J Arthropod-Borne Dis, December 2013, 7(2): 122–131 M Akhoundi et al.: Molecular Characterization of … http://jad.tums.ac.ir Published Online: August 31, 2013 Original Article Molecular Characterization of Leishmania Infection from Naturally Infected Sand Flies Caught in a Focus of Cutaneous Leishmaniasis (Eastern Iran) Mohammad Akhoundi 1, 2, Ahmad Baghaei 2, *Jérôme Depaquit 1, Parviz Parvizi 2 1Université de Reims Champagne-Ardenne, ANSES, EA4688-USC «Transmission vectorielle et épidémiosurveillance de maladies parasitaires (VECPAR)», Faculté de Pharmacie, Département de la parasitologie, Reims, France 2Pasteur Institute of Iran, Department of Parasitology, Molecular Systematic Laboratory, Tehran, Iran (Received 15 Feb 2012; accepted 16 March 2013) Abstract Background: Cutaneous leishmaniasis due to Leishmania major is a serious and increasing problem affecting many rural areas of 17 out of 31 provinces in Iran. Little is known about sand fly fauna and leishmaniases in Eastern Iran and no study has been carried out in Sarbisheh County. The aim of this study was to determine sand flies composi- tion and probable Leishmania infection to find the probable vectors of leishmaniasis in Sarbisheh district. Methods: Sand flies were caught using both sticky papers and CDC light traps in August 2010. They were identified morphologically and analyzed for Leishmania infection by amplification of ITS-rDNA. Results: Totally, 842 specimens were caught and 8 species recorded. They belonged to the genera Phlebotomus and Sergentomyia: P. (Phlebotomus) papatasi, P. (Paraphlebotomus) sergenti, P. (Pa.) caucasicus, P. (Pa.) mongolensis, P. (Pa.) jacusieli, S. (Sergentomyia) dentata, S. (Se.) sintoni and S. (Sintonius) clydei. All collected females were processed for Leishmania DNA detection by PCR amplifying of Internal Transcribed Spacer1 (partial sequence), 5.8S (complete sequence) and ITS2 (partial sequence) fragments. Thirteen females were positive for Leishmania DNA. The sequencing of the 430 bp amplicons indicated that 9 P. papatasi and 3 females belonging to the Caucasicus group carried L. major DNA whereas one P. sergenti carried L. tropica DNA. Conclusion: Phlebotomus papatasi and P. sergenti are, like in several places, the probable vectors of cutaneous leishmaniases in this emerging or unknown focus of cutaneous leishmaniases. Keywords: Leishmania major, Leishmania tropica, ITS-ribosomal DNA, Iranian Sand fly Introduction Cutaneous Leishmaniases (CL) due to Leish- mania major Yakimoff and Schokhor, 1914 and L. tropica Wright, 1903 (Kinetoplastida: Trypanosomatidae) occur serious increasing health problems in Iran, affecting mainly rural areas in 17 out of 31 provinces in Iran (Yaghoobi-Ershadi 2012). The most important foci are due to L. major. They are endemic and are located in Turkemen Sahara and Lotf Abad in north east of Iran, Abardejh, Esfa- han and Yazd districts in center of Iran, Fars and Sistan v Baluchestan provinces in south and south east, Ilam and Khuzestan provinces in south west of the country (Nadim and Seyedi-Rashti 1971, Javadian et al. 1998, Yaghoobi-Ershadi et al. 2005, Nekouie et al. 2006, Oshaghi et al. 2010). In Iran, as in many foci located all over the world, the main vector of L. major is P. papatasi Scopoli, 1786 (Nadim and Seyedi- Rashti 1971, Yaghoobi-Ershadi et al. 2005, Parvizi and Ready 2008). However, other species belonging to the subgenus Phlebo- tomus or females belonging to the Caucasicus group have also been reported as vectors of L. major, the latter especially as secondary vectors in areas where P. papatasi is not recorded, or at low densities (Nadim and *Corresponding author: Prof Jérôme Depaquit, E- mail: jerome.depaquit@univ-reims.fr 122 J Arthropod-Borne Dis, December 2013, 7(2): 122–131 M Akhoundi et al.: Molecular Characterization of … http://jad.tums.ac.ir Published Online: August 31, 2013 Seyedi-Rashti 1971, Yaghoobi-Ershadi et al. 1994). L. tropica is mainly transmitted by P. sergenti Parrot, 1917 (Oshaghi et al. 2010). Despite the report of several new foci of cutaneous leishmaniases in Iran and the po- tential spread of the disease in the country according to the Iranian authorities, leish- maniases were unknown in the province of Khorasan-e-Jonoubi till now. According to the report of the Ministry of Health, 417 new cases of CL were reported from Khorasan-e- Jonoubi in 2009. An increase of 4% was rec- orded in 2010 compared to 2009 (Iran Min- istry of Health and Medical Education 2010). In the present study, Phlebotomine sand flies were sampled in Sarbisheh County bor- dering Afghanistan (Fig. 1). According to our knowledge, no entomological or epidemi- ological study has been carried out in this region. The aim of this study was to carry out a pilot study on the sand fly species com- position in the prospected area and to have a look on their Leishmania infection. Materials and Methods Phlebotomine sand flies sampling was car- ried out from 18th to 27th August, 2010, in Sarbisheh county in East of Iran, 58˚48' N and 32˚34' E, at an altitude of about 1800 meters above sea level (Fig. 1). The climate in this area bordering Afghanistan is mild and dry. The highest temperature in summer, 40 degrees above zero and the lowest in winter, 23 degrees below zero. The normal annual rainfall is 228 mm in Sarbisheh County. During the collection period, the average minimum and maximum tempera- tures were 31˚C and 39 ˚C while the mean humidity was 54%. In this cross-sectional study, sampling was done in rural regions of Sarbisheh County during 10 summer nights. We selected two catching methods: sticky papers and CDC miniature light traps. The goal of our study was not to collect data of the relative abundance of the species, that could be done by using sticky papers, but to mix two trapping methods in order to maximize the opportunity to catch all the species from a prospected location, photophilic or not. Sticky papers consist of white sheets 21x 29.7 cm coated with castor oil placed in different habitats and various biotopes: in- doors, animal shelters, and outdoors (scuppers, wall cracks, burrows, and vegetation). They were put on the ground with a stick, or rolled into cones and placed in the interstices of stone walls, in walls made of clay, or placed vertically in cracks, crevices and large boul- ders. CDC miniature light traps were put in the same locations. All these traps were installed before sunset and remained func- tional throughout the night until the next morning. Sand flies specimens were stored in 96% ethanol and kept in refrigerator (-20 ˚C) for further analysis. After recording the sampling data and lo- cations, sand fly specimens were washed in 1% detergent then in sterile distilled water. Each specimen was then dissected in fresh drop of sterile normal saline by cutting off the head and genitalia with sterilized ento- mological needles, then were mounted in Berlese medium and identified using the identification key of Theodor and Mesghali (1964). We considered the females of P. caucasicus Marzinovsky, 1917 and P. mongolensis Sinton, 1928 indistinguishable (Artemiev and Neronov 1984, Parvizi et al. 2010). All these females were identified as “Caucasicus group”. Thorax, abdomen, legs and wings were stored in the sterile 1.5 ml microtube, then frozen and defrosted twice to break up tissue using a sampler tips or pestle, with grinding mix. Then SDS mix was used to denature proteins associated with the DNA, and then ice cold 8 M potas- sium acetate was added to effectively re- move the SDS-bound proteins from solution. Cell debris and proteins were separated from the DNA by centrifugation and the DNA in 123 J Arthropod-Borne Dis, December 2013, 7(2): 122–131 M Akhoundi et al.: Molecular Characterization of … http://jad.tums.ac.ir Published Online: August 31, 2013 the supernatant was precipitated over night at -20 ˚C in 96% ethanol. Following ethanol precipitation, the DNA was dissolved in 1X- TE (10 mM Tris–HCl, 1 mM EDTA PH 8.0) and stored at 4 ˚C. Leishmania DNA was detected in Phlebo- tomine sand flies by amplification of the first Internal Transcribed Spacer of the ribosomal DNA (partial sequence), 5.8S ribosomal RNA gene (complete sequence) and Internal Tran- scribed Spacer 2 (partial sequence) that able to detect L. major and L. tropica. This frag- ment was amplified using the forward (ITS1F) and reverse (ITS2R4) primers (Parvizi and Ready 2008). The length of PCR band was 430 bp for L. major and L. tropica. Double distilled water and DNA from L. major and L. tropica were used as negative and positive controls for each batch of PCR. Standard PCR was performed in a 45 µl volume using extracted DNA solution 5 µ l, 10X buffer 4 µ l, MgCl2 2.4 µ l, dNTPs 4 µ l, Taq polymerase 0.4 µ l, DDW 28.6 µ l and 0.3 µ l from each forward (ITS1F: 5′- GCAGCTGGATCATTTTCC-3′) and reverse (ITS2R4: 5′-ATATGCAGAAGAGAGGAGGC-3′) primers and according to the PCR Ther- mocycler program for Leishmania parasite (Parvizi and Ready 2008). Amplicons were analyzed by electrophoresis in 1.5% agarose gel containing ethidium bromide. PCR products were sequenced both direc- tions directly using the ITS1F and ITS2R4 primers which used for DNA amplification. Sequences compared to homologous se- quences in GenBank thanks to the nucleo- tide-nucleotide Basic Local Alignment Search Tool (BLAST: www.ncbi.nlm.nih.gov/BLAST). Strains were considered as identified at the species level when their sequence showed ≥99 % homology with a sequence deposited in GenBank. Sequences were also aligned with BioEdit v7.0.0 software (Hall 1999) for comparison. Results A total of 842 sand flies were collected: 574 by sticky papers and 268 by CDC min- iature light traps (Table 1). Five species be- long to the genus Phlebotomus: Phlebotomus (Phlebotomus) papatasi Scopoli, 1786, P. (Paraphlebotomus) sergenti Parrot, 1917, P. (Pa.) caucasicus Marzinovsky, 1917, P. (Pa). mongolensis Sinton, 1928 and P. (Pa.) jacusieli Theodor, 1947 and also 3 species belong to the genus Sergentomyia: S. (Sergentomyia) dentata Sinton, 1933, S. (Se.) sintoni Pringle, 1953 and S. (Sintonius) clydei Sinton, 1928 (Fig. 2). The captured specimens by sticky papers show that P. papatasi is the most abundant species in this area (33%) followed by P. sergenti (22%) and S. sintoni (13%). The other species have relative abundances less than 10% (Table 1). The genus Phlebotomus (77.9%) is more abundant than the genus Sergentomyia (22.1%). The sex ratios show more males than females: 1.1 for the genus Phlebotomus and 1.9 for the genus Ser- gentomyia. The majority of these caught female specimens are unfed and gravid. Of 268 specimens caught by CDC minia- ture light traps, the most prevalent sand fly species was P. papatasi (45%) followed by P. sergenti (26%). The sex ratios show more females than males (1.05) for the genus Phlebotomus and fewer females than males (0.75) for the genus Sergentomyia. Most of the sand flies were collected from outdoor places (463: 55%) and in animal shelters (320: 38%). A few specimens have been caught indoors (59: 7%): P. papatasi, P. sergenti, Caucasicus group and S. sintoni. Of the specimens caught outdoors, 21 P. caucasicus/Caucasicus group, 19 S. clydei, 21 S. sintoni and 14 S. dentata were captured in rodent burrows. The females consisted of 368 out of 842 (43.7%) caught specimens. Nine out of 151 (6%) female P. papatasi and three out of 60 124 J Arthropod-Borne Dis, December 2013, 7(2): 122–131 M Akhoundi et al.: Molecular Characterization of … http://jad.tums.ac.ir Published Online: August 31, 2013 (5%) female Caucasicus group were infected by L. major and one out of 90 (1.1%) female P. sergenti tested for Leishmania DNA was also positive for L. tropica infection using the Standard PCR method. Each one of these specimens produced 430 bp band (Fig. 3). There was not any infected sample of female Sergentomyia sand flies in this study. Fig. 1. Villages prospected in Sarbisheh County (Eastern Iran) Fig. 2. Phlebotomus jacusieli caught in Sarbisheh. Female pharynx (A) and spermathecae (B), male coxite and style (internal view) (C) 125 J Arthropod-Borne Dis, December 2013, 7(2): 122–131 M Akhoundi et al.: Molecular Characterization of … http://jad.tums.ac.ir Published Online: August 31, 2013 Table 1. Caught samples of sand fly from different rural regions and various habitats of Sarbisheh County in Eastern Iran County Village H ab it at T ra p t yp e T ot al Phlebotomus Paraphlebotomus Sergentomyia P. papatasi P. sergenti P. caucasicus P. mongolensis caucasicus group P. jacusieli S. sintoni S. dentata S. clydei ♂ ♀ ♂ ♀ ♂ ♂ ♀ ♂ ♀ ♂ ♀ ♂ ♀ ♂ ♀ Sarbisheh Gongan A S 6 5* 4 1 3 3 1 _ _ 4 2 1 1 2 1 34 C 2 4 2 3 _ _ 1 _ _ 1 1 _ 2 _ _ 16 H S 2 1 1 _ _ _ _ _ _ 2 _ _ _ _ _ 6 C 1 1 1 _ _ _ _ _ _ _ _ _ _ _ _ 3 O S 9 6* 4 3 2 3 3 2 _ 6 2 2 1 2 1 46 C 2 5 2 4 1 2 _ _ _ 1 1 _ 3 1 _ 22 Zusk A S 5 6 4 5 2 1 2 _ _ 2 1 1 1 1 1 32 C 2 _ 3 3 _ _ 1 _ _ 1 _ _ 1 1 1 13 H S _ 1 2 1 _ _ _ _ _ 1 _ _ _ _ _ 5 C 1 _ _ _ _ _ _ _ _ _ _ _ _ _ _ 1 O S 8 4 6 7 2 4 3 2 1 4 1 2 _ 2 _ 46 C 4 4 4 3 2 2 1 _ _ _ 1 1 1 _ _ 23 Mud A S 6 3 2 3 3 2 2 _ _ 3 2 _ _ 2 2 30 C 3 2 3 2 _ _ _ _ _ 1 1 _ 1 _ 1 14 H S _ _ _ _ _ _ _ _ _ 2 _ _ _ _ _ 2 C 2 1 _ _ _ _ _ _ _ _ _ _ _ _ _ 3 O S 7 4 6 3 2 3 4 2 _ 2 3 2 1 3 1 43 C 5 5 2 3 1 1 1 _ _ 1 1 1 _ _ _ 21 Janat abad A S 5 3 5 3 1 2 2 _ _ 2 1 1 1 1 1 28 C 4 7 2 2 _ _ 1 _ _ _ _ 1 _ 1 _ 18 H S 3 2 2 _ _ _ 1 _ _ _ _ _ _ _ _ 8 C 1 _ _ 2 _ _ _ _ _ _ _ _ _ _ _ 3 O S 8 5* 6 5 1 3 3 _ _ 3 2 3 1 2 _ 42 C 3 5 2 3 1 1 1 _ _ 1 _ 1 _ _ _ 18 Sarbisheh A S 4 6 3 1 2 2 2 _ _ 3 1 1 _ 1 2 28 C 3 3 3 2 1 _ 1 _ _ 1 _ 1 _ _ _ 15 H S 3 3 1 _ _ _ _ _ _ 1 _ _ _ _ _ 8 C 1 1 1 1 _ _ _ _ _ _ _ _ _ _ _ 4 O S 9 4 5 6** 1 2 3 _ _ 4 2 1 2 2 1 42 C 2 5* 3 2 1 1 2 _ _ 2 _ 1 _ 1 _ 20 Salm Abad A S 5 4 4 1 _ _ 3 _ _ 3 1 2 _ 2 _ 25 C 3 4 2 1 1 1 1 _ _ 1 1 _ _ _ _ 15 H S 3 _ _ 1 _ _ 1 _ _ 1 _ _ _ _ _ 6 C 1 _ 1 _ _ _ _ _ _ _ _ _ _ _ _ 2 O S 4 7* 5 6 2 2 6* 1 1 3 2 1 1 2 1 44 C 3 5* 2 2 1 1 1 _ _ 2 _ _ _ _ 1 18 Asadieh A S 7 9* 3 2 1 1 4* _ _ 2 1 2 1 _ 1 34 C 4 8 1 _ 1 1 2 _ _ _ _ _ _ _ 1 18 H S 2 2 _ _ _ _ 1 _ _ 1 _ _ _ _ _ 6 C 1 1 _ _ _ _ _ _ _ _ _ _ _ _ _ 2 O S 11 9* 8 7 2 3 5* 2 1 4 1 2 1 2 1 59 C 6 6* _ 2 1 1 1 _ _ 1 _ _ _ 1 _ 19 Total 161 151 105 90 35 42 60 9 3 66 28 27 19 29 17 842 A: Animal Shelter, H: House, O: Outdoor, S: Sticky Paper, C: CDC miniature light trap *: includes specimens infected by L. major **: includes specimen infected by L. tropica 126 J Arthropod-Borne Dis, December 2013, 7(2): 122–131 M Akhoundi et al.: Molecular Characterization of … http://jad.tums.ac.ir Published Online: August 31, 2013 Fig. 3. Gel electrophoresis profile of the standard PCR based amplification products. The bands correspond to molecular weight marker (Lane1), control negative (Lane 2), reference strains of L. major (Lane 3) and L. tropica (Lane 4), P. papatasi (Bir-733: Lanes 5 and Bir-803: Lane 6), caucasicus group (Bir-211: Lane 7, Bir-341: Lane 8 and Bir-624: Lane 9) and P. sergenti (Bir-797: Lane 10) Discussion Little is known about sand fly fauna in Khorasan-e-Jonoubi Province. Several inves- tigations have previously been carried out on the sand flies fauna in Khorasan district e.g. in Meshed, Lotf Abad, Esfarayen and Neishabur counties (Mesghali et al. 1967, Nadim et al. 1971, Javadian et al. 1976, Nadim and Tahvildar-Biruni 1977). Nadim et al. (1971) reported a list of sand fly species caught in the mountains and plains of Khorasan district. They consisted of 12 species of Phlebotomus and 9 Sergentomyia. Out of the mentioned sand flies, some species were found only in the mountains and the caves (P. major, S. pawlovskyi). Others species were found both in mountains and in flat areas: P. mongolensis, P. caucasicus, P. mofidii, P. ansarii, P. kandelakii in the north Khorasan, P. kazeruni, P. eleonorae, S. christophersi, S. tiberiadis and S. mervinae near the central desert in the south of the central desert in the south of Khorasan district. Nadim and Seyedi-Rashti (1972) have studied the sand fly fauna of the western part of the Khorasan district and recorded nine Phlebotomus and 10 Sergentomyia species: P. papatasi, P. sergenti, P. caucasicus, P. alexandri, P. kazeruni, P. jacusieli, P. eleonorae, P. major, P. chinensis, S. sintoni, S. dentata, S. mervynae, S. grekovi, S. sumbarica, S. squamipleuris, S. pawlovskyi, S. clydei, S. tiberiadis and S. christophersi. Moreover, P. papatasi, P. sergenti, females belonging to the Caucasicus group (P. mongolensis and P. caucasicus), S. clydei and S. sintoni have been found infected by promastigotes (Nadim and Seyedi-Rashti 1972). Our findings are in accordance with the pre- vious investigations carried out in this district (Nadim et al. 1971, Nadim and Seyedi-Rashti 1972). Since the 70’s, no investigation has been carried out in this province and the Sarbisheh County has never been prospected. Nine P. papatasi females and three females belonging to the Caucasicus group carried L. major DNA according to the BLAST pro- cess. The sequences obtained from the pre- sent study have been deposited in Genbank under accession numbers JN541326 to JN541337. These are identical or highly sim- 127 J Arthropod-Borne Dis, December 2013, 7(2): 122–131 M Akhoundi et al.: Molecular Characterization of … http://jad.tums.ac.ir Published Online: August 31, 2013 ilar to several sequences deposited in Gen- Bank, including isolates from Iran and Friedlin references (Friedlin FR796423, Iran AY260965, AY283793, EF413075, GQ402544, GQ402543, GQ466354 and GQ466350). The sequence of ITS-rDNA obtained from the female P. sergenti (accession number: JN541338) is similar (99% homology) to those L. tropica that previously have been deposited in GenBank from two regions of Iran: Shiraz (HM060588, HM060589, HM060590) (Oshaghi et al. 2010) and Kaleybar (EU604811, EU604813) (Parvizi and Ready 2008). Investigation on the reservoirs of zoonotic cutaneous leishmaniasis (ZCL) was previ- ously carried out by Seyedi-Rashti and Nadim (1967) in two regions of Khorasan district: Meshed (and its suburbs) and Lotf Abad. They mentioned Rhombomys opimus as the main reservoir of CL in the endemic focus of the rural type in Lotf Abad region. Later, rodent reservoirs of CL were studied in Meshed, Lotf abad, Sarakhs and Esferayen districts (Nadim and Seyedi-Rashti 1972, Javadian et al. 1976) and Rhombomys opimus was again reported as the main reservoir. The reservoirs of ZCL in Khorasan-e-Jonoubi Province due to insufficient studies in men- tioned rural regions are not very clear. It seems that R. opimus is the main reservoir in this region as well as Khorasan district. In our study, 3 infected specimens by L. major have been captured in rodent burrows. Two of them were P. papatasi and the third one belonged to the Caucasicus group. Sarbisheh County is located in the north of Sistan v Balouchestan Province, in border of Afghanistan. This area is separated from the central parts of Iran by deserts (Dasht-e-Kavir in north-east and Dasht-e-Loot in south-east). Several investigations have been carried out in Sistan and Balouchestan both on vectors and reservoirs of cutaneous leishmaniases in some regions of this province (Kassiri et al. 2011a, 2011b, 2012). Kassiri et al. (2011a) reported five species as proven (P. papatasi) or probable (P. salehi, P. sergenti, P. alexandri and P. keshishiani) vectors of cutaneous and visceral leishma- niasis in this province. They showed the role of P. papatasi and P. salehi in maintenance and transmission of L. major to humans and reported Meriones hurrianae and Tatera indica as the probable reservoirs of ZCL (Kassiri et al. 2011b, 2012). To our knowledge, no study has been car- ried out on the leishmaniases in the province of Khorasan-e-Jonoubi. However, it seems that illegal immigration with low sanitary conditions occurs from Afghanistan and Pa- kistan, two countries where CL are endemic (Bhutto et al. 2009, Ruiz Postigo 2010) to Sarbisheh County. Consequently, there is a potential risk of leishmaniasis outbreak in this area, according to the presence of numer- ous P. papatasi and P. sergenti, in this area. Several investigations show various ratios of females P. papatasi infected by L. major in following districts: 19.8% in Shiraz (Oshaghi et al. 2010), 15.6% in Badrood (Yaghoobi- Ershadi et al. 2005), 6.5% in Baft (Oshaghi et al. 2008), 11% in Damghan (Rassi et al. 2011), 12.5% in Shahrood (Abaei et al. 2007), 22.1% in Abardejh (Nekouie et al. 2006), 12.7% in Rafsanjan (Yaghoobi-Ershadi et al. 2010) and 2.1% in Chabahar (Kassiri et al. 2012). Our findings indicates 9 out of 151 (6%) P. papatasi carrying L. major DNA, constitute a relatively low level. Concerning the females belonging to the Caucasicus group, 4.2 to 7.5% of the speci- mens were infected by L. major in several studies carried out in Borkhar, Ahar, Damghan and Shahrood districts (Yaghoobi- Ershadi et al. 1994, Rassi et al. 2004, Abaei et al. 2007, Rassi et al. 2011). In the present study, 3 out of 60 (5%) of females belonging to Caucasicus group have been found posi- tive for L. major DNA, ranking these speci- mens in the mean of reported range in the mentioned areas of the country. 128 J Arthropod-Borne Dis, December 2013, 7(2): 122–131 M Akhoundi et al.: Molecular Characterization of … http://jad.tums.ac.ir Published Online: August 31, 2013 Cutaneous leishmaniasis due to L. tropica occurs in a vast distribution areas of the world. Its cycle varies between localities and generally does not require a sylvatic reservoir. Several surveys report the isolation of L. tropica from P. sergenti, its classical vector (Al-Zahrani et al. 1988, Oshaghi et al. 2010). However, in the middle-east, an atypical focus transmitted by P. (Adlerius) arabicus with reservoirs (hyraxes) has been recorded very close to classical focus (Svobodova et al. 2006). In eastern Africa, the subgenus Larroussius can also been implicated in the transmission of L. tropica (Lawyer et al. 1991). In Iran, L. tropica CL was first described in Tehran by Schlimmer several decades before the discovery of the parasite. Some of the most important foci of this disease are Teh- ran in center, Meshed in North-East, Shiraz and Kerman in south of Iran (Nadim and Seyedi-Rashti 1971). Our pilot study reports a sand fly inventory showing that P. papatasi and P. sergenti are abundant species. The detection of L. major and L. tropica from the latter shows their local role in the transmission of the disease in emerging or previously unknown foci of cutaneous leishmaniases. There is lack of knowledge in the pro- spected county about the local reservoirs and human prevalence and incidence. 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