4. Iran J Arthropod-Borne Dis, 2011, 5(1): 20–27 A Sanei Dehkordi et al.: Molecular Detection of … 20 Original Article Molecular Detection of Leishmania infantum in Naturally Infected Phlebotomus perfiliewi transcaucasicus in Bilesavar District, Northwestern Iran A Sanei Dehkordi1, *Y Rassi1, MA Oshaghi 1, MR Abai1, S Rafizadeh2, MR Yaghoobi- Ershadi1, M Mohebali 3, Z Zarei1, F Mohtarami1, B Jafarzadeh4, A Ranjbarkhah4, E Javadian1 1Department of Medical Entomology and Vector Control, School of Public Health, Tehran University of Medical Sciences, Iran 2Emergency Management Center (EMC) Ministry of Health and Medical Education, Iran 3Department of Parasitology and Mycology, School of Public Health, Tehran University of Medical Sciences, Iran 4Health Center of Bilesavar, Ardebil Province, Iran (Received 16 Aug 2010; accepted 19 Feb 2011) Abstract Background: Visceral leishmaniasis is caused by Leishmania infantum, transmitted to humans by bites of phle- botomine sand flies and is one of the most important public health problems in Iran. To identify the vector(s), an investigation was carried out in Bilesavar District, one of the important foci of the disease in Ardebil Province in northwestern Iran, during July−September 2008. Methods: Using sticky papers, 2,110 sand flies were collected from indoors (bedroom, guestroom, toilet and stable) and outdoors (wall cracks, crevices and animal burrows) and identified morphologically. Species-specific amplifica- tion of promastigotes revealed specific PCR products of L. infantum DNA. Results: Six sand fly species were found in the district, including: Phlebotomus perfiliewi transcaucasicus, P. pa- patasi, P. tobbi, P. sergenti, Sergentomyia dentata and S. sintoni. Phlebotomus perfiliewi transcaucasicus was the dominant species of the genus Phlebotomus (62.8%). Of 270 female dissected P. perfiliewi transcuacasicus, 4 (1.5%) were found naturally infected with promastigotes. Conclusion: Based on natural infections of P. perfiliewi transcaucasicus with L. infantum and the fact that it was the only species found infected with L. infantum, it seems, this sand fly could be the principal vector of visceral leishmaniasis in the region. Keywords: Leishmania infantum, Phlebotomus perfiliewi transcuacasicus, nested PCR, Iran Introduction Leishmaniases are parasitic diseases of mul- tifaceted clinical manifestations caused by in- fections with species of Leishmania. These dis- eases are widespread in the Old and New Worlds with great epidemiological diversity. Approximately, 700 species of sand flies are known but only 10% of these serve as disease vectors. Further, only about 30 species are im- portant from a public health standpoint (WHO 1990, Desjeux 2000, Sharma 2008). Visceral leishmaniasis (VL), commonly caused by Leishmania infantum in the Medi- terranean region, the middle east and Latin America, affects approximately half a million new patients each year (Lachaud 2002). In the Mediterranean basin, domestic dogs (Canis fa- *Corresponding author: Dr Yavar Rassi, E-mail: rassiy@sina.tums.ac.ir Iran J Arthropod-Borne Dis, 2011, 5(1): 20–27 A Sanei Dehkordi et al.: Molecular Detection of … 21 miliaris) are the principle reservoir host and some species of sand-flies belonging to the subgenus Larroussius are the primary vectors (Oshaghi et al. 2009a). Although VL occurs sporadically through- out Iran, the disease is endemic in several parts of northwestern Iran (Nadim et al. 1978, Davies et al.1999, Mohebali et al. 1999, Rassi et al. 2004, 2005, 2009, Oshaghi et al. 2009b). The rate of infected sand flies in endemic areas and the identification of the infecting Leishma- nia parasites in the determined phlebotomine species are of prime importance in vectorial and epidemiological studies of leishmaniasis (Rod- riguz et al. 1994). Three sand fly species, Phle- botomus perfiliewi transcaucasicus, P. (Lar- roussius) kandelakii Shchurenkova and P. (Lar- roussius) major Annandale are proven vectors in Iran (Rassi 2004, 2005, Azizi et al. 2008). Two other species, P. (Larroussius) keshi- shiani Shchurenkova and P. (Paraphlebotomus) alexandri Sinton have been found naturally in- fected with promastigotes and are suspected vectors of VL in the country (Seyyedi-Rashti et al. 1963, Schönian et al. 2003, Azizi et al. 2006). Leishmania parasites are directly detected by microscopic examination and all Leishmania species are very similar and their species identification is not possible morphologically (Schönian et al. 2003, Oshagi et al. 2009a) therefore we used nested PCR and PCR- RFLP methods in this study, because the main advantages of these methods are their sensi- tivity and specificity, independently of the num- ber, stage and localization of the parasite in the digestive tract of the vector (Perez et al. 1994). This study was carried out during Jul-Sep 2008 in rural areas of Bilesavar District, Arde- bil Province, in northwestern Iran, to detect and identify Leishmania infection in sand flies. Materials and Methods Study area The study was carried out in three villages of Gunpapagh, Odlu and Nazaralibalaghi, Bile- savar District, in northwestern Iran at an alti- tude of 1311 m (Fig.1). The total population of the Bilesavar was about 55000 in 2008. The climate is very hot (up to 40°C) in the summer and quite cold (-27° C) during the win- ter. The summers are short, lasting from mid May to mid September. The main activities of the people are agriculture and animal husbandry. Sand fly collection Sand flies were collected biweekly from indoors (bedroom, guestroom, toilet and stable) and outdoors (wall cracks and crevices and animal burrows) using sticky papers (100 pa- pers per village, 50 papers in outdoors and 50 papers indoors) during July−September 2008. Collected sand flies were removed from sticky papers using needles or fine brushes, dipped in 70% ethanol, were stored in 96% ethanol, and kept in -20 ºC before dissection. Sandfly identification The sandfly specimens were washed in 1% detergent then twice in sterile distilled water. Each specimen was then dissected in fresh drop of sterile normal saline by cutting off the head and abdominal terminalia with sterilized for- ceps and single used mounted needles. The re- mainder of the body was stored in the sterile Eppendorf microtubes for DNA extraction. Specimens were mounted in Puri’s medium and identified using the identification keys of Theo- dor and Mesghali (1964) and Lewis (1982). DNA extraction DNA was extracted by using the Bioneer Genomic DNA Extraction Kit. Extraction was carried out by grinding of individual sand flies in a microtube using glass pestle and followed by kit protocol and stored at 4°C. Detection and identification of Leishmania species Initial screening of sand flies was per- formed by nested-PCR amplification of ki- netoplast DNA (kDNA) using the protocol and primers (Table 1) already explained by Noyes Iran J Arthropod-Borne Dis, 2011, 5(1): 20–27 A Sanei Dehkordi et al.: Molecular Detection of … 22 et al. (1996). Amplification was carried out in two steps, both in the same tube. This PCR is able to identify promastigote infection of sand flies by producing a 680 bp for L. infantum/L. donovani, 560 bp for L. major, and a 750 bp for L. tropica. Further identification of the Leishmania parasites was done by using the ITS1-PCR (El Tai et al., 2000) followed by HaeIII di- gestion of the resulting amplicons described by Schonian et al. (2003). The set of primers (Ta- ble 1) forward LITSR and reverse L5.8S was used to amplify 340 bp of rDNA including parts of 3’ end of 18S rDNA gene, complete ITS1, and part of 5’ end of 5.8S rDNA gene. All of the amplification reactions were ana- lyzed by 1–1.5% agarose gel electrophoresis, followed by ethidium bromide staining and visualization under UV light. Standard DNA fragments (100 bp ladder, Fermentas) were used to permit sizing. PCR products (15 µl) were digested with HaeIII without prior purification using con- ditions recommended by the supplier (Cina- gen, Tehran, Iran). The restriction fragments were subjected to electrophoresis in 2% aga- rose and visualized under ultraviolet light after staining for 15 min in ethidium bromide (0.5 µg/ml). HaeIII digestion of ITS1 PCR re- veals two fragments of 220 and 140 bp for L. major, the fragments of 200, 80 and 60 bp for L. donovani complex, and two fragments of 200 and a 60 bp for L. tropica. Results Altogether, 2,110 sand flies were collected and identified including P. perfiliewi transcau- casicus (62.8%) , P. papatasi Scopoli (19.1%), P. tobbi Adler and theodor (3.9%), P. ser- genti (10%), S. dentata Sinton and (1.8%), S. sintoni Pringle (2.4%). Among the collected specimens 433 females belonging to six spe- cies were screened for Leishmania infections (Table 2). Only 4 of 270 P. perfiliewi tran- scaucasus (1.5%) were observed to be natu- rally infected with L. infantum using nested PCR against minicircle kDNA molecules with 680 bp (Fig. 2). Furthermore ITS1 amplifica- tion by PCR primers followed by PCR-RFLP technique confirmed the L infantum DNA in two infected P. perfiliewi transcaucasus with 340 bp (Fig.3). ITS1-PCR products were di- gested by HaeIII, for the Leishmania charac- terization. Since the length of PCR products for different species is different, for example, it is 360 bp for L. major and 340 bp for L. in- fantum, therefore the RFLP pattern is po- lymorphic for each species. The fragments of 220 and 140 bp for L. major, and the frag- ments of 200, 80 and 60 bp for L. infantum and two fragments of 200 and 60 bp were observed for L. tropica were diagnosed (Fig. 4). This is the first report of naturally infected of P. perfiliewi transcaucasus to L. infantum in Bilesavar District, Northwestern Iran. Table 1. Primers used in this study kDNA First step CSB2XF(forward): 5´-CGAGTA GCAGAAACTCCCGTTCA-3´ CSB1XR(reverse): 5´-ATTTTTCGCGATTTTCGCAGAACG-3´ Second step 13Z(forward): 5´ (ACTGGGGGTTGGTGTAAAATAG-3´ LIR(reverse): 5´-TCGCAGAACGCCCCT-3´ ITS1 LITSR(forward): 5´-CTGGATCATTTTCCGATG-3´ L5.8S (reverse): 5´-TGATACCACTTATCGCACTT-3’ Iran J Arthropod-Borne Dis, 2011, 5(1): 20–27 A Sanei Dehkordi et al.: Molecular Detection of … 23 Table 2. Fauna and PCR results of collected sand flies in Bilesavar District, 2008 Leishmania species No of Infected Female Male Species ITS kDNA (%) NO (%) NO L. infantum 2 4 62.35 270 62.91 1055 P. perfiliewi trancaucasicus P. papatasi 356 21.22 47 10.85 0 0 ــــــــــــــــ P. sergenti 179 10.67 33 7.62 0 0 ــــــــــــــــ P. tobbi 45 2.69 35 8.09 0 0 ــــــــــــــــ S. sintoni 17 1.01 34 7.85 0 0 ــــــــــــــــ S. dentate 25 1.5 14 3.24 0 0 ــــــــــــــــ 2 4 100 433 100 1677 Total Fig. 1. Map of the study area located in Ardebil Province Fig. 2. kDNA PCR amplification of Leishmania stocks and L. infantum in P. perfiliewi transcaucasicus using nested- PCR. Lane N, Negative control, Lanes1, 2, 3 represent L. infantum in P. perfiliewi transcaucasicus (680 bp) and Lane 4 L. infantum (680 bp) positive control, M: 100 bp size marker (Fermentas) Iran J Arthropod-Borne Dis, 2011, 5(1): 20–27 A Sanei Dehkordi et al.: Molecular Detection of … 24 Fig. 3. Electerophoresis results of ITS1-RCR from Leishmania stocks and L. infantum in P. perfiliewi transcaucasicus, Lane N, negative control, Lanes 1, 2 represent L. infantum in P. perfiliewi transcaucasicus (340 bp), Lanes 3, 4 represent L. infantum positive controls (340 bp), M: 100 bp size marker (Fermentas) Fig. 4. Restriction fragment length polymorphism (RFLP) patterns obtained from Leishmania stocks and L. infantum in P. perfiliewi transcaucasicus, Lanes 1, 2 and 4 represent L. major, L. tropica and L. infantum reference stocks respectively, Lane 3 is L. infantum in P. perfiliewi transcaucasicus, M: 50 bp size marker (Fermentas) Discussion Control of leishmaniasis depends on eco- logical and epidemiological information per- taining to the disease such as identification of preferred hosts and detection of natural infec- tions in the vector(s). Finding naturally infected wild-caught specimens that are anthropophilic fulfills two essential requirements for incrimi- nating a sand fly vector (Killick-Kendrick 1990). In endemic areas where more than one Leish- mania species is present, diagnostic tools are required for the detection of parasites directly in samples and distinguish all relevant Leishma- nia species (Schönian et al. 2003). Charac- terization of Leishmania species is important, because different species may require special remedial method. On the other hand, such in- formation is also valuable in epidemiologic studies where the distribution of Leishmania species in hosts and insect vectors is a urgent item in the controlling programs (El Tai et al. 2000, Schönian et al. 2003). Recently, mo- Iran J Arthropod-Borne Dis, 2011, 5(1): 20–27 A Sanei Dehkordi et al.: Molecular Detection of … 25 lecular techniques (PCR) have been employed for vector incrimination of sand flies (Oshaghi et al. 2009a). The highly sensitive technique of PCR has been used for detecting Leishma- nia in sand flies in many endemic areas in- cluding Iran and India (Azizi et al. 2006, De Bruijn and Barker 1992, Oshaghi et al. 2009b, Mukherjee et al. 1997, Rassi et al. 2004, 2005, 2009). In the present study, infection of P. perfiliewi transcaucasicus by L. infan- tum was confirmed using molecular meth- ods. It needs to mention that P. perfiliewi transcaucasicus was first found naturally in- fected with L. infantum in Germi District (other important focus of VL) adjoining to our study area (with 30 kilometers distance) in northwestern Iran (Rassi et al. 2009).Our study in Germi District showed that, 1.1% of dissected P. perfiliewi transcaucasicus sand flies were positive to L. infantum with 36.5% hematophagy preference to human (Anthro- pophilic Index) indicating a strong prefer- ence for human blood (Rassi et al. 2009). The apparent secondary preference of this species for dogs (23.5%), the main domestic reservoir of disease, may indicate that this species also plays an important role in trans- mission of VL to dogs (Rassi et al. 2009). Based on high density of P. perfiliewi transcaucasicus, natural infected with Leish- mania infantum, and high degree of anthro- pophily, it seems that that P. perfiliewi tran- scaucasicus could be the principal vector of VL in Bilesavar District northwestern Iran. Phlebotomus kandelakii was the first sand fly incriminated as a vector of VL in Mesh- ginshahr city in northwestern Iran (Rassi et al. 2005). The high prevalence of P. perfiliewi transcaucasus revealed by this study is con- sistent with the reports of Lewis (1982) on the distribution of this species in Iran and the Republic of Azerbaijan, adjoining to our study area. This is the first report incriminating P. perfiliewi transcaucasicus as the main vector of VL due L. infantum in the region. Acknowledgements We are grateful to staff of Bilesavar Health center for providing facilities to conduct this research and cooperation in the field sampling. 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