Insecticide susceptible/resistance status in Aedes (Stegomyia) aegypti and Aedes (Stegomyia) albopictus (Diptera: Culicidae) in Thailand during 2003-2005

Susceptibility baselines and diagnostic doses of the technical grade insecticides deltamethrin, permethrin, fenitrothion, and propoxur were established based on Aedes aegypti (L.), Bora (French Polynesia), a reference susceptible strain. Field-collected Aedes mosquitoes from each part of Thailand were subjected to bioassay for their susceptibility to the diagnostic doses of each insecticide. Almost all Ae. aegypti collected were incipient resistant or resistant to deltamethrin and permethrin, except those from some areas of Songkhla (southern) and Phan district of Chiang Rai (northern) province. Susceptibility to fenitrothion was found in mosquitoes from Bangkok (central), Chonburi (eastern), Chiang Rai, Kanchanaburi (western), and Songkhla, whereas they were resistant in almost all areas of Nakhon Sawan (north central) and Nakhon Ratchasima (northeastern) provinces. Most of Ae. aegypti were susceptible to propoxur except those from Mae Wong, Nakhon Sawan province. Various levels of insecticide resistance and susceptibility in adjacent areas revealed a focal susceptible/resistance profile in the country. It could be noted that almost all of Ae. albopictus were susceptible to the insecticides tested at the same diagnostic doses. In conclusion, resistance to pyrethroids (permethrin and deltamethrin) has developed in Ae. aegypti in most of the collected areas, suggesting that an alternative choice of insecticide or other control measures should be applied.     

Characterization of deltamethrin resistance in field populations of Aedes aegypti in Thailand.

Five field collections of adult Aedes aegypti mosquitoes from different areas in Bangkok and Pathum Thani provinces were subjected to susceptibility tests against deltamethrin. Low levels of resistance were detected among all populations tested (RR50 = 8-17.2) compared to the susceptible strain, Bora (French Polynesia). Among the five populations tested, the BKH (Bang Khen, Bangkok) and PSC (Phasicharoen, Bangkok) populations showed a higher level of deltamethrin resistance than the other three populations (RR50 of BKH = 17.2, and of PSC= 13.6) and cross-resistance to DDT was observed in these strains. Biochemical analysis showed a significant elevation of mixed function oxidases enzyme activity in all populations. There was an elevation of non-specific esterases in all populations except BKL, and there was no consistent association of glutathione S-transferases with deltamethrin and DDT resistance, although not all populations were bioassayed for DDT. The partial cDNA sequence of the para-type voltage-dependent sodium channel (IIS4-IIS6) was determined for BKH and PSC populations. Common amino acid substitution, leucine to phenylalanine in the IIS6 region, found for insects including Anopheles gambiae was not found in either the BKH or the PSC populations. However, two other amino acid substitutions (proline substituted with serine at position 64 in the PSC population and leucine with phenylalanine at position 69 in the BKH population) were found in the IIS5-IIS6 inter-segment region sequenced. The role these substitutions play in target site resistance is uncertain at this time.     

神经递质释放与家蝇对拟除虫菊酯抗性关系研究

通过生物测定比较溴氰菊酯、氯菊酯和DDT对Dec-R,2C1-R,DDT-R和敏感(SP)家蝇Musca domestica vicina的毒力,表明三个抗性品系对溴氰菊酯、氯菊酯和DDT均有很高的抗性,抗性倍数分别达120 912,6 032和112.2倍,并对上述三种杀虫剂有明显的交互抗性和抗击倒效应。杂交试验表明Dec-R对溴氰菊酯的抗性是一个隐性基因,电生理试验表明抗性家蝇中枢神经系统(CNS)对药剂敏感度的降低是其产生抗性和交互抗性的重要机制。研究结果表明Dec-R和2CLR家蝇品系中存在有击倒抗性因子(Kdr)。当用1×10^-7mol/L溴氰菊酯对SP家蝇脑突触体在提高K+浓度去极化后,可加强3H-胆碱的释放,而在Dec-R品系中,溴氰菊酯浓度提高到1×10^-4m0l/L也未能加强³H-胆碱的释放,表明溴氰菊酯与神经递质的释放和钠通道亲和性的降低是抗性的主要机制。     

Molecular evidence for a kdr-like pyrethroid resistance mechanism in the malaria vector mosquito Anopheles stephensi

The mosquito Anopheles stephensi Liston (Diptera: Culicidae) is the urban vector of malaria in several countries of the Middle East and Indian subcontinent. Extensive use of residual insecticide spraying for malaria vector control has selected An. stephensi resistance to DDT, dieldrin, malathion and other organophosphates throughout much of its range and to pyrethroids in the Middle East. Metabolic resistance mechanisms and insensitivity to pyrethroids, so-called knockdown resistance (kdr), have previously been reported in An. stephensi. Here we provide molecular data supporting the hypothesis that a kdr-like pyrethroid-resistance mechanism is present in An. stephensi. We found that larvae of a pyrethroid-selected strain from Dubai (DUB-R) were 182-fold resistant to permethin, compared with a standard susceptible strain of An. stephensi. Activities of some enzymes likely to confer pyrethroid-resistance (i.e. esterases, monooxygenases and glutathione S-transferases) were significantly higher in the permethrin-resistant than in the susceptible strain, but the use of synergists--piperonyl butoxide (PBO) to inhibit monooxygenases and/or tribufos (DEF) to inhibit esterases--did not fully prevent resistance in larvae (permethrin LC50 reduced by only 51-68%), indicating the involvement of another mechanism. From both strains of An. stephensi, we obtained a 237-bp fragment of genomic DNA encoding segment 6 of domain II of the para type voltage-gated sodium channel, i.e. the putative kdr locus. By sequencing this 237 bp fragment, we identified one point mutation difference involving a single A-T base change encoding a leucine to phenylalanine amino acid substitution in the pyrethroid-resistant strain. This mutation appears to be homologous with those detected in An. gambiae and other insects with kdr-like resistance. A diagnostic polymerase chain reaction assay using nested primers was therefore designed to detect this mechanism in An. stephensi.     

Insecticide susceptibility level of Anopheles arabiensis in two agrodevelopment localities in eastern Ethiopia

Anopheles arabiensis strains reared from larvae and pupae collected from two different localities, Metehara and Melka-Worer, eastern Ethiopia, were evaluated against three insecticides. Resistance states of adult females were determined using the WHO test kits under field condition. The insecticides used were WHO discriminating doses of 4% DDT, 0.75% permethrin and 0.1% propoxur. The study revealed that 42.5% of the An. arabiensis population was resistant to DDT in Melka-Worer while only 30% of the species was resistant in Metehara to the same insecticide. In Metehara, 25% of An. arabiensis was also resistant to permethrin while the population was highly susceptible to the insecticide in Melka-Worer. Propoxur, which was not evaluated in Melka-Worer, was highly toxic to An. arabiensis in Metehara. The knocked-down time (KD50) for permethrin was 14.5 and 12.5 minutes in Metehara and Melka-Worer, respectively. The implications of these findings are discussed.     

Characterisation of DDT and pyrethroid resistance in Trinidad and Tobago populations of Aedes aegypti

Insecticide resistance is an important factor in the effectiveness of Aedes aegypti control and the related spread of dengue. The objectives of this study were to investigate the status of the organochlorine dichlorodiphenyltrichloroethane (DDT) and pyrethroid (permethrin and deltamethrin) resistance in Trinidad and Tobago populations of Ae. aegypti and the underlying biochemical mechanisms. Nine populations of Ae. aegypti larvae from Trinidad and Tobago were assayed to DDT and PYs using the Centers for Disease Control and Prevention (CDC) time-mortality-based bioassay method. A diagnostic dosage (DD) was established for each insecticide using the CAREC reference susceptible Ae. aegypti strain and a resistance threshold (RT), time in which 98-100% mortality was observed in the CAREC strain, was calculated for each insecticide. Mosquitoes which survived the DD and RT were considered as resistant, and the resistance status of each population was categorised based on the WHO criteria with mortality <80% indicative of resistance. Biochemical assays were conducted to determine the activities of α and β esterases, mixed function oxidases (MFO) and glutathione-S-transferases (GST) enzymes which are involved in resistance of mosquitoes to DDT and PYs. Enzymatic activity levels in each population were compared with those obtained for the CAREC susceptible strain, and significant differences were determined by Kruskal-Wallis and Tukey's non-parametric tests (P<0.05). The established DDs were 0.01 mg l(-1), 0.2 mg l(-1) and 1.0 mg l(-1) for deltamethrin, permethrin and DDT, respectively; and the RTs for deltamethrin, permethrin and DDT were 30, 75 and 120 min, respectively. All Ae. aegypti populations were resistant to DDT (<80% mortality); two strains were incipiently resistant to deltamethrin and three to permethrin (80-98% mortality). Biochemical assays revealed elevated levels of α-esterase and MFO enzymes in all Ae. aegypti populations. All, except three populations, showed increased levels of β-esterases; and all populations, except Curepe, demonstrated elevated GST levels.Metabolic detoxification of enzymes is correlated with the manifestation of DDT and PY resistance in Trinidad and Tobago populations of Ae. aegypti. The presence of this resistance also suggests that knock down (kdr)-type resistance may be involved, hence the need for further investigations. This information can contribute to the development of an insecticide resistance surveillance programme and improvement of resistance management strategies aimed at combatting the spread of dengue in Trinidad and Tobago.     

Pyrethroid resistance mechanisms in the head louse Pediculus capitis from Israel: implications for control

In Israel, the head louse, Pediculus capitis, developed resistance to DDT through the extensive use of this insecticide until the 1980s. In 1991, permethrin was introduced for control of DDT resistant P. capitis in Israel, leading to control failure of this pyrethroid insecticide by 1994. Pyrethroid resistance of P. capitis in Israel extends to phenothrin, which has not been used for louse control. We identified a glutathione S-transferase(GST)-based mechanism of DDT resistance in the Israeli head lice. This GST mechanism occurred before 1989, while permethrin resistance in P. capitis developed after 1994, suggesting that the main GST resistance mechanism selected by DDT use does not confer any pyrethroid cross-resistance. Esterase activity levels were equivalent in pyrethroid resistant and susceptible P. capitis field-collected in Israel, and in a susceptible strain of P. humanus, the body louse, indicating no involvement of any esterase-based mechanism in resistance. A weak monooxygenase-based permethrin metabolism resistance mechanism was the only factor identified which could account for any of the observed pyrethroid resistance in P. capitis. However, the lack of synergism of phenothrin resistance by piperonyl butoxide suggests that a non-oxidative mechanism is also present in the resistant lice. Therefore it seems probable that pyrethroid resistance in Israeli P. capitis is due to a combination of nerve insensitivity (knockdown resistance or 'kdr') and monooxygenase resistance mechanisms.     

Reduced susceptibility to permethrin and its relationship to DDT resistance in larvae of Anopheles stephensi

Permethrin selection of DDT resistant Anopheles stephensi Liston mosquito larvae produced a reduction in susceptibility to knockdown (2 h exposure) of 17-fold, but only 1.6-fold to kill (24 h exposure). Genetic analysis, incorporating visible mutant markers, was interpreted as indicating that, through multigenic inheritance, several interacting genetic factors were collectively responsible for reduced larval susceptibility to knockdown. These were maintained together only under selection pressure, as the effect was lost quickly in the absence of selection or with outcrossing. The 30-40-fold DDT-resistance found in the parental strain was barely altered by permethrin selection, suggesting no relationship with the major source of DDT resistance. This was confirmed in single family studies. Some evidence for an additional tolerance to DDT was found to be associated with reduced larval susceptibility to permethrin.     

家蝇对DDT和拟除虫菊酯的重要抗性机制——中枢神经系统的不敏感性

本文以电生理技术研究了四个品系的家蝇Musca domestica viMna Macq.中枢神经系统(CNS)对DDT、二氯苯醚菊酯和澳氰菊酯的敏感性,结果表明:三种抗性家蝇,DDT高抗品系(DDT-R)、二氯苯醚菊酯高抗品系(2C1-R)和溴氰菊酯高抗品系(Dec-R)的中枢神经系统(CNS)对三种杀虫剂的敏感性与敏感家蝇相比均明显降低,而且,GNS的不敏感性随杀虫剂LD_(50)的升高有逐渐上升的趋势。我们认为,CNS不敏感性是家蝇对DDT相拟除虫菊酯产生抗性的一个重要机制,也是产生交互抗性的一个重要原因。     

赤拟谷盗的磷化氢敏感和抗性品系体内羧酸酯酶的活性比较

本文比较测定了赤拟谷盗Tribolium castaneum(Herbst)的磷化氢抗性(Rf=327)和敏感品系害虫的羧酸酯酶活性,研究了该害虫同一品系不同个体间羧酸酯酶的活性差异,比较了两品系害虫在系列磷化氢浓度下熏蒸24h和6.94×10-2mg/L磷化氢浓度下熏蒸不同时间的羧酸酯酶活性。主要结果为:未熏蒸的抗性害虫幼虫和蛹体内的羧酸酯酶活性分别高于敏感品系的1.37和1.16倍;敏感和抗性害虫同品系内不同个体间羧酸酯酶活性分布频率都存在明显差异,抗性害虫中酶活性大的个体数量占的比例较大;磷化氢浓度分别为0.69×10-2、2.78×10-2、5.56×10-2、8.33×10-2和11.11×10-2mg/L时都可导致敏感害虫羧酸酯酶的活性降低,但活性受抑制的程度不因浓度高低呈相应的增减。浓度分别为5.56×10-2、11.11×10-2、13.89×10-2、20.83×10-2和27.78×10-2mg/L的熏蒸中抗性害虫体内酶活性增加,且活性增高的程度与浓度增减也不呈对应变化。在6.94×10-2mg/L磷化氢浓度下熏蒸不同时间的结果中,敏感害虫的酶活性随时间延长而下降,抗性害虫的活性则随时间延长而增大。研究表明赤拟谷盗对磷化氢的抗性可能与羧酸酯酶的活性增加有关。