酯酶基因扩增及突变与昆虫抗药性

有机磷和氨基甲酸酯类杀虫剂的大量使用导致昆虫对其产生抗药性。酯酶是昆虫体内重要的解毒代谢酶,酯酶基因表达量上升和点突变使其代谢或结合杀虫剂的能力增强是昆虫对常用农药产生抗药性的2个重要原因。文章概述昆虫酯酶基因扩增及突变所导致的抗药性,进一步分析了酯酶突变对蛋白结构和功能的影响。     

小菜蛾及菜蛾绒茧蜂乙酰胆碱酯酶敏感性的相关变化

用生物测定和生化检测的方法,对福州地区小菜蛾Plutella xylostella和菜蛾绒茧蜂Apanteles plutellae的抗药性及两种昆虫乙酰胆碱酯酶对杀虫剂的敏感性进行了田间监测。结果显示,从1998年9月至1999年4月,小菜蛾乙酰胆碱酯酶对6种有机磷和氨基甲酸酯杀虫剂敏感性逐渐恢复,寄生于同一虫源的菜蛾绒茧蜂乙酰胆碱酯酶敏感性的变化也呈明显的相关性,但菜蛾绒茧蜂乙酰胆碱酯酶的敏感性高于其寄主小菜蛾。脱离选择压力后,两种昆虫对杀虫剂的敏感性迅速恢复,乙酰胆碱酯酶的K_i值显著增高。对乙酰胆碱酯酶的K_m、V_max和K_i值测定结果表明,两种昆虫对有机磷和氨基甲酸酯杀虫剂的抗性与乙酰胆碱酯酶对杀虫剂的不敏感性有关。此外还研究了不同发育期小菜蛾乙酰胆碱酯酶活性及其K_i值的变化。探讨了在杀虫剂选择压力下,两种昆虫乙酰胆碱酯酶敏感性的环境适应性变化机制。     

害早抗药性的生化机理

害虫的抗药性是与杀虫剂穿透昆虫表皮速率降低,解毒作用增强和靶标部位敏感性降低有关。昆虫体内多功能氧化酶、磷酸酯酶、羧酸酯酶、谷胱甘肽－Ｓ－转移酶和脱氯化氢酶活力的增加是害虫抗性的主要生化机理。抗性昆虫体内乙酰胆碱酯酶对杀虫剂敏感性降低,中枢神经组织敏感性降低和“抗击倒基因”的存在是拟除虫菊酯类杀虫剂的主要抗性机制。     

乙酰胆碱酯酶性质改变与昆虫抗药性的关系

乙酰胆碱酯酶是生物神经传导中的一种关键性酶,同时又是有机磷和氨基甲酸酯杀虫剂的靶标,因此一直是人们研究的热点。就近年来昆虫乙酰胆碱酯酶(AChE)在生化和分子生物学方面的研究进展、昆虫AChE基因结构及表达的变化对动力学参数、昆虫抗药性的影响机制以及害虫与天敌AChE的比较研究进行了简要综述。     

害虫抗药性的生化机理

害虫的抗药性是与杀虫剂穿透昆虫表皮速率降低,解毒作用增强和靶标部位敏感性降低有关。昆虫体内多功能氧化酶、磷酸酯酶、羧酸酯酶、谷胱甘肽－Ｓ－转酶和脱氯化氢酶活力的增加是害虫抗性的主要生化机理。抗性昆虫体内乙酰胆碱酯酶对杀虫剂敏感性降低,中枢神经组织敏感性降低和“抗击倒基因”（Ｋｄｒ）的存在是拟除虫菊酯类杀虫剂的主要抗性机制。     

细胞色素P450介导的昆虫抗药性的分子机制

细胞色素P450(简称P450) 对杀虫剂的代谢作用直接影响到昆虫对杀虫剂的耐受性和杀虫剂对昆虫的选择性,由P450介导的杀虫剂代谢解毒作用的增强是昆虫产生抗药性的常见而重要的机制。P450介导的杀虫剂代谢抗性具有普遍性、交互抗性与进化可塑性的特点,涉及P450基因重复与基因扩增、基因转录上调以及结构基因的变异等多样化的分子机制,并且多重机制的共同作用可以导致高水平抗药性。这些研究发现说明,无论是昆虫抗药性机制的研究,还是抗药性监测与治理都要有动态的、因地制宜的理念。     

抑制剂存在下不同种群烟粉虱乙酰胆碱酯酶残余活性频率分布及其与抗药性的关系

为了探讨烟粉虱Bemisia tabaci不同种群个体乙酰胆碱酯酶敏感性差异及其与抗药性的关系, 我们选用室内饲养的烟粉虱SUD S敏感品系和6个田间抗性种群, 采用酶标板酶动力学法测定了各品系 (种群）乙酰胆碱酯酶对抑制剂的敏感性反应以及抑制剂存在时各抗性种群个体乙酰胆碱酯酶残余活性频率分布。结果表明: 在抑制剂浓度为300 μmol/L时, 敏感品系乙酰胆碱酯酶的活性基本上被完全抑制, 可以明显地区分敏感品系与田间抗性种群。在抑制剂浓度为2 000 μmol/L时, 各抗性种群个体乙酰胆碱酯酶残余活性频率分布差异明显, 其中ZZ-R种群和FZ-R种群的乙酰胆碱酯酶残余活性频率分布相似, 大部分个体的乙酰胆碱酯酶残余活性分布在1.00~1.80 mOD/min之间; SM-R种群和ND-R种群的乙酰胆碱酯酶残余活性频率分布也相似, 大部分个体的乙酰胆碱酯酶残余活性分布在0.40~1.00 mOD/min之间; LY-R和NP-R种群大部分个体的乙酰胆碱酯酶残余活性分别分布在1.00~1.60 mOD/min和0.80~1.20 mOD/min之间。各抗性种群乙酰胆碱酯酶高残余活性 (大于1.00 mOD/min）个体频率与对敌敌畏的抗性水平之间具有明显相关性, 相关系数为0.86 (P<0.05）。考虑到乙酰胆碱酯酶对抑制剂作用不敏感是一些昆虫对有机磷和氨基甲酸酯类杀虫剂抗性的重要机制之一, 建议可以将乙酰胆碱酯酶对敌敌畏的敏感性作为烟粉虱抗药性生化检测的一个参考指标。     

昆虫抗药性靶标不敏感机制的研究进展

靶标不敏感（targetsiteinsensitivity）是昆虫对杀虫剂产生抗药性的一个极为重要的生化机制,已在多种昆虫对多种杀虫剂的抗性中发现[1,2],最著名的便是：变构乙酰胆碱酯酶（alteredacetvlcholinesterase,简称变构AChE）对有机磷和氨基甲酸酯类杀虫剂的抗性、不敏感的Na 通道（insensitivesodiumchannel）对DDT和除虫菊酯的击倒抗性（knockdownresistance,kdr）,以及不敏感的γ-氨基丁酸受体（insensitiveGABAreceptor）对环戊二烯类杀虫剂和γ-六六六的抗性[3]。80年代以来,众多学者利用各种技术尤其是分子生物学技术对上述靶…     

无脊椎动物乙酰胆碱酯酶研究进展

乙酰胆碱酯酶(AChE)是生物体中一种十分重要的神经递质水解酶,也是有机磷和氨基甲酸酯类杀虫剂的作用靶标。AChE在不同生物中的性质显著不同,如编码基因个数、序列保守性、表达分布及生理功能等。作为杀虫剂的主要作用靶标之一,AChE不但可以通过单个点突变引起昆虫抗药性,还能够通过多个点突变联合作用、靶标表达量变化及基因复制等方式引起抗药性并且改变昆虫的适合度代价。本文主要从AChE的基因类型、分子进化、蛋白结构、生理功能、与昆虫的抗药性关系、同一物种中不同AChE的性质等6个方面对昆虫纲、蛛形纲和线虫等无脊椎动物AChE的研究进展作一综述。     

昆虫对有机磷杀虫剂的抗性

有机磷杀虫剂在害虫的防治中多年来一直被作为一种有效的化学农药来使用。随着杀虫剂的大量使用,大部分害虫对这些杀虫剂产生了不同程度的抗性,导致杀虫剂剂量不断加大、防治效果降低,同时也造成了严重的环境污染。近年来,对昆虫有机磷杀虫剂抗性机制的研究发现,害虫对有机磷杀虫剂产生抗性的主要原因是由于其作用靶标物乙酰胆碱酯酶(AchE)对杀虫剂敏感性下降、AchE或普通酯酶活性上升等。本文就近年来国内外关于昆虫对有机磷杀虫剂抗性机制的研究进行综述,以期对害虫的抗性监测及抗性治理提供有用的参考。     

A method to estimate acetylcholinesterase-active sites and turnover in insects

Acetylcholinesterase is the primary target of organophosphorous and carbamate insecticides. Quantitative changes in acetylcholinesterase are suspected to confer resistance to these insecticides, but a method to estimate the amount in insect is not available. A method using irreversible inhibitors has been developed. Among the irreversible inhibitors tested, 7-(methylethoxyphosphinyloxy)-1-methylquinolinium iodide, chlorpyrifos-ethyl-oxon, and coumaphos-oxon were found to be sufficiently potent and specific.     

A butterfly effect: highly insecticidal resistance caused by only a conservative residue mutated of drosophila melanogaster acetylcholinesterase

Acetylcholinesterase (AChE) and its mutation recently emerged as a significant research area, due to its resistance against organophosphate and carbamate insecticides. Residue G265, which is always a conservative residue, mutated to A265 is the most frequent mutant of AChE in Drosophila populations. However, only this mutation caused a ‘butterfly effect’ that gives high insecticidal resistance. Herein, the models of sensitive strain (Dm-S) and the resistance strain (Dm-R) were constructed, to give a total of 2000 ps molecular dynamics simulation and to reveal the insecticidal resistance mechanism, with implied, the active gorge of Dm-R was much less flexible than that of Dm-S. The “back door” channel was widened to accelerate the detoxication against insecticides by the conformation changing of W83 and I161. All the distances (S238-H480, S238-G150, S238-G151, Y71-M153) in Dm-R became smaller than those in Dm-S, which may deeply influence the binding between the insecticides and DmAChE.     

Mutations in acetylcholinesterase genes of Rhopalosiphum padi resistant to organophosphate and carbamate insecticides.

Apple grain aphid, Rhopalosiphum padi (Linnaeus), is an important wheat pest. In China, it has been reported that R. padi has developed high resistance to carbamate and organophosphate insecticides. Previous work cloned from this aphid 2 different genes encoding acetylcholinesterase (AChE), which is the target enzyme for carbamate and organophosphate insecticides, and its insensitive alteration has been proven to be an important mechanism for insecticide resistance in other insects. In this study, both resistant and susceptible strains of R, padi were developed, and their AChEs were compared to determine whether resistance resulted from this mechanism and whether these 2 genes both play a role in resistance. Bioassays showed that the resistant strain used was highly or moderately resistant to pirimicarb, omethoate, and monocrotophos (resistance ratio, 263.8, 53.8, and 17.5, respectively), and showed little resistance to deltamethrin or thiodicarb (resistance ratio, 5.2 and 3.4, respectively). Correspondingly, biochemistry analysis found that AChE from resistant aphids was very insensitive to the first 3 insecticides (I50 increased 43.0-, 15.2-, and 8.8-fold, respectively), but not to thiodicarb (I50 increased 1.1-fold). Enzyme kinetics tests showed that resistant and susceptible strains had different AChEs. Sequence analysis of the 2 AChE genes cloned from resistant and susceptible aphids revealed that 2 mutations in Ace2 and 1 in Ace1 were consistently associated with resistance. Mutation F368(290)L in Ace2 localized at the same position as a previously proven resistance mutation site in other insects. The other 2 mutations, S329(228)P in Ace1 and V435(356)A in Ace2, were also found to affect the enzyme structure. These findings indicate that resistance in this aphid is mainly the result of insensistive AChE alteration, that the 3 mutations found might contribute to resistance, and that the AChEs encoded by both genes could serve as targets of insecticides.     

Biochemical mechanisms of resistance in strains of Oryzaephilus surinamensis (Coleoptera: Silvanidae) resistant to malathion and chlorpyrifos-methyl.

The acetylcholinesterase, carboxylesterase, and cytochrome P450 monooxygenase activities of three strains of Oryzaephilus srinamensis (L.) were examined to better understand biochemical mechanisms of resistance. The three strains were VOS49 and VOSCM, selected for resistance to malathion and chlorpyrifos-methyl, respectively, and VOS48, a standard susceptible strain. Cross-resistance to malathion and chlorpyrifos-methyl was confirmed in VOS49 and VOSCM. Acetylcholinesterase activity was not correlated to resistance among these strains. VOS49 and VOSCM showed elevated levels of carboxylesterase activity based on p-nitrophenylacetate, alpha-naphthyl acetate, or beta-naphthyl acetate substrates. PAGE zymograms showed major differences in caboxylesterase isozyme banding among strains. VOSCM had one strongly staining isozyme band. A band having the same Rf-value was very faint in VOS48. The VOS49 carboxylesterase banding pattern was different from both VOSCM and VOS48. Cytochrome P450 monooxygenase activity was based on cytochrome P450 content, aldrin epoxidase activity, and oxidation of organophosphate insecticides, all elevated in resistant strains. The monooxygenase activity varied with insecticide substrate and resistant strain, suggesting specific cytochromes P450 may exist for different insecticides. The monooxygenase activity of the VOS49 strain was much higher with malathion than chlorpyrifos-methyl as substrates, whereas VOSCM monooxygenase activity was higher with malathion than chlorpyrifos-methyl as substrates. Results are discussed in the context of resistance mechanisms to organophosphate insecticides in O. surinamensis.     

Mechanisms of insecticide resistance in the aphid Nasonovia ribisnigri (Mosley) (Homoptera: Aphididae) from France.

Nasonovia ribisnigri, a main pest of salad crops, has developed resistance to various insecticides in southern France, including the carbamate pirimicarb and the cyclodiene endosulfan, two insecticides widely used to control this aphid. Here we have investigated the mechanisms of resistance to these two insecticides by studying cross-resistance, synergism, activity of detoxifying enzymes, and possible modifications of the target proteins. Resistance to pirimicarb was shown to be mainly due to a decreased sensitivity of the target acetylcholinesterase; this modification conferred also, resistance to propoxur but not to methomyl and the two tested organophosphates (acephate and paraoxon). Endosulfan resistance was associated with a moderate level of resistance to dieldrin, and resistance to both insecticides was due, in part, to increased detoxification by glutathione S-transferases (GST). The endosulfan resistant strain displayed the same amino acid at position 302 of the Rdl gene (GABA receptor) as susceptible aphids (e.g. Ala), indicating that the Ala to Ser (or to Gly) mutation observed among dieldrin resistant strains of other insect species was not present.     

Expression of the housefly acetylcholinesterase in a bioreactor and its potential application in the detection of pesticide residues

Acetylcholinesterase is a key enzyme of the animal nerve system. The enzyme is the primary target of organophosphorous (OP) and carbamate (CB) insecticides. The insect AChE is being extensively used in development of new insecticides or in vitro selection of the new designed insecticides, and in pharmacological and toxicological field. Rapid assays using AChE-based methods have been proposed as an efficient and rapid method for the detection of pesticides, especially in many Asian markets. In this study, the acetylcholinesterase gene was cloned from housefly (Musca domestica) susceptible to organophosphate (OP) and carbamate (CB) insecticides, and expressed in baculovirus-insect cells system using a bioreactor with oxygen supplementation. The recombinant housefly AChE was purified using ammonium sulfate precipitation and procainamide affinity chromatography, and approximately 0.42 mg of the purified AChE with high biological activity (118.9 U/mg) was obtained from 100 ml of culture solution. The purified AChE was highly sensitive to OP and CBs insecticides. In conclusion, an efficient expression and purification system has been developed for large-scale production of recombinant housefly AChE. The recombinant enzyme is potential to be used for the detection of pesticide residues.     

Acetylcholinesterase. Two types of modifications confer resistance to insecticide.

Quantitative and qualitative changes in acetylcholinesterase confer resistance to insecticides. We have constructed several Drosophila melanogaster strains producing various amounts of enzyme by P-mediated transformation. Toxicological analysis of these strains demonstrates that resistance to organophosphorus insecticides is correlated with the amount of acetylcholinesterase in the central nervous system. Resistance may also be qualitatively determined. Comparison of the Drosophila acetylcholinesterase gene between a resistant strain caught in the wild and a wild type susceptible strain only revealed one nucleotide transition resulting in the replacement of a phenylalanine by a tyrosine. Flies mutant for acetylcholinesterase and rescued with a minigene mutagenized for this same transition produced an altered enzyme which renders flies resistant to pesticides.     

Cloning,mutagenesis, and expression of the acetylcholinesterase gene from a strain of Musca domestica; the change from a drug-resistant to a sensitive enzyme

Insect acetylcholinesterase (AChE) is known to be a primary target of organophosphorus and carbamate insecticides. However chronic exposure to these chemicals has led to resistance to applied insecticides, due usually to mutation of the AChE gene. Analysis of the AChE gene (hm) of Musca domestica (the housefly), which is cloned in this report, reveals the relationship between mutation and insecticide resistance. The 2,076 bp hm encodes a mature protein of 612 amino acids (67 kDa), and an 80 residue signal peptide. Unlike the enzyme of 'sensitive' strains, the AChE used in this study was resistant to the organophosphorus insecticide, trichlorphon. DNA sequencing showed that this AChE is identical to that of the sensitive strains with the exception of three amino acids Met-82, Ala-262, and Tyr-327. Site-directed mutagenesis of the Ala-262 and Tyr-327 residues largely restored sensitivity to the insecticide, suggesting that these two residues are the key structural elements controlling sensitivity. In addition to these residues, Glu-234 and Ala-236 in the conserved sequence FGESAG are thought to play a role in modulating sensitivity to organophosphorus insecticides.