EU780683) AGCACA-CCTTTGGCAACTGCTG-TG-AGT-A--G-TCAAAATGGTAAATTTGCTTTTGC 404 P. perfiliewi AGCA-ATCCTT---CAAAAGCTGATGCAGTTAAAGATCAAAAAGG-A--TTTGGTTTTGC ****.*.****...***..****.**.***.*..*.******.**.*..****.****** P. papatasi (EU780683) TGGTCAAGCAAGAGCTGGTGTT 426 P. perfiliewi TTATCAAGCAAAAGCTGGTGTT *..********.********** Fig. 2. Alignment of the single wsp gene sequence of W. pipientis isolated from Iranian P. papatasi with the GenBank sequence EU780683 reported by Parvizi et al. (2009). Nucleotide differences are marked by a point, not a star Table 2. Wolbachia detection in sand flies screened by PCR using wsp gene in North West of Iran (+ve = Wolbachia positive) Location No. female sand flies screened by PCR No. +ve female sand flies +ve female sand flies% No. male sand flies screened +ve male sand flies +ve male sand flies% Total sand flies Total +ve sand flies Total +ve sand flies % Kaleybar 39 9 23.1 7 0 0 46 9 19.6 Sarab 29 0 0 51 2 3.9 80 2 2.5 Meshkin Shahr 34 1 2.9 23 0 0 57 1 1.7 Total 102 10 9.8 81 2 2.5 183 12 6.5 51 J Arthropod-Borne Dis, June 2013, 7(1): 46–55 P Parvizi et al.: Detection of a New … http://jad.tums.ac.ir Published Online: April 10, 2013 Discussion Recently, wsp gene has been used to im- prove phylogenetic resolution within the spe- cies clade of W. pipientis, which was divided into four groups (A–D) and 12 subgroups (Zhou et al. 1998, Ono et al. 2001). The groups A and B are concordant with those identified by 16S rDNA for the strains of W. pipientis from insects, mites and crustaceans, whereas groups C and D harbor the strains from filar- ial nematodes. Populations of P. perfiliewi transcaucasicus from Iran were screened and for the first time, W. pipientis were found in this sand fly. Two haplotypes including, one new haplotype were obtained from wsp gene (Fig. 2). The common widespread strain (GenBank ID: EU780683, AY288297) was the A-group strain of W. pipientis (wPap) but the new haplotype was indistinguishable from that of the Agroup strain of W. pipientis (wPap) pre- viously isolated from P. papatasi originating from Israel/West Bank (AF237883 (Ono et al. 2001) and India (GenBank accession num- ber AF237882 (Ono et al. 2001), as well as from Spain and Iran (Benlarbi and Ready 2003, Parvizi et al. 2003). From the three regions under study, 183 sand flies were selected in order of their ge- nus and diversities of types and regions. Wolbachia infection was detected in 1 case out of 57 samples in Meshkin Shahr (1.7%), 9 cases out of 46 samples in Kaleybar (19.6%), and 2 cases out of 80 samples in Sarab (2.5%) out of subgenus of Larroussius “Wolbachia Surface Protein genes”. Larroussius and Adlerius subgenus species were first identified as male because only males have good morphological characters of the head and abdominal terminalia for dif- ferentiation of species but females do not have this advantage. So it is obvious that this females are mates of that detected male gen- eses that were taken from this area (the males of these three species were taken from the given three regions, same as females) (Parvizi et al. 2003, Akhondi et al. 2012). Out of Adlerius subgenus, only two cases in female sand flies were infected by Wolbachia which had no morphological characters for identification of genus (as mentioned above), but the males had good morphological char- acteristics for identification. As in these re- gions, male sand flies of Adlerius subgenus “P. longiductus, P. halepensis, P. brevis, P. balcanicus, P. simici” have been found, the two cases of detected Wolbachia in female sand flies of Adlerius subgenus in Kaleybar region, could be of any of the above five men- tioned types. We would like to mention that all collected sand flies of above 5 mentioned species from Kaleybar were not examined because it was not the purpose of this paper. The selection of Wolbachia surface protein gene has been due to free availability of this protein at the surface of the bacteria, ease of its identification, diversity of this gene in various genus and the possibility of usage of this gene for the purpose of studying the evo- lutional relationship and phylogenetic prox- imity of these groups of bacteria (Werren 1997, Bandi et al. 1998, Werren 1998, Sinkins and O’Neill 2000). There is a natural Wolbachia infection in sand flies. Cytoplasmic incompatibility is the recognized phenotype in sand flies which have been shown to be infected with Wolbachia (McGraw et al. 2002, Rasgon 2003). Moreo- ver, it has been suggested that Wolbachia can prevent the carriage and transferring of par- asites and viruses via infected insects. In ad- dition, it is a unique unknown manner which allows Wolbachia to be a good selection and used as a transgene of the target genes and controlling the leishmaniasis which has been recently adapted among the population of sand flies (Breeuwer and Jacobs 1996, Werren 1998, Sinkins and O’Neill 2000, Brownstein et al. 2003). 52 J Arthropod-Borne Dis, June 2013, 7(1): 46–55 P Parvizi et al.: Detection of a New … http://jad.tums.ac.ir Published Online: April 10, 2013 As the existence of Wolbachia in many sand flies which carry cutaneous leishmaniasis agents of urban and rural types is not known, it is suggested that the existence of this bac- teria in other types of carriers of leishmaniasis is surveyed (Dobson et al. 2002). Wolbachia can be used as a transferring gene or transgene in insects. This can be done by designing and synthesizing of target genes by genetic engineering techniques and then to transfer them into Wolbachia genome the point at which proper genes of Wolbachia can be released to the mass of insects. It appears that the use of this technology would be very useful for the purpose of biologically control and combat against varieties of parasites and viruses of the region by employing arthro- pods (Werren 1998, Dobson et al. 2002, Mitsuhashi et al. 2002, Rasgon 2003). Acknowledgements The work was supported by the Pasteur Institute of Iran, grant 463 awarded to Dr Parviz Parvizi. The collections of sand flies were made possible by the assistance of the Centre of Health Service in Kaleybar and Sarab, Azerbaijan Province as well as Meshkin Shahr in Ardabil Province. We thank Mehdi Baghban for help with the field work and Elnaz AlaeeNovin for help in Molecular Sys- tematics Laboratory. 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