J Arthropod-Borne Dis, September 2017, 11(3): 354–362 H Hoosh-Deghati et al.: Composition of Anopheles … 354 http://jad.tums.ac.ir Published Online: September 08, 2017 Original Article Composition of Anopheles Species Collected from Selected Malarious Areas of Afghanistan and Iran Helen Hoosh-Deghati 1,2, *Navid Dinparast-Djadid 2, *Vahideh Moin-Vaziri 1, Hoda Atta 3, Abbas Ali Raz 2, Seyyed Javad Seyyed-Tabaei 1, Naseh Maleki-Ravasan 2, Hamzeh Alipour 2, Sedigheh Zakeri 2, Eznollah Azar-Gashb 1 1Department of Parasitology, School of Medicine, Shahid Beheshti University of Medical Sciences, Tehran, Iran 2Malaria and Vector Research Group, Biotechnology Research Center, Pasteur Institute of Iran, Tehran, Iran 3Malaria Control, Word Health Organization/Eastern Mediterranean Regional Office, Cairo, Egypt (Received 3 June 2016; accepted 9 Jan 2017) Abstract Background: Malarious areas in Iran are close to Afghanistan and Pakistan that urge the researchers to extend their knowledge on malaria epidemiology to the neighboring countries as well. Vectorial capacity differs at species or even at population level, the first essential step is accurate identification of vectors. This study aimed to identify Anopheles species composition in selected malarious areas of Afghanistan and Iran, providing further applied data for other re- search in two countries. Methods: Adults Anopheles spp. were collected from four provinces in Afghanistan (Badakhshan, Herat, Kunduz, Nangarhar) by pyrethrum spray catch, hand collection methods through WHO/EMRO coordination and from Chabahar County in Iran by pyrethrum spray catch method. Identification was performed using reliable identification key. Results: Totally, 800 female Anopheles mosquitos, 400 from each country were identified at species level. Anopheles composition in Afghanistan was An. superpictus, An. stephensi and An. hyrcanus. Most prevalent species in Badakh- shan and Kunduz were An. superpictus, whereas An. stephensi and An. hyrcanus were respectively found in Nangarhar and Heart. Anopheles species in Chabahar County of Iran were An. stephensi, An. fluviatilis, An. culicifacies and An. sergentii. The most prevalent species was An. stephensi. Conclusion: Current study provides a basis for future research such as detection of Plasmodium infection in collected samples which is on process by the authors, also for effective implementation of evidence-based malaria vector inter- vention strategies. Keywords: Anopheles, Morphological identification, Afghanistan, Iran Introduction Malaria is known as one of the six im- portant infectious diseases based on WHO (1). It is caused by the protozoon Plasmodium spp and transmitted by female Anopheles mosquitoes (2). Anopheles spp belongs to Cu- licidae family (Diptera) with 460 or so differ- ent species that 70 of them have the potential of being malarial vectors, however, around 36 species are considered as main ones (3, 4, 5). About 198 million cases of malaria occurred in 2013, leading to 584000 deaths (6). Glob- ally, around 3.2 billion people are at risk of being infected with malaria and 1 in 1000 is at high risk of getting malaria in year (1). In Eastern Mediterranean regions (EMR), more than 10 million clinical malaria cases occur annually with 50 thousands death. Generally 287 million which is approximately 60% of Eastern Mediterranean population is at the risk of malaria infection (1, 7, 8). Malaria is of great importance from public health concerns in Iran, more than 2 million *Corresponding authors: Dr Navid Dinparast- Djadid, E-mail: navidmvrg@gmail.com, Dr Vahideh Moin-Vaziri, E-mail: vmvaziri@gmail.com http://jad.tums.ac.ir/ mailto:navidmvrg@gmail.com J Arthropod-Borne Dis, September 2017, 11(3): 354–362 H Hoosh-Deghati et al.: Composition of Anopheles … 355 http://jad.tums.ac.ir Published Online: September 08, 2017 people live at high risk regions (7). Iran with population of more than 78 million people is located in West Asia sharing a border of 1458 and 936km respectively with Iraq from the west, Afghanistan, and Pakistan from the east (9). Malaria is endemic in the South and Southeast of Iran, where more than 90 percent of malaria cases are reported (10, 12). These regions are bordered with Pakistan and Af- ghanistan which malaria cases due to P. falci- parum and P. vivax are prevalent. Malaria has an unstable pattern varying between 42% up 60% of total malaria cases with two seasonal peaks mostly in spring and autumn after the rainy seasons in the provinces located in South-East of Iran comprising Sistan and Ba- luchistan, Hormozgan and the tropical part of Kerman (13). Recently a notable reduction has been observed in malaria cases due to the re- port of Ministry of Health and Medical Edu- cation of Iran, which has led WHO to catego- rize Iran in the elimination phase (14). Nation- wide campaign malaria elimination was launched by Iranian Government in 2010 in epidemic regions with the goal of becoming malaria-free country by 2025 (12, 14). Vector control is the most efficient way to decrease the malaria transmission at the com- munity level. Regarding to the recent Iranian mosquitoes checklist, seven different genera, 64 species and 3 subspecies are reported (15). Seven species of the genus Anopheles includ- ing An. culicifacies Giles s.l., An. dthali Pat- ton, An. fluviatilis James s.l., An. maculipennis Meigen s.l., An. sacharovi Favre, An. stephensi Liston, and An. superpictus Grassi are identi- fied as malarial vectors in Iran. Six species are known as its vectors in southeast of Iran: An. culicifacies, An. stephensi, An. dthali, An. flu- viatilis, An. pulcherrimus, and An. superpictus. Among them, An. stephensi is the main vector of malaria in the area and considerably prefers human blood (16, 13, 12). In Afghanistan, approximately half of the population is at the risk of malaria. There are at least six malaria vectors in Afghanistan: Anopheles superpictus, An. culicifacies, An. hy- cranus, An. pulcherrimus, An. fluviatilis and An. stephensi (17). Full understanding of malaria vectors can be considered as a key factor in malaria con- trol programmes. The first step in any control program is the vector species identification. Moreover, malaria endemic areas in Iran are close to Afghanistan and Pakistan, urging us to extend our research to the neighboring coun- tries as well. Anopheles species were collected from se- lected malarious areas of Afghanistan (Ba- dakhshan, Herat, Kunduz, and Nangarhar) lo- cated in high risk areas (18, 19) by WHO. This study aimed to identify Anopheles species composition in selected malarious areas of Afghanistan and Iran, providing further ap- plied data for other research in two countries. Results presented here reflect the composition of Anopheles species of mentioned collection as a part of ongoing project. It could provide also useful information in planning and imple- menting of an effective program for vector control during elimination phase in Iran and control phase in Afghanistan for the national malaria control program. Materials and Methods Study areas Afghanistan: Afghanistan is a landlocked country in south central Asia (33° 00’ N, 65° 00’ E). Its climate is arid to semiarid with fre- quent sand storms. The northern and south- eastern areas of the country have very rugged mountain terrains (Hindu Kush), while the western and southern parts are flat deserts and plains. Climate varies according to the eleva- tion and location. In general, malaria occurs at altitude below 2,000m and is the most preva- lent in snow-fed river valleys and rice grow- ing areas (20). Samples were collected from four counties, located in different geograph- ical sites of Afghanistan, North-East (Badakh shan and Kunduz), South-East (Nangarhar) and http://jad.tums.ac.ir/ J Arthropod-Borne Dis, September 2017, 11(3): 354–362 H Hoosh-Deghati et al.: Composition of Anopheles … 356 http://jad.tums.ac.ir Published Online: September 08, 2017 Western part close to Iran boundary (Herat) (Fig. 1). Iran: Sistan and Baluchistan Province as the main malarious area is located in the Northern coast of Persian Gulf and Oman Sea, where the weather is warm and humid enough for Anopheles species to be activated throughout the year (7). This study took place in Chabahar County (25° 17’ N, 60° 38’ E), bounded by Pakistan in the east, Hormozgan Province in the west, Kerman Province in the north, and Oman Sea in the south. It has a warm and humid weather in summer and temperate in winter. The aver- age maximum and minimum temperature are respectively 34 ˚C and 10.5 ˚C in July and January. Latitude from the sea level is 7m. The annual rainfall is low mainly in spring and autumn so that it has a desert climate. However it has high humidity due to neigh- boring sea (Fig. 1) (21). Mosquito collection and identification Adult Anopheles spp were collected on August 2011 through WHO/EMRO coordi- nation from four provinces of Afghanistan (Badakhshan, Herat, Kunduz, Nangarhar) by pyrethrum spray catch, hand collection method using manual aspirator and from Chabahar County in Iran by pyrethrum spray catch meth- od (Table 1). The sampling sites are indicated on Fig. 1. The species identification was per- formed by using reliable identification key (22) under Leica EZ4D (16X) stereomicroscope. Resuts Morphological identification of Afghanistan Anophelinae mosquitoes A total of 400 adults female Anopheles were collected from Herat, Nangarhar, Badakhshan and Kunduz provinces of Afghanistan (Table 1). Among the collected specimens, 3 species were identified based on the morphological charac- teristics, 45% of total specimens belong to An. superpictus collected from Badakhshan and Kunduz. Totally 180 An. superpictus were col- lected from mentioned areas, with pyrethrum spray catch (PSC) and hand collection, among them 141 (78.3%) collected from human house. The major morphological characteristics of this species are having unusually long palps (Fig. 2A), no dark spots at point of bifurcation of 5th longitudinal vein and equal division part of the second and forth vein to the end of wing (Fig. 2B). Next species was An. hyrcanus which was gathered by PSC method from an- imal and human house in Herat. Totally 110 (27.5%) was identified, which mainly col- lected from human house (63%). In An. hyr- canus fore margin of wing has less than four light and four dark bands alternating (Fig. 3A), fore margin of the wing with two small white spots, one near the tip, the other about two thirds of the way from the root of the wing (Fig. 3B). Third identified species was An. stephensi (27.5%), which was sampled from the human house of Nangarhar by PSC method. This spe- cies could be easily characterized by white spots which speckled on femora and tibiae (Fig. 4 A, B). Morphological identification of Anopheline mosquitoes of Chabahar County (Iran) Morphological characteristic of 400 adults female Anopheles specimens collected from two villages of Chabahar County, Iran, re- vealed the presence of 4 different species (Ta- ble1). Regardless the kind of species, all spec- imens was collected from human house and by PSC method. The most prevalent species among them was An. stephensi (94.75%), which its main morphology character was mentioned previously. The other species were An. fluviatilis (2.75%), An. culicifacies (1.5%) and An. sergentii (1%). Anopheles culicifacies has been identified based on the following main characters, existence of two fringe spots, no tuft of scales on anterior margin of mesonotum and finally existence of a dark spots opposite to the light spot at the costa http://jad.tums.ac.ir/ http://mississippientomologicalmuseum.org.msstate.edu/collecting.preparation.methods/aspirator.htm J Arthropod-Borne Dis, September 2017, 11(3): 354–362 H Hoosh-Deghati et al.: Composition of Anopheles … 357 http://jad.tums.ac.ir Published Online: September 08, 2017 base (Fig. 5). Anopheles fluviatilis has palps with usual length (Fig. 6A), dark spot at the point of bifurcation of the 5th vein and farther division part of the second vein than the forth vein with respect to the end of wing (Fig. 6B). Anopheles sergentii characteristics include more than two light spots on the posterior margin of fringe with pale base of subcostal and no dark spot of sub-costal opposite to the pale spot of costa (Fig. 7). Table 1. Details of collected specimens based on study areas and collection methods: PSC: Pyrethrum Spray Catch, HC: Hand Collection by manual aspirator, HC: Hand Collection, HH: Human House, AH: Animal House Total Total number of species Anopheles spp Number of Mosquitoes Collection methods and Sites Village Province 400 110 (27.5%) An. hyrcanus 70 PSC-HH (Indoor) Haja Sourma Herat A fg h a n is ta n 30 PSC-AH (Indoor) 110 (27.5%) An. stephensi 55 PSC-HH (Indoor) Pol-e tar- acheh Nangarhar 55 Ali khan 100 (25%) An. superpic- tus 39 PSC-AH (Indoor) Darewazer Badakhshan 37 HC-HH (Indoor) 24 PSC-HH (Indoor) 80 (20%) An. superpic- tus 80 PSC-HH (Indoor) Gerghiz Kunduz 400 379 (94.75%) 11 (2.75%) 6 (1.5%) 4 (1%) An. stephensi An. fluviatilis An. culicifa- cies An. sergentii 100 PSC-HH (Indoor) Owraki Chabahar Ir a n 300 PSC-HH (Indoor) Baloch- adam Fig. 1. Map of Iran and Afghanistan, indicating the location of the study area in Chabahar County (marked with an asterisk) situated in the south of Sis- tan and Baluchistan in Iran and Herat, Kunduz, Ba- dakhshan, Nangarhar provinces in Afghanistan. Fig. 2. Anpheles superpictus, A: Head with long palps B: No dark spot at point of bifurcation of 5th vein and division part of the second and forth vein to the end of wing is equal http://jad.tums.ac.ir/ J Arthropod-Borne Dis, September 2017, 11(3): 354–362 H Hoosh-Deghati et al.: Composition of Anopheles … 358 http://jad.tums.ac.ir Published Online: September 08, 2017 Fig. 3. A: existence at least dark spot at the upper margins of the swings, which is common in all Anopheles except An. hyrcanus B: An. hyrcanus, fore margin of the wing with two small white spots Fig. 4. Anopheles stephensi, A, B: Femora and tibiae speckled with white spots Fig. 5. Anopheles culicifacies, first vein with a dark spot opposite the light spot at the base of costa Fig. 6. Anopheles fluviatilis, A: usual length of palps B: spot at the point of bifurcation of the 5th vein and division part of the second vein is farther than the forth vein to the end of wing Fig. 7. Anopheles sergentii, no dark spot on sub-costa Discussion Malaria is widespread in the tropical and subtropical regions of the world and is also a public health problem in western extensions of the oriental zoogeographical region includ- ing Iran, Afghanistan and Pakistan. Accord- ing to WHO report, 9 of the 97 countries with ongoing malaria transmission, including Iran, are classified as being in the malaria elimination phase. At this stage, interventions focus on the detecting all malaria cases, managing malaria foci, managing imported malaria cases and pre- venting onward transmission (23). Regarding the latest reports, it should be intentioned that, different Anopheles species even different pop- http://jad.tums.ac.ir/ J Arthropod-Borne Dis, September 2017, 11(3): 354–362 H Hoosh-Deghati et al.: Composition of Anopheles … 359 http://jad.tums.ac.ir Published Online: September 08, 2017 ulation of one species, have different ecolo- gies, biological attributes and vectorial capac- ities (24). Then, exact species identification is necessary for better understanding of their po- tential roles in malaria transmission (25, 12). In Iran the most problematic malarious ar- eas is south and southeast of the country, which highly affected by the epidemiology of malaria in neighboring countries, Afghanistan and Pakistan. The following reasons support this consumption 1. Afghanistan is in control phase of the malaria control, compared to Iran which is in elimination phase (14), 2. similar- ity of Anopheles fauna and human causative agents of malaria, both P. falciparum and P. vivax are prevalent in both countries and 3. importance of immigration from Afghanistan and Pakistan to malarious areas of Iran is the major routes of malaria transmission. This sit- uation urges us to conduct current study, con- centrating on morphological characters of Anopheles and their composition within se- lected areas of Afghanistan and Iran. Taxon- omy that utilizes morphological characteriza- tion has been known as the gold standard method in identifing the mosquito species, which also have been used in current study for identification of five anopheline species in the study areas of Iran and Afghanistan, includ- ing known malaria vector species. All the species which were identified during current study previously was reported in the checklist of Iranian mosquito fauna (15). The most prevalent species among our collected specimens from Chabahar was An. stephensi playing a dominant role in transmission of ma- laria in Persian Gulf as well in south of Iran (26, 27). This species is considered as an en- dophage and endophile mosquito. Sporozoite rate of this species was reported between 0.2 and 1.8% in south of Iran (26, 28) Other col- lected species were An. culicifacies, An. fluvi- atilis and An. sergenti; the first two types are also important as secondary vectors in the South and South-East of the country (3, 12). Among secondary vectors, An. culicifacies can be regarded as potential vector, as it is greatly responsible for the epidemy of ma- laria in Sistan and Baluchistan Province (29). Sporozoite rate of this species is varied be- tween 1–4.7% in south malarious areas of Iran (3, 12). Although it is mainly known as zoophilic Anopheles, its anthropophilic index is reported as 16.4% (30). Anopheles culicifa- cies has also a wide distribution in Asia and Indian subcontinent (31). Anopheles fluviatilis, distribution at altitude 50–1100m, along the foothills of the Zagros Mountains and exten- sion to South and South-East of Iran as a sec- ondary vector, its sporozoite rate was re- ported between 1.4–11% (3, 12). Anopheles sergentii is also prevalent in different prov- inces of Iran, acting as secondary vector and responsible for maintaining the parasite res- ervoir in malarious areas. In Afghanistan, totally three species were identified among collected specimens, re- ported previously in mosquito fauna of this country (32). Comprising An. superpictus, An. stephensi and An. hyrcanus, which are all known vectors of malaria (33). Anopheles su- perpictus has a broad geographical distribution in Asia, Europe and Africa considered as a malaria vector in these areas (13, 12). It was collected from Badakhshan and Kunduz lo- cated in northeast of Afghanistan as it was re- ported previously (34). Moreover, the only species which was recently reported by Ah- mad et al. from the Badakhshan was An. su- perpictus (35). Although during current study, this species was not found among the col- lected specimens of Chabahar, but it is com- monly widespread in Iran in altitudes 50– 2000m. Sporozoite rate of mentioned species is 0.65–4.7% in Iran (36, 3). Anopheles ste- phensi was collected mainly from Nangarhar Province in human house and mainly were blood-fed. As mentioned, this species is an important vector of human malaria in the Middle East and South Asia including Indo- Pakistan sub-continent (16). The third species in the study area was An. hyrcanus. It is a mem http://jad.tums.ac.ir/ J Arthropod-Borne Dis, September 2017, 11(3): 354–362 H Hoosh-Deghati et al.: Composition of Anopheles … 360 http://jad.tums.ac.ir Published Online: September 08, 2017 ber of the Hyrcanus group comprising of 30 species, some of them are vectors of malaria, filariasis and arboviruses (37, 38). It is con- sidered as the fauna of bloodsucking mosqui- toes of Afghanistan (32, 17), also its potential role as malaria vector was reported from France, Turkey, Greece and Afghanistan (32, 39). This species has already been reported in the North and North-East of Iran (40), and is suspected to transmit malaria in Fooman Dis- trict located in the north of Iran (41). This study presents some limitations that may reflect the article. Mosquito collection was performed in a limited time and areas of Iran and Afghanistan due to the shortage of research time and lack of facilities, so alt- hough results are worthy enough for the other basic research, but could not regarded as a representative of a faunistic or eco-epidemio- logical study. Conclusions Obtained results provide baseline infor- mation for other researchers and it reveals val- uable information for designing further stud- ies on vectorial capacity and detection of Plasmodium species and the status of insecti- cide resistance within collected Anopheles spp which is undergoing by the authors. Fur- thermore, it could be useful for designing, im- plementation and evaluation of local and re- gional evidence-based malaria control program. Acknowledgements This work is a part of WHO/EMRO grant to NDD. 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