Overall Prevalence and Distribution of Knockdown Resistance (kdr) Mutations in Aedes aegypti from Mandalay Region, Myanmar

Article information

Korean J Parasito. 2020;58(6):709-714

Publication date (electronic) : 2020 December 31

doi : https://doi.org/10.3347/kjp.2020.58.6.709

Haung Naw ¹^,²^,^†, Mya Nilar Chaw Su ³^,^†, Tuấn Cường Võ ¹^,², Hương Giang Lê ¹^,², Jung-Mi Kang ¹^,², Hojong Jun ⁴, Yi Yi Mya ³, Moe Kyaw Myint ³, Jinyoung Lee ⁴, Woon-Mok Sohn ¹

, Tong-Soo Kim ⁴, Byoung-Kuk Na ¹^,²^,

¹Department of Parasitology and Tropical Medicine, and Institute of Health Sciences, Gyeongsang National University College of Medicine, Jinju 52727, Korea

²Department of Convergence Medical Science, Gyeongsang National University, Jinju 52727, Korea

³Department of Medical Research Pyin Oo Lwin Branch, Pyin Oo Lwin, Myanmar

⁴Department of Tropical Medicine, Inha University College of Medicine, Incheon 22212, Korea

^*Corresponding author (bkna@gnu.ac.kr)

^†

These authors contributed equally to this work.

Received 2020 August 12; Revised 2020 November 13; Accepted 2020 November 18.

Abstract

Knockdown resistance (kdr) mutations in the voltage-gated sodium channel (VGSC) of mosquitoes confer resistance to insecticides. Although insecticide resistance has been suspected to be widespread in the natural population of Aedes aegypti in Myanmar, only limited information is currently available. The overall prevalence and distribution of kdr mutations was analyzed in Ae. aegypti from Mandalay areas, Myanmar. Sequence analysis of the VGSC in Ae. aegypti from Myanmar revealed amino acid mutations at 13 and 11 positions in domains II and III of VGSC, respectively. High frequencies of S989P (68.6%), V1016G (73.5%), and F1534C (40.1%) were found in domains II and III. T1520I was also found, but the frequency was low (8.1%). The frequency of S989P/V1016G was high (55.0%), and the frequencies of V1016G/F1534C and S989P/V1016G/F1534C were also high at 30.1% and 23.5%, respectively. Novel mutations in domain II (L963Q, M976I, V977A, M994T, L995F, V996M/A, D998N, V999A, N1013D, and F1020S) and domain III (K1514R, Y1523H, V1529A, F1534L, F1537S, V1546A, F1551S, G1581D, and K1584R) were also identified. These results collectively suggest that high frequencies of kdr mutations were identified in Myanmar Ae. aegypti, indicating a high level of insecticide resistance.

Keywords: Aedes aegypti; knockdown resistance; voltage-gated sodium channel; Myanmar

Rapid urbinization, climate change and increasing global trade enhance the widespread incidence of mosquito-borne diseases worldwide [1,2]. Insecticide usage and environmental sanitation are the most common methods used to control mosquitoes due to their effectiveness, feasibility and economic viability [3]. Mosquitoes have been relatively well controlled by insecticides; however, concerns that indiscreet and long-term usage of insecticides induces the development or emergence of insecticide resistance, which eventually reduces the effectiveness of currently used insecticides and threatens global mosquito control programs, have been increasing [4,5]. Until now, 4 different mechanisms of insecticide resistance have been recognized: (1) increased production of metabolic detoxification enzymes, such as cytochrome P450 monooxygenase, esterases, and glutathione S-transferases, (2) mutations in target genes such as voltage-gated sodium channel (VGSC), gamma-amino butyric acid receptor (GABA), and acetylcholine esterases, (3) decreased insecticide penetration due to cuticle thickening, and (4) altered mosquito behaviors [6,7]. Pyrethroid insecticides are regarded as one of the most promising measures for mosquito control due to their fast-acting and effective insecticidal activities and low toxicity to mammals, including humans [8,9]. They interfere with the normal nerve function of insects by disrupting the VGSC function and by depolarizing neurons that leads to paralysis and death [10,11]. However, repeated and indiscreet application of insecticides induces knockdown resistance (kdr) in the VGSC that confers insecticide resistance. Structural changes of the VGSC by these mutations reduces the binding affinity of pyrethroid insecticides to its target site and results in poor sensitivity to the insecticides [4,5,12,13]. More than 50 kdr mutations associated with resistance to pyrethroids have been identified in various arthropod pests and vectors, including mosquitoes [9,14]. Aedes aegypti is the primary vector of arbovirus, including dengue fever, yellow fever, chikungunya fever, and Zika viruses in many geographical locations [15–18]. Aedes aegypti is a primary vector of dengue fever in Myanmar. Warm and humid climate and unsanitary environmental condition that are favorable for the proliferation of Ae. aegypti mosquitoes contributes to the spread of Ae. aegypti in the country [19,20]. An estimated population of 3.9 billion is at risk of dengue fever worldwide [21] and more than 20,000 annual cases have been reported in the last decade in Myanmar [22–25]. Pyrethroid insecticides represent the primary control measure for Ae. aegypti in Myanmar; however, the massive use of insecticides to control mosquitoes has increased concerns of insecticide resistance. Therefore, an understanding of the status of insecticide resistance is important to develop guidelines and alternative methods for mosquito control in Myanmar. In this study, the overall prevalence and distribution of kdr mutations in the VGSC of the Ae. aegypti in the Mandalay region, Myanmar, were investigated.

Aedes aegypti mosquitoes were collected in 4 townships, Aung Myae Thar San (21°59′32.9″N 96°06′51.9″E), Chanmya Thar Se (21°56′55.5″N 96°06′33.6″E), Amarapura (21°54′56.1″N 96°03′39.3″E), and Pyaw Bwe (20°35′27.2″N 96°02′53.1″E), of Mandalay region, Myanmar from December 2016 to March 2017 (Fig. 1). Mosquito larvae and pupae were collected from different habitants in and around human dwellings. Different types of mosquito breeding sites, such as metal drums, traditional clay pots for water storage, concrete water storage tanks, discarded tires, plastic cups and artificial water containners, were the main source of collections. The collected larvae and pupae were reared to adult in the laboratory insectary at 25±2°C and humidity of 80±10%. Adult mosquitoes were identified using standard mosquito identification keys under microscopy [26].

Fig. 1

Map of mosquito collection sites. Mosquito larvae and pupae were collected from 4 different areas of Mandalay region, Myanmar.

A total of 1,040 Ae. aegypti adult mosquitoes were obtained and placed in 103 pools of up to 10 mosquitoes based on collection sites and regions. The mosquitoes were transferred to 1.5 ml sterile tubes and stored at −80°C until use. Genomic DNA was extracted from the pooled mosquitoes using the Tissue DNA extraction kit (Bioneer, Daejon, Korea) according to the manufacturer’s protocols. Segment 6 region flanking domains II and III of the VGSC in Ae. aegypti were amplified via polymerase chain reaction (PCR) using specific primers described previously [14]. The thermal cycling conditions were; initial denaturation at 95°C for 10 min followed by 35 cycles of denaturation at 95°C for 30 sec, annealing at 56°C for 30 sec and extension at 72°C for 30 sec, and a final extension at 72°C for 5 min. PCR products were analyzed on 2% agarose gel, purified from gel, and ligated into the T&A vector (Real Biotech Corporation, Banqiao City, Taiwan). Each ligation mixture was transformed into Escherichia coli DH5α competent cells (Real Biotech Corporation) and positive clones with appropriate insert were selected via colony PCR. The nucleotide sequences of the cloned inserts were analyzed by automatic DNA sequencing (Genotech, Daejeon, Korea). Plasmids from at least 2 or 3 independent clones from each mosquito sample were sequenced bi-directionally to verify sequence accuracy.

A total of 13 mutations resulting in amino acid changes were dectected at 12 positions in domain II (Fig. 2A). S989P and V1016G were highly prevalent with frequencies of 68.6% and 73.5%, respectively. The other 11 mutations (L963Q, M976I, V977A, M994T, L995F, V996M/A, D998N, V999A, N1013D and F1020S) were also detected, but with low frequencies ranging from 1.0% to 2.0%. These 11 mutations were novel in that they have not been reported previously in Ae. aegypti mosquitoes globally. A total of 11 amino acid mutations were detected at 10 positions in domain III (Fig. 2B). F1534C showed the highest frequency of 40.1%, followed by T1520I (8.1%). Nine novel mutations (K1514R, Y1523H, V1529A, F1534L, F1537S, V1546A, F1551S, G1581D and K1584R) were detected with low frequencies (1.0–2.0%).

Fig. 2

Distribution and frequency of amino acid mutations identified in the VGSC of Ae. aegypti from Myanmar. (A) Domain II region. A total of 13 mutations were identified. The frequencies of S989P and V1016G were 68.6% and 73.5%, respectively. The other mutations were detected with low frequencies ranging from 1.0% to 2.0%. (B) Domain III region. A total of 11 mutations were identified. The frequency of F1534C was 40.1%. T1520I was also found with a frequency of 8.1%. The other mutations were detected with low frequencies ranging from 1.0% to 2.0%.

The mutations identified in domains II and III of the VSGC were distributed unevenly in Myanmar Ae. aegypti mosquitoes, and their frequencies varied with the geographical location. High frequencies of S989P/V1016G double mutation in domain II were detected in mosquitoes collected from all 4 collection sites ranging from 43.6% to 66.7% (Fig. 3A). Frequencies of V1016G were also relatively high in mosquitoes collected from the 4 collection sites ranging from 11.1% to 25.0%. Meanwhile, S989P was detected in only mosquitoes collected in Aung Myae Thar San and Chanmya Thar Se. Other minor mutations found in domain II were mostly combined with either S989P or V1016G, except D998N, V999A, and N1013D. The overall frequencies of mutations found in domain III were lower than those in domain II in mosquitoes from all 4 collection sites (Fig. 3B). F1534C was detected in mosquitoes collected from Aung Myae Thar San, Pyaw Bwe, and Chanmya Thar Se. However, this mutation was not detected in mosquitoes from Amarapura. T1520I was detected in mosquitoes collected only at Aung Myae Thar San. The T1520I/F1534C double mutation was observed in mosquitoes collected at Aung Myae Thar San and Pyaw Bwe with a frequency of 5.6% and 40.0%, respectively.

Fig. 3

Comparason on distribution and frequency of VGSC mutations in Myanmar Ae. aegypti collected from 4 study areas. (A) Domain II. The S989P, V1016G, and S989P/V1016G were identified with high frequencies in Ae. aegypti collected from all study areas. Minor mutations were identified as single or combined forms with S989P and/or V1016G. (B) Domain III. High frequency of F1534C was identified in Aung Myae Thar San, Pyaw Bwe and Chanmya Thar Se, but not in Amarapura. Minor mutations were identified as single or combined forms with F1543C.

It has been reported that the 11 common kdr mutations in the VGSC are associated with insecticide resistance in Ae. aegypti: V410L in domain I, G923V, L982W, S989P, I1011M/V, and V1016G/I in domain II, T1520I and F1534C in domain III, and D1763Y in domain IV [13,27]. High frequencies of S989P (68.6%), V1016G (73.5%), F1534C (40.1%), and T1520I (8.1%) were observed in Ae. aegypti that indicate a relatively high level of insecticide resistance. Meanwhile, other mutations that are known to be associated with insecticide resistance were not detected in domains II and III of Myanmar Ae. aegypti mosquitoes. The S989P/V1016G double mutation, which confers higher pyrethroid resistance [28], was detected in mosquitoes collected in all 4 collecting areas ranging from 43.6% to 66.7%. Similar or higher levels of S989P (78.8%), V1016G (84.4%), and S989P/V1016G (65.7%) were previously reported in Ae. aegypti populations of Yangon, Myanmar [29]. The values in Myanmar Ae. aegypti were significantly higher than those of neighboring countries including India, Thailand, Vietnam, and Malaysia [30–33]. F1534C in domain III is also known to be closely associated with type I pyrethroid resistance [34]. The frequency of this mutation in Ae. aegypti analyzed in this study was also high (40.1%), which was higher than that observed in Ae. aegypti (20.2%) from Yangon, Myanmar [29]. Meanwhile, the rate of F1534C mutation differed from that of Ae. aegypti populations in other neighboring countries, including Thailand (62.0%) [31], India (79.0%) [35], Vietnam (7.4%) [32], and Malaysia (13.3%) [34]. The frequencies of V1016G/F1534C and S989P/V1016G/F1534C were 30.1% and 23.5%, respectively, in Ae. aegypti analyzed, while the frequency of T1520I was 8.1%. This mutation was previously identified in Ae. aegypti from India and China [35,36], and now has been identified in the Myanmar Ae. aegypti. It has been proposed that T1520I does not confer pyrethroid or DDT resistance by itself, nor does it increase F1534C-mediated resistance to DDT [36]. However, considering that T1520I is usually tightly combined with F1534C, further studies are needed to determine the role of this mutation in insecticide resistance. Besides these well-known kdr mutations in domains II and III, diverse mutations, alone or combined with other kdr mutations, were identified in Ae. aegypti from Mandalay region, Myanmar. Most of them were novel, even though their frequencies were generally low. Additional studies are needed to elucidate the role of these mutations in insecticide resistance.

In conclusion, high frequencies of kdr mutations were observed in the VGSC of Ae. aegypti in the Mandalay region, Myanmar, suggesting a high level of insecticide resistance. Therefore, the current insecticide application program in Mandalay region, Myanmar, should be carefully reconsidered to develop alternative methods for Ae. aegypti control. A limitation to this study was using pooled mosquito samples, rather than individual mosquitoes. A further study including larger sample sizes and individual Ae. aegypti mosquitoes is needed to determine the relative insecticide resistance of mosquitoes in the areas more clearly.

ACKNOWLEDGMENT

This work was supported by a grant of the National Research Foundation (NRF) funded by the Korean government (NRF-2019K1A3A9A01000005).

Notes

CONFLICT OF INTEREST

The authors declare that they have no competing interests.

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