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。     

苹果蠹蛾8个烟碱型乙酰胆碱受体基因的克隆与生物信息学分析

烟碱型乙酰胆碱受体(nicotinic acetylcholine receptors,n AChRs)能够快速介导胆碱能突触传递,并在许多认知功能障碍性疾病的过程中发挥作用。昆虫的烟碱型乙酰胆碱受体是新烟碱类等杀虫剂的重要作用靶标,而且靶标抗性是昆虫产生抗药性的一个重要机制。本文利用生物信息学结合现代分子生物学技术,以新疆石河子地区的苹果蠹蛾种群为材料,克隆获得了8个烟碱型乙酰胆碱受体n AChR亚基基因的c DNA全长序列,并对这8个亚基基因的序列进行了生物信息学分析。研究结果有助于进一步深入解析苹果蠹蛾对新烟碱类杀虫剂的靶标抗性机制,进而为开发新型靶标药剂提供科学依据和理论基础。     

谷胱甘肽S-转移酶与昆虫抗药性的关系

谷胱甘肽S -转移酶 (GSTs)是一种对杀虫剂产生代谢抗性的重要酶系 ,参与许多分子的解毒机制 ,并可转运一些重要的亲脂性化合物。GSTs在保护组织以抵御氧化侵害及氧化压力中起重要的作用。GSTs是昆虫及螨类对有机磷类杀虫剂产生抗生的重要因素     

害虫抗药性进化的遗传起源与分子机制

根据生物进化理论深入理解害虫抗药性进化的遗传起源,并根据解释基因新功能进化的基因重复理论,推测认为基因重复为抗性基因变异提供了原材料。最后,根据现有抗性报道的例子将抗性突变的分子机制进行归类,并发现在多样化的抗性突变中存在一定的规律性,如靶标位点的点突变导致抗性的机制是靶标抗性机制的主要形式,基因扩增或基因过表达导致的代谢酶活性增加是代谢抗性的重要机制,这种规律性与变异的适合度密切相关。     

一个致倦库蚊杀虫剂敏感品系的筛选

化学防治是控制蚊虫传播疾病的主要方法, 抗性监测表明我国蚊虫已对有机磷、 有机氯、 氨基甲酸酯和拟除虫菊酯类杀虫剂产生了不同程度的抗性。蚊虫抗药性的分子机制主要包括靶标抗性和三大解毒酶家族带来的代谢抗性。筛选对杀虫剂敏感的品系是抗性监测和抗性机理研究必不可少的材料。本研究通过从一个致倦库蚊Culex pipiens quinquefasciatus野生种群筛选无乙酰胆碱酯酶G119S突变且具有低活性羧酸酯酶、 P450单加氧酶和谷胱甘肽-S-转移酶的单雌系, 建立了一个对杀虫剂敏感的致倦库蚊品系。该品系的羧酸酯酶活性是敏感品系S-lab的2.5倍, P450单加氧酶和谷胱甘肽-S-转移酶的活性与S-lab相当。生物测定表明, 与S-lab相比, 该品系对有机磷杀虫剂有低于2倍的抗性, 对氨基甲酸酯和拟除虫菊酯类杀虫剂没有抗性, 可以作为相对敏感品系用于抗性监测。     

昆虫钠离子通道基因突变及其与杀虫剂抗性关系的研究进展

昆虫电压门控钠离子通道(voltage-gated sodium channel)存在于所有可兴奋细胞的细胞膜上,在动作电位的产生和传导上起重要作用,是有机氯和拟除虫菊酯杀虫剂的靶标位点。在农业和医学害虫控制过程中,由于有机氯和拟除虫菊酯杀虫剂的广泛使用,抗药性问题日益突出。其中,由于钠离子通道基因突变,降低了钠离子通道对有机氯和拟除虫菊酯类杀虫剂的亲和性,从而产生击倒抗性(knock-down resistance, kdr),已成为抗性产生的重要机制之一。本文综述了昆虫钠离子通道的跨膜拓扑结构、功能、进化及其基因的克隆;更重要的是总结了已报道的40多种昆虫40个钠离子通道基因非同义突变,以及钠离子通道基因选择性mRNA剪接和编辑,以及它们与杀虫剂抗性的关系;也评述了钠离子通道基因突变引起蛋白质结构的改变,从而对杀虫剂抗性的影响机制。这些研究对于进一步鉴定与杀虫剂抗性相关的突变及抗性机制,开发有机氯和拟除虫菊酯类杀虫剂抗性分子监测方法具有重要意义。     

杀虫剂抗性: 遗传学、基因组学及应用启示

杀虫剂抗性已成为害虫防治工作需要解决的一个重要问题,也是一种人为的、自然选择的重要的进化现象,开展抗药性的研究不仅为抗性的监测、治理和农药工业的发展提供科学参考,还可以揭示生物进化的一些基本规律。在过去的10年,昆虫对许多化学杀虫剂抗药性的分子基础得到了进一步阐明,已从果蝇Drosophila melanogaster中克隆了杀虫剂的靶标基因,还查明了一些害虫的与抗性相关联的基因突变。最近,随着经注释的昆虫基因组的出现,由复杂多基因酶系如酯酶、细胞色素P450酶及谷胱甘肽S-转移酶介导的抗性的机制有了突破性的进展,有关杀虫剂抗性的进化以及抗性基因的传播模式也逐步得到揭示。基因组技术在揭示昆虫其他可能的抗药性机制以及在发现新的杀虫剂靶标方面将发挥更大的作用。     

昆虫抗药性产生机制

杀虫剂是害虫防治的有效途径之一,但随着杀虫剂长期和广泛的使用,昆虫种群对各种杀虫剂的敏感性降低,产生了抗药性,如何克服昆虫的抗药性是害虫综合治理的重要问题。近年来,借助基因组测序和遗传操作技术的发展,对昆虫抗药性的研究已经深入到细胞水平和分子水平,取得诸多重要的突破,为害虫抗性的控制奠定了理论基础。本文从常见杀虫剂的历史沿革及作用机理切入,从靶标抗性、代谢抗性和穿透抗性3个方面阐述了杀虫剂抗性产生的机制:杀虫剂作用位点的突变降低了靶标与杀虫剂的亲和力,细胞色素P450酶系和谷胱甘肽转移酶系的激活增加了杀虫剂的降解,表皮结构成分的变化和ABC转运蛋白的增加有效阻挡了杀虫剂的渗入。利用基因操作手段或抑制剂,对上述3种抗性机制的关键步骤进行调控可能成为未来杀虫剂抗性控制的新策略。     

昆虫分子生物学的一些进展：杀虫剂抗性的分子基础

昆虫分子生物学的一些进展：杀虫剂抗性的分子基础翟启慧（中国科学院动物研究所北京１０００８０）昆虫对杀虫剂的中毒,在药物动力学上包括三种不同水平上的作用：穿透表皮组织,在体内组织中的分布、贮存和代谢,以及对最终靶部位的作用。因此,已经公认的抗性机理包括...     

细胞色素P450介导抗性的进化可塑性

细胞色素P450是超基因家族,由其介导的杀虫剂代谢解毒的增强是昆虫产生抗药性的普遍而主要的机制。近年的研究表明,细胞色素P450介导的代谢抗性表现出一定程度的进化可塑性:即使是同种昆虫的不同种群在相同种类杀虫剂的胁迫下,进化选择出的抗性相关的细胞色素P450也有所不同,抗性的产生也可以是几种不同细胞色素P450协同作用或控制P450表达的调控因子的不同。     

苹果蠹蛾抗药性研究进展

苹果蠹蛾是世界各国高度关注的严重危害苹果生产的外来有害生物。该虫于20世纪50年代在我国首次报道,目前是我国一类进境检疫性有害生物,正严重威胁我国苹果主产区的水果生产安全。苹果蠹蛾以幼虫钻蛀到果实内部为害,防治难度高,对其主要采用化学农药、交配干扰和苹果蠹蛾颗粒体病毒进行防治。由于农药的长期大量使用,苹果蠹蛾已对有机磷、氨基甲酸酯、拟除虫菊酯、昆虫生长调节剂、阿维菌素和苹果蠹蛾颗粒体病毒等不同类型的杀虫剂产生了抗药性。本文总结了国内外有关苹果蠹蛾抗药性现状和抗药性机理方面的研究,并分析了其对几种农药产生抗性的主要原因,同时结合国外苹果蠹蛾防治和抗药性相关研究,以及其在我国发生与防治的现状,提出该虫抗药性治理策略,即及时对我国疫区苹果蠹蛾的抗药性现状进行监测,在此基础上,注意科学地使用化学农药,并结合农业防治和生物防治等措施对该虫进行综合治理。     

苹果蠹蛾种群遗传多样性研究进展

苹果蠹蛾是重要的世界性果树害虫,寄主广泛,通过形成各种生态型或种群适应新入侵环境,对当地果品生产造成严重损失。本文综述了国内外有关苹果蠹蛾遗传多样性的研究进展。相关研究表明,寄主植物、地理隔离和杀虫剂等因素影响种群间的遗传多样性和遗传分化。其中,地理隔离是种群间形成遗传分化的主要原因之一,寄主分布格局、气候条件、虫体飞行能力和人为活动等因素都会影响种群间遗传分化的程度。苹果蠹蛾是我国重要的入侵害虫,我国东北地区和西北地区的苹果蠹蛾种群具有不同的遗传多样性水平,并且种群间有一定程度的分化,今后需要进一步研究影响我国苹果蠹蛾种群遗传的重要因素,明确该虫种群间分化情况、入侵来源和扩散路径,这对于延缓苹果蠹蛾在我国的扩散,制定合理有效的综合防治策略具有重要意义。     

Genetic architecture in codling moth populations: comparison between microsatellite and insecticide resistance markers

The codling moth, Cydia pomonella, is renowned for developing resistance to insecticides and causing significant economic damage to pome fruits worldwide. In spite of its economic importance, little is known about the patterns of movement of this pest and the effects of insecticide treatment on the population genetic structure. Here, we investigated the genetic structure of the pest in 27 orchards from France, Italy, Armenia and Chile at seven microsatellite loci and two resistance markers [biochemical activity of cytochrome P450 oxidases and proportion of knockdown resistance (kdr) alleles in the sodium channel gene]. According to the microsatellite loci, we detected isolation by distance at the supranational scale but found no evidence of geographical structure among the 24 French orchards, which were mainly structured by the intensity of the insecticide treatments. Similarly, the highest levels of metabolic resistance associated with activity of the cytochrome P450 oxidases were detected in the most treated orchards. The kdr alleles were observed in southern France and Armenia where the pyrethroid insecticides were or have been intensively sprayed. The intensity of the insecticide treatments marginally affected the allelic richness in each orchard, but not the level of inbreeding. These results suggest important and high-distance gene flow among the codling moth populations, which were mainly structured according to the history of insecticide applications. Differences in mutation-migration-drift equilibrium among treated and untreated orchards also suggest that insecticide applications are the main force regulating the local dynamics of codling moth populations.     

苹果蠹蛾的综合防控和遗传控制研究进展

苹果蠹蛾是仁果类水果的重要检疫害虫,在世界各地造成了巨大的经济损失。目前对其化学防治、化学生态调控、病毒等防治方法研究较多,但仍不能满足防控该害虫的需要,对新型防控技术的需求日益增强。不育昆虫释放技术(SIT)是一种可控制甚至根除靶标害虫的环境友好型防控技术,但传统SIT技术存在一定的局限性,如较难区分性别与筛选雌雄虫、辐射不育昆虫的交配竞争力和适合度降低等问题,这些缺陷随着昆虫遗传修饰技术的发展将得以解决,并将在害虫防控进程中起到积极作用。本文综述了苹果蠹蛾主要防控技术研究现状,介绍了通过遗传修饰技术改善SIT的技术策略,并综合分析了我国开展苹果蠹蛾遗传修饰研究情况和将其应用在苹果蠹蛾防控体系中的可行性及优势。     

Molecular phylogeny and population structure of the codling moth (Cydia pomonella) in Central Europe: II. AFLP analysis reflects human-aided local adaptation of a global pest species

Originally resident in southeastern Europe, the codling moth (Cydia pomonella L.) (Tortricidae) has achieved a nearly global distribution, being one of the most successful pest insect species known today. As shown in our accompanying study, mitochondrial genetic markers suggest a Pleistocenic splitting of Cydia pomonella into two refugial clades which came into secondary contact after de-glaciation. The actual distribution pattern shows, however, that Central European codling moths have experienced a geographic splitting into many strains and locally adapted populations, which is not reflected by their mitochondrial haplotype distribution. We therefore have applied, in addition to mitochondrial markers, an approach with a higher resolution potential at the population level, based on the analysis of amplification fragment length polymorphisms (AFLPs). As shown in the present study, AFLP markers elucidate the genetic structure of codling moth strains and populations from different Central European apple orchard sites. While individual genetic diversity within codling moth strains and populations was small, a high degree of genetic differentiation was observed between the analyzed strains and populations, even at a small geographic scale. One of the main factors contributing to local differentiation may be limited gene flow among adjacent codling moth populations. In addition, microclimatic, ecological, and geographic constraints also may favour the splitting of Cydia pomonella into many local populations. Lastly, codling moths in Central European fruit orchards may experience considerable selective pressure due to pest control activities. As a consequence of all these selective forces, today in Central Europe we see a patchy distribution of many locally adapted codling moth populations, each of them having its own genetic fingerprint. Because of the complete absence of any correlation between insecticide resistance and geographic or genetic distances among populations, AFLP markers do not have a prognostic value for predicting an outbreak of pesticide resistance in the field. By combining mitochondrial genetic data and AFLP analysis it was possible, however, to track the recent evolutionary history of Cydia pomonella on three different time scales: from population splitting in Pleistocene, to interbreeding of mitochondrial haplotypes in Holocene, to human-aided complete intermixing and splitting into many locally adapted populations in very recent times. The case of Cydia pomonella is reminiscent of examples of sympatric speciation and another example of a human-induced globally successful pest species.     

我国启动重大入侵害虫苹果蠹蛾基因组测序

苹果蠹蛾Cydia pomonella (L.)属鳞翅目卷蛾科,具有极强的适应性和抗逆能力,是仁果类果树的毁灭性害虫。1953年首次在我国新疆库尔勒发现,并迅速扩散危害,1987年随旅客携带物传入甘肃敦煌,造成了重大经济损失,是我国重点防控的检疫对象。近日,由中国农业科学院植物保护研究所、南京农业大学等科研单位联合启动了苹果蠹蛾的基因组测序工作。研究团队对苹果蠹蛾进行了10余代的纯化,建立了纯化品系。利用流式细胞分析和小片段文库前期测序等方法,对苹果蠹蛾基因组进行了初步的基因组前期分析。结果显示,苹果蠹蛾基因组大小约为650 Mb, 17-mer和SNP分析显示杂合度大约在0.3%-0.6%之间。经协商拟定了详细的全基因组鸟枪法测序方案后,基因组测序已经全面启动。苹果蠹蛾的基因组测序,对阐明其入侵机制、抗逆机理及防控等研究具有重要的推动意义。     

Insecticidal resistance and cross-resistance in populations of Cydia pomonella (Lepidoptera: Tortricidae) in central Europe

Insecticide bioassays were used to investigate resistance of Cydia pomonella (L.) (Lepidoptera: Tortricidae) to insecticides with various types of active ingredients. The efficacy baselines of selected insect growth regulators (fenoxycarb), insect growth inhibitors (diflubenzuron and teflubenzuron), organophoshorous insecticides (phosalone), and neonicotinoids (thiacloprid) against the eggs and first and fifth instars of sensitive laboratory strains of codling moth were determined. According to concentration-mortality baseline, 50% lethality concentration values and 90% lethality concentration values were determined for all the tested insecticides. The lethal concentration ratio quantified the relation between the efficacy of selected insecticides against fifth instars found by topical application and against first instars found by diet-treated bioassay. No difference was detected when the efficacy of technical grade diflubenzuron diluted in tetrahydrofuran and diflubenzuron in the formulated product Dimilin 48 SC diluted in water was compared. However, just before the application of insecticide, the integument of larvae must be treated with acetone. Two bioassays were used to monitor the resistance of codling moths collected in 2003-2005 in two apple (Malus spp.) orchards with different intensities of chemical control. Resistance ratios (RRs) to the tested insecticides were determined for both field populations of codling moth. For the population of codling moth from a commercial apple orchard in Velké Bílovice, cross-resistance to fenoxycarb, teflubenzuron, and phosalone was detected after the topical application of insecticides to fifth instars. The population of codling moth from Prague-Ruzyne was slightly resistant to phosalone and teflubenzuron. No resistance to diflubenzuron was detected in either tested population.     

Evaluation of border sprays for managing the codling moth (Tortricidae: Lepidoptera) and the apple maggot (Tephritidae: Diptera) in Ontario apple orchards

The efficacy of two insecticide control programs for managing the codling moth, Cydia pomonella (L.), and the apple maggot, Rhagoletis pomonella (Walsh), were compared in the Georgian Bay, London, Niagara, and Quinte apple production areas of Ontario during 1995, 1996, and 1997. In the border spray program, an initial cover spray of organophosphorus insecticide was applied to eradicate codling moths that may have colonized a test plot during the previous growing season. Subsequent sprays were applied only to a four-tree-wide zone (approximately 20 wide) around the perimeter of the plot to control immigrating codling moths or apple maggots. In the cover spray program, all sprays of organophosphorus insecticide were applied to the entire plot. Apple maggot injury was significantly greater in border spray program plots than in cover spray program plots only during 1995 in the London production area. There was no significant difference in codling moth injury between border spray and cover spray plots in the four production areas during the three-year study. The elimination of cover sprays from border spray plots during July and August may have left the apple crop more susceptible to damage by second generation larvae of the obliquebanded leafroller, Choristoneura rosaceana (Harris), in the London production area during 1995. There was a trend of increasing codling moth injury from 1995 to 1997 in two border spray plots, and apple maggot injury was detected in these plots during the third year of the study.     

Molecular phylogeny and population structure of the codling moth (Cydia pomonella) in Central Europe: I. Ancient clade splitting revealed by mitochondrial haplotype markers

The codling moth (Cydia pomonella L., Tortricidae, Lepidoptera) is an important pest of pome fruit with global distribution. It has adapted successfully to different habitats by forming various ecotypes and populations, often termed strains, which differ among each other in several morphological, developmental, and physiological features. Many strains of Cydia pomonella have developed resistance against a broad range of chemically different pesticides. Obviously, pesticide-resistant strains must have a genetic basis inherent to the gene pool of codling moth populations, and this deserves our particular attention. The primary intention of the present study was to contribute novel information regarding the evolutionary phylogeny and phylogeography of codling moth populations in Central Europe. In addition, we aimed at testing the hypothesis that differential biological traits and response patterns towards pesticides in codling moth populations may be reflected at a mitochondrial DNA level. In particular, we wanted to test if pesticide resistance in codling moths is associated repeatedly and independently with more than one mitochondrial haplotype. To this end, we analyzed mitochondrial DNA and constructed phylogenetic trees based on three mitochondrial genes: cytochrome oxidase I (COI), the A+T-rich region of the control region (CR), and the nicotinamide adenine dinucleotide dehydrogenase subunit 5 (ND5). The results indicate that Central European populations of Cydia pomonella are clearly divided in two ancient clades. As shown by means of a molecular clock approach, the splitting of the two clades can be dated to a time period between the lower and middle Pleistocene, about 1.29-0.20 million years ago. It is assumed that the cyclic changes of warm and cold periods during Pleistocene may have lead to the geographic separation of codling moth populations due to glaciation, giving rise to the formation of the two separate refugial clades, as already shown for many other European animal species. Due to their inclination towards developing novel detoxification gene variants, codling moth individuals from both clades independently and multifariously may have developed pesticide resistance, and this process may be ongoing. During their more recent evolutionary history, natural events such as the gradual disappearance of climate-specific geographic barriers, as well as human-aided dispersal in recent historic times, may have allowed codling moth haplotypes from the original clades to interbreed and completely merge again, creating a globally successful insect species with a gene pool capable of responding to novel selective challenges by rapid adaptation.     

生物源农药在苹果蠹蛾防治中的应用

苹果蠹蛾是世界性检疫害虫,对我国苹果优势产区构成了巨大威胁。长期依赖化学防治使该虫抗性问题变得十分严峻。为了保障食品安全,以环境友好的生物源农药替代化学农药已成为当前苹果蠹蛾防治的热点。本文对国内外现有的生物源农药,如寄生蜂、不育昆虫、颗粒体病毒、病原线虫、Bt、病原真菌、微孢子虫、性信息素、斑蝥素、多杀菌素等,在苹果蠹蛾防治中的最新应用及其存在的问题进行论述,讨论了生物源农药凭借其种类多、来源广且在用药时期上选择性强等特点,在该虫综合治理中的重要地位及面临的挑战。