Seasonal Prevalence of Mosquitoes, Including Vectors of Brugian Filariasis, in Southern Islands of the Republic of Korea

Article information

Korean J Parasito. 2011;49(1):59-64

Publication date (electronic) : 2011 March 18

doi : https://doi.org/10.3347/kjp.2011.49.1.59

Hyeng-Il Cheun ¹, Shin-Hyeong Cho ¹, Hee-Il Lee ², E-Hyun Shin ², Jong-Soo Lee ¹, Tong-Soo Kim ¹^,³, Won-Ja Lee ¹

¹Department of Malaria & Parasitic Diseases, National Institute of Health, Seoul 122-701, Korea.

²Department of Medical Entomology, National Institute of Health, Seoul 122-701, Korea.

³Department of Parasitology, College of Medicine, Inha University, Incheon 400-712, Korea.

Corresponding author (ilcheun7@korea.kr)

Received 2010 April 30; Revised 2010 December 31; Accepted 2011 January 04.

Abstract

A survey of mosquitoes, including the vector status of Brugia malayi filariasis and their relative larval density, was conducted from 2002 to 2005 at several southern remote islands of Jeollanam-do (province), Gyeongsangnam-do, and Jeju-do, Korea, where filariasis was previously endemic. Overall, a total of 9 species belonging to 7 genera were collected. Ochlerotatus togoi (formerly known as Aedes togoi), Anopheles (Hyrcanus) group, and Culex pipiens were the predominant species captured at all areas. Oc. togoi larvae were most frequently collected at salinity levels <0.5% during June and July, with densities decreasing sharply during the rainy season in August. The most likely explanation for the eradication of filariasis in these areas is suggested to be an aggressive treatment program executed during the 1970s and the 1990s. However, high prevalence of the vector mosquitoes may constitute a potential risk for reemerging of brugian filariasis in these areas.

Keywords: Ochlerotatus togoi (=Aedes togoi); Anopheles (Hyrcanus) group; vector; brugian filariasis; southern islands

INTRODUCTION

The identification of vector species and their relative population densities is important for a better understanding of the transmission of zoonotic and human pathogens and the epidemiology of emerging and reemerging diseases. In the Republic of Korea, lymphatic filariasis was prevalent in the inland areas of Gyeongsangbuk-do (do=province) and coastal and southern areas of Jeollanam-do and Jeju-do. However, the prevalence of filariasis has decreased sharply due to medical treatments of microfilaria-positive patients and increased use of mosquito nets [1-5]. The islands of Heuksan, Sinan-gun (county), Jeollanam-do, were identified as endemic foci of fila-riasis in the mid-1980s (mean microfilaria positive rate: 12.5%). However, the positive rate in endemic regions dropped to 0%, and it was finally reported that filariasis had been eradicated from Korea [6].

Ochlerotatus togoi (formerly known as Aedes togoi) is the primary vector of lymphatic filariasis along the coastal areas of Jeju-do and other southern islands, whereas Anopheles sinensis sensu stricto, associated with rice paddies, is found in inland areas [3,7]. In these regions, however, vector mosquitoes and their larval densities have not been fully studied. There is also little information on their distribution and relative population densities of filariasis vectors and other mosquitoes in previous endemic areas. In the present study, mosquito surveillance was conducted to identify relative distributions and population den-sities of filariasis vectors in previous endemic areas in Korea.

MATERIALS AND METHODS

Survey areas

The southern islands of Jeollanam-do (Sa-ri [ri=village] and Sim-ri, Heuksan Islands in Sinan-gun, 2002; Baekdo-ri, Bogil Island in Wando-gun, 2003; Geomun-ri, Geomun Island in Yeosu-si [si=district], 2004), Gyeongsangnam-do (Maejuk-ri, Maemul Island in Tongyoung-si, 2004), and Jeju-do (Island) (Wimi-ri, Seoguipo-si, 2005) were surveyed (Fig. 1).

Fig. 1

Areas surveyed for adult and immature mosquitoes during 2002-2005.

Adult mosquito surveillance

Adult mosquitoes were collected twice weekly using the commercial Black Hole® mosquito black light trap (Model: Black Hole, Bio-trap Inc., Seoul, Korea). The traps were placed under the eaves of houses from 19:00 to 06:00 hr the following morning. All mosquitoes were identified to the genus or species level under a dissecting microscope using standard morphological keys [8,9].

Larval surveillance

The meshed sinking quadrat method [3,7] was used to estimate the relative larval density of Oc. togoi. Briefly, 5 quadrats (size: 100 cm²) were placed in each rock pool for 5 min and then removed simultaneously. Salinity was measured at the surface with a salinometer (SINAR NS-3P, Merbabu Trading Co., LTD, Tokyo, Japan). Larvae in each quadrat were counted, number recorded, and then identified under a dissecting microscope using standard morphological keys [8,9].

RESULTS

Sa-ri and Sim-ri, Heuksan Island, Sinan-gun

There were a mean of 347.0 mosquitoes collected from each trap at Sa-ri village on Heuksan Island (Table 1). Among the 4 genera and 5 species collected, Culex pipiens (45.8%) was the most frequently collected, followed by Oc. togoi (41.2%), An. (Hyrcanus) Group (6.3%), Culex tritaeniorhynchus (5.8%), and Armigeres subalbatus (0.9%). The number of Oc. togoi peaked in August, then decreased markedly thereafter. There were a trap mean of 359.0 mosquitoes from 5 genera and 7 species collected from Sim-ri (Table 2). The collection rates were as follows: Cx. pipiens, 56.3%; Oc. togoi, 31.2%; Cx. tritaeniorhynchus, 8.9%; An. (Hyrcanus) Group, 1.7%; Ar. subalbatus, 1.4%; Culex bitaeniorhynchus, 0.3%; and Tripteroides bambusa, 0.3%. The density of mosquitoes and their seasonal prevalence were similar to those of Sa-ri on Heuksan Island.

Table 1.

Seasonal variations of mosquitoes collected in mosquito traps in Sa-ri, Heuksan Island (latitude 34˚39´N, longitude 125˚25´E), Sinan-gun, Jeollanam-do in 2002

Table 2.

Seasonal prevalence of mosquitoes collected in mosquito traps in Sim-ri in Heuksan Island (latitude 34˚39´N, longitude 125˚25´E), Sinan-gun, Jeollanam-do in 2002

Baekdo-ri, Bogil Island, Wando-gun

A trap mean of 876.0 mosquitoes, comprising 4 genera and 8 species were collected from Baekdo-ri on Bogil Island (Table 3). Oc. togoi (41.2%), a vector of filariasis in shoreline areas, was the most frequently collected, followed by An. (Hyrcanus) group (26.5%), Cx. tritaeniohynchus (16.6%), Cx. pipiens (7.8%), Ar. subalbatus (7.6%), Aedes dorsalis (0.2%), Aedes albopictus (0.1%), and Cx. bitaeniorhynchus (0.1%). O. togoi increased sharply during the rainy season from June through July, followed by a marked decline in numbers through October. The number of An. (Hyrcanus) group was very low in June, which rapidly increased in July and August, and decreased in October.

Table 3.

Seasonal variation of adult mosquitoes collected in mosquito traps in Baekdo-ri, Bogil Island (latitude 34˚08´N, longitude 126˚32´E), Wando-gun, Jeollanam-do in 2003

Geomun-ri, Geomun Island, Yeosu-si

A trap mean of 56.2 mosquitoes belonging to 3 genera and 5 species were collected (Table 4). While Oc. togoi comprised of 85.4% of all mosquitoes, relatively low numbers of other mosquitoes were collected.

Table 4.

Seasonal variation in mosquitoes collected by black light trap in Geomun-ri (latitude 34˚17´N, longitude 127˚23´E), Geomun Island, Yeosu-si, Jeollanam-do in 2004

Maejuk-ri, Maemul Island, Tongyeong-si

A total of 98.7 mosquitoes belong to 3 genera and 4 species were collected (Table 5). Oc. togoi comprised of 98.6% with the highest numbers collected from May to July (range 17.9-25.8) and October (15.7).

Table 5.

Seasonal variation in mosquitoes collected by black light trap in Maejuk-ri (latitude 38˚38´N, longitude 128˚34´E), Maemul Island, Tongyeong-si, Gyeongsangnam-do in 2004

Wimi-ri, Namwon-eup, Seoguypo-si

A total of 76 mosquitoes belong to 3 genera and 4 species were collected (Table 6). Cu. pipiens (53.9%) comprised the largest proportion of all mosquitoes, followed by Oc. togoi (40.1%), Cx. tritaeniohynchus (5.3%), and An. (Hyrcanus) group (0.7%).

Table 6.

Seasonal variation in mosquitoes collected by black light trap in Wimi-ri (latitude 33˚16´N, longitude 126˚39´E), Seoguypo-si, Jeju-do in 2005

Relationships of population density of Oc. togoi larvae with salinity and temperature

The Oc. togoi larval population was investigated at Geomun-ri and Maejuk-ri from rock pools using a meshed sinking quadrat from March through October (Tables 7-9), and Wimi-ri on Namwon-eup in Seoguypo-si from April though July (Table 10). The number of larvae for each quadrat at Geomun-ri was 65.3 in March, peaked in June (93.5), and then gradually declined. While 3rd and 4th instars comprised the greatest proportion during the entire period at Geomun-ri, 1st and 2nd instars comprised the greatest proportion collected at Maejuk-ri (Table 10). The salinity of the rock pools varied from 0.2% to 4.1% at both sites (Tables 7, 8), while most of the larvae (68.6% and 78.1%) were collected in water with <0.5% salinity (Table 10).

Table 7.

Larval density of Ochlerotatus togoi in rock pools using the meshed-sinking quadrat (100 cm²) collection method at Geomun-ri (latitude 34˚17´N, longitude 127˚23´E), Geomun Island, Yeosu-si, Jeollanam-do in 2004

Table 9.

Larval density of Ochlerotatus togoi in rock pools using the meshed-sinking quadrat (100 cm²) collection method at Namwon-eup (latitude 33˚16´N, longitude 126˚39´E), Seoguypo-si, Jeju-do in 2005

Table 10.

Frequency distribution of salinity of Ochlerotatus togoi larvae and pupae at Geomun-ri (latitude 34˚17´N, longitude 127˚23´E), Geomun Island, Yeosu-si, Jeollanam-do, and Maejuk-ri (latitude 34˚38´N, longitude 128˚34´E), Maemul Island, Tongyeong-si, Gyeongsangnam-do in 2004

Table 8.

Larval density of Ochlerotatus togoi in rock pools using the meshed-sinking quadrat (100 cm²) collection method at Maejuk-ri (latitude 34˚38´N, longitude 128˚34´E), Maemul Island, Tongyeong-si, Gyeongsangnam-do in 2004

At Maejuk-ri, the number of mosquitoes in each quadrat was 24.9 in March, peaked in June (72.9), and decreased gradually after August (Table 8).

At Wimi-ri, the number of Oc. togoi (14.7) was the highest in April. Unlike the previous 2 sites, larvae were comprised mostly of 1st and 2nd instars (70.7%). The sampling schedule was disrupted at times due to frequent periods of drought, which resulted in some of the rock pools drying.

DISCUSSION

Oc. togoi and Cx. pipiens were the most frequently collected mosquitoes captured by black-light traps in southern islands of Korea during this survey. An. (Hyrcanus) group was collected at high densities only in the Baekdo-ri village, suggesting that it is a potential important vector of filariasis in this area. The mosquito population on Geomun-ri was the highest during the early rainy season and peaked a month earlier than the population on Maejuk-ri, due presumably to differences in climate (e.g., temperature and rainfall) between the 2 areas. However, both areas had a lower population after July because of frequent typhoons during the summer season (data not shown). The larval densities were the highest in June, when the average rainfall and temperature in these areas were 195-210 mm (data not shown) and 20-27℃ (Tables 7, 8), respectively. The appearance of Oc. togoi larvae coincided with decreases in the salinity of rock pools due to frequent rains (Table 10). Thus, lower salinity during this period may be a reason for increased population densities as observed in previous reports [10,11]. Larval Oc. togoi densities decreased during the drier summer due to strong direct sunlight and high water temperature [12]. In a previous study, increase in salinity played a role in reducing the susceptibility of Oc. togoi larvae [4,13]. The presence of <0.5% salt concentrations during the summer and the rainfall amount influenced the number of larval survival [7,14].

The number of Oc. togoi collected in our study was greater than a previous survey collection by Lee et al. [15] at the same location on Heuksan Island. This difference may have been due to differences in collection methods between the CDC miniature type (American Biophysics Co., East Greenwich, Rhode Island, USA) used in the Lee et al. study [15] and black-light traps used in our study. However, the proportion of Oc. togoi in the collected mosquitoes in this study was also lower than that reported by Kim et al. [1] and Lee [16]. These previous studies reported that collection of Oc. togoi and Cx. pipiens ranged 70-90% and 5-26%, respectively, in Jeju-do.

As both vector species are present in Korea, the most likely explanation for the eradication of filariasis is suggested to be an aggressive treatment program executed during the 1970s and 1990s [2,3,17,18], with the consequent benefit that there were fewer vector mosquitoes that have contracted the disease from human carriers. Furthermore, transmission of mosquito-borne diseases has been greatly reduced by the ommercialization of mosquito repellents and insecticides, as well as the use of bed nets and screened windows, all of which decrease human-vector contact [19]. However, a steadily high prevalence of the vector mosquitoes may constitute a potential risk for reemergence of brugian filariasis in these areas.

ACKNOWLEDGEMENTS

We thank our colleagues at the Province and City Bureau of Health Center and the Research Institute of Health and Environment for their devoted support and efforts. This work was supported by a grant from the National Institute of Health (NIH-091-4800-4845-300), National Research and Development Program, Ministry of Health and Welfare, Republic of Korea.

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