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。     

利用虫生真菌生物防治柑橘木虱的研究进展

柑橘木虱是柑橘黄龙病的重要传播虫媒。目前对柑橘黄龙病的防治尚缺有效的药剂和抗病品种,加强对柑橘木虱的防治,对控制柑橘黄龙病的蔓延具有重要意义。目前防治柑橘木虱多采用化学防治,杀虫剂的频繁使用造成了农药残留、环境污染、生物多样性被破坏和害虫产生抗药性等诸多问题,生物防治以其高效、低毒、低残留、不易产生抗药性等优点逐渐受到重视。昆虫病原真菌能侵入昆虫寄主体内,导致昆虫发病死亡,具有良好的病害流行潜力及生产应用便利性,利用昆虫病原真菌防治柑橘木虱具有广阔的发展空间。本文总结了用于柑橘木虱生物防治的虫生真菌种类,重点介绍了国内外利用球孢白僵菌、玫烟色棒束孢、淡紫紫孢菌、宛氏拟青霉、蜡蚧菌等虫生真菌在防治柑橘木虱中的应用,并对虫生真菌防治柑橘木虱的发展前景进行了展望,以期为柑橘黄龙病的防控提供借鉴。     

新疆荒漠绿洲生态区苹果蠹蛾生物学、生态学和防治技术研究与应用进展

苹果蠹蛾是我国重要的检疫害虫,自1953首次在新疆库尔勒地区发现以来,疫情保持不断扩张的趋势,目前已经在我国新疆、甘肃、宁夏、内蒙古、黑龙江、辽宁和吉林7个省区发现,对我国苹果产业构成了严重威胁。新疆在苹果蠹蛾生物学、生态学等研究领域起步较早,开展了大量的相关研究和应用工作。本文通过对新疆苹果蠹蛾相关文献的搜集、整理和分析,回顾和总结了新疆绿洲荒漠生态区苹果蠹蛾生物学、生态学和综合防治技术等领域的研究和应用进展,以期对今后该虫的研究和防治提供参考。     

现代生物农药技术进展

1 什么是现代生物农药 现代生物农药是指可以用来防治病、虫、草等有害生物的生物活体及其代谢产物和转基因产物,并且可以制成商品上市流通的生物源制剂,包括病毒、细菌、真菌、植物源农药、生物化学农药和抗病虫草害的转基因植物等.它已经大大扩展了种类和范围,不同于传统意义上的生物农药.     

小菜粉蝶的人工饲料及饲养方法

<正> 小菜粉蝶Pieris rapae L.是我国重要的蔬菜害虫。多年来,在其农药筛选、抗药性和生物防治的研究中,用虫均来自田间。这些虫源往往受季节、施药及病源和寄生等因子的影响,     

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。     

林木白蚁的生物防治和生物源农药防治研究进展

林木白蚁在我国南方林区危害严重.目前,林木白蚁的防治仍以化学防治为主.但化学农药残毒严重,对环境和人类健康已构成极大威胁.利用生物防治以及生物源农药对林木白蚁进行防治具有高效、低毒,与环境兼容的特性,极具发展潜力.本文综述了生物防治以及生物源农药防治林木白蚁的研究现状与进展,并对其目前存在的问题和未来应用前景进行了分析...     

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。     

入侵生物苹果蠹蛾监测与防控技术研究——公益性行业(农业)科研专项(200903042)进展

苹果蠹蛾Cydia pomonella(L.)是世界著名的严重危害苹果的重要入侵害虫,常造成20%～30%的产量损失,现已传入新疆、甘肃、内蒙古、宁夏、黑龙江和吉林等省区,对我国全国苹果安全生产构成严重威胁。2009年农业部科教司批准设立公益性行业(农业)专项"入侵生物苹果蠹蛾监测与防控技术研究",由中国科学院动物研究所主持,全国农业技术推广服务中心、西北农林科技大学、中国农科院植保所和郑州果树所、中国农业大学、河北农业大学以及相关省区植保部门等16单位参加。本文对该项目执行3年中在苹果蠹蛾关键生物学特性、实用监测和防治技术方面取得的主要进展进行了总结,详细情况可通过苹果蠹蛾信息网(www.codlingmoth.net)获得。     

荔枝蝽生物学及防治技术的研究进展(英文)

荔枝蝽Tessaratoma papillosa是荔枝和龙眼生产中的重要害虫,在中国南方及东南亚地区危害严重。该虫以若虫及成虫吸食寄主植物的嫩芽、嫩梢、花穗和幼果,成虫和3龄以上若虫是传播龙眼鬼帚病病原体的传病介体昆虫。本文综述了近60年来国内荔枝蝽的研究情况,旨在为广大科研工作者提供更详尽的荔枝蝽研究现状,以期为该虫的深入研究及绿色防控技术的研发提供参考。荔枝蝽为不完全变态昆虫,一年发生1代,若虫期80 d左右,成虫寿命为203~371 d,单雌产卵总量190粒左右,在习性上表现出明显的聚集性、趋光性、趋色性和趋嫩梢性。近年来,通过荔枝蝽触角感受器分类及分布观察,触角转录组数据测定和分析,臭腺解剖观察以及臭腺分泌物组分分析,对该虫触角和臭腺两大器官组织已有较深入研究及了解。目前,荔枝蝽的发生期主要通过卵巢发育分级法进行预测预报,对该虫的防治仍然是以化学防治为主,农业防治、物理防治和生物防治为辅的策略。其中,荔枝蝽生物防控技术研究报道最多,主要集中在天敌的保护利用和生物源农药的应用。由于荔枝蝽虫源的季节性制约和发生为害地域限制,对该虫的研究进展缓慢,深层次的研究较少,且所涉及到的研究领域也比较窄。从组学、分子生物学、细胞生物学等多角度探明荔枝蝽对寄主植物的选择机制,与寄主植物、天敌及共生菌间的互作关系,以及抗药性机理等,将为荔枝蝽绿色防治技术带来新思路。     

Effect of rearing strategy and gamma radiation on fecundity and fertility of codling moth Cydia pomonella (Linnaeus) (Lepidoptera: Tortricidae)

The codling moth Cydia pomonella (Linnaeus) (Lepidoptera: Tortricidae) is a serious pest of pome fruit worldwide. In an effort to reduce the use of pesticides to control this pest, the sterile insect technique (SIT) is used or considered for use as a component of area‐wide integrated pest management programmes. Rearing codling moths through diapause has been shown to improve the competitiveness of sterile moths released in orchards, and provides management alternatives that would allow mass‐rearing facilities to increase their yearly production of sterile moths. Because radiosensitivity in insects can be influenced by numerous biological factors, laboratory tests were conducted to examine whether the response to increasing doses of radiation, as expressed in the fecundity and fertility of cohorts of moths, is similar for adult moths mass‐reared through diapause or through standard (non‐diapause) production protocols. Our data revealed that the effect of increasing doses of radiation on fecundity and fertility of codling moths reared through both rearing strategies was similar. In the case of fertility, this is a particularly important finding for the expanded application of codling moth SIT. If mass‐rearing facilities use year‐round diapause rearing, the dose required to treat the insects prior to release will be similar to that used when codling moths are reared through standard production protocols.     

Potential for controlling codling moth Cydia pomonella (Linnaeus) (Lepidoptera: Tortricidae) in Argentina using the sterile insect technique and egg parasitoids

Codling moth is the main pest affecting apples and pears worldwide. Most pest control strategies used against this insect have relied on the use of broad‐spectrum insecticides which have led to non‐desirable effects like pesticide resistance, residues in the environment, human health concerns and the reduction of access to international markets. Therefore, alternative pest control strategies that would result in sustainable fruit production systems while taking care of the environment are strongly promoted. The use of the sterile insect technique has proven to be a valuable pest control tactic within area‐wide integrated pest management strategies, and its synergistic effect for Lepidoptera pests when combined with other biological control tactics such as parasitoids has been documented. The purposes of this research were to evaluate the response of an Argentinean codling moth strain to a sub‐sterilizing radiation dose of 100 Gy and to assess the acceptability and suitability of sterile codling moth eggs by the egg parasitoids, Trichogramma cacoeciae (Marchal) and Trichogramma nerudai (Pintureau and Gerding). Irradiated female moths survived better than irradiated male moths and non‐irradiated male and female moths. Also, the fecundity of irradiated female moths was reduced by more than 30% as compared to non‐irradiated ones whereas their fertility was close to zero. The F₁ generation was male biased with a lower fertility (inherited sterility) than the parental generation. Trichogramma cacoeciae and T. nerudai parasitized both fertile and sterile eggs. However, there was a significant reduction in acceptability for sterile eggs. Trichogramma nerudai parasitized more eggs than T. cacoeciae, but egg acceptability for this species was proportionally lower than for T. cacoeciae especially on eggs oviposited by irradiated females. Development to adult of both parasitoids species was not substantially affected by the origin of the eggs and the wasps had acceptable levels of adult emergence, survival and fecundity. These results provided useful information on the potential for controlling the codling moth using egg parasitoids and the sterile insect technique in Argentina.     

Improvement of the sterile insect technique for codling moth Cydia pomonella (Linnaeus) (Lepidoptera Tortricidae) to facilitate expansion of field application

The codling moth Cydia pomonella (L.) (Lepidoptera Tortricidae) is a key pest of pome fruit (apple, pear and quince) and walnut orchards in most temperate regions of the world. Efforts to control the codling moth in the past mostly relied on the use of broad spectrum insecticide sprays, which has resulted in the development of insecticide resistance, and the disruption of the control of secondary pests. In addition, the frequent reliance and use of these insecticides are a constant threat to the environment and human health. Consequently, there have been increased demands from the growers for the development of codling moth control tactics that are not only effective but also friendly to the environment. In that respect, the sterile insect technique (SIT) and its derivative, inherited sterility (IS), are, together with mating disruption and granulosis virus, among the options that offer great potential as cost‐effective additions to available control tactics for integration in area‐wide integrated pest‐management approaches. In support of the further development of the SIT/IS for codling moth control, the Joint FAO/IAEA Programme of Nuclear Techniques in Food and Agriculture implemented a 5‐year Coordinated Research Project (CRP) entitled ‘Improvement of codling moth SIT to facilitate expansion of field application’. Research focussed on sterile codling moth quality and management (e.g. mobility and life‐history traits in relation to rearing strategy, dispersal, flight ability, radiosensitivity and mating compatibility) and a better understanding of the basic genetics of codling moth to assist the development of genetic sexing strains (e.g. cytogenetics, the development of dominant conditional lethal mutations, molecular characterization of the sex chromosomes, sex identification in embryos and cytogenetic markers). The results of the CRP are presented in this special issue.     

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.     

梨小食心虫生物防治研究进展

梨小食心虫Grapholita molesta(Busck)是世界性分布的果树主要害虫之一,可危害多种果树。多年来,过度依赖化学农药防治梨小食心虫效果并不理想,且杀伤天敌、污染环境、导致农药残留。利用自然天敌防治梨小食心虫高效、无毒、无污染,符合当前社会对环保的要求。本文结合前人工作,从病原微生物、寄生性天敌、捕食性天敌、性信息素、化学信息物质等方面,综述了梨小食心虫生物防治的研究进展,并对其应用前景进行了展望。     

Biocontrol of Pests of Apples and Pears in Northern and Central Europe: 1. Microbial Agents and Nematodes

The viral, bacterial, fungal and nematode pathogens of arthropod pests of apple and pear in northern and central Europe and their use as biocontrol agents are reviewed. Baculoviruses are important viral pathogens of several lepidopterous pests of apple and pear but other viral pathogens have not been investigated in depth and are little known. The granuloviruses of codling moth, Cydia pomonella (CpGV), and to a lesser extent, of the summer fruit tortrix moth, Adoxophyes orana (AoGV), have been researched extensively and are exploited as biological control agents. Commercial development and use has been limited because of their high costs, slow action, short persistence and specificity relative to broad-spectrum pesticides. The widespread development of strains of codling moth multi-resistant to insecticides and the desire to reduce dependence on pesticides have improved the commercial prospects of CpGV and use is likely to increase. The development of a genetically improved egt-strain of CpGV (lacking the ecdysteroid-UDP glucosyl transferase gene) in the UK is a significant breakthrough, though commercialization in the UK may be difficult due to adverse public attitudes to the release of genetically-modified microorganisms. Future research and development approaches include further genetic manipulation of CpGV and AoGV to improve potency, speed of kill and/or persistence, improvement of formulation (to reduce UV light sensitivity) and development of cheaper mass production techniques and possibly in vitro production. A systematic search for baculoviruses and other viruses of apple and pear pests is likely to reveal important new opportunities. The most important bacterial pathogen used as a biological control agent is Bacillus thuringiensis (Bt). However, Bt products currently available have limited effectiveness against many orchard pests due to the pests' cryptic life habits. The HD-1 Bt strain has been investigated and used extensively for control of leaf-rolling tortricid larvae and is widely used, but efficacy is moderate. Advances in biotechnology and genetic engineering provide opportunity for development of Bt strains designed specifically to control orchard pests, but this has not yet been done for commercial reasons. Other research approaches include the evaluation of new Bt products developed for other markets worldwide and the bioassay of strains from Bt collections against specific apple or pear pests. Entomopathogenic fungi provide good opportunity for development as biological control agents of apple and pear pests. The main factor limiting their effectiveness is the requirement for high humidities and moderate temperatures for spore germination and development. For foliar pests, a useful starting point for research might be the control of sucking pests which excrete honeydew (e.g. Cacopsylla sp. or aphids) or those that inhabit protected microenvironments (e.g. Dasineura sp.). Key areas for research are improved formulation, the selection of low temperature-active strains, field evaluation and avoiding possible adverse effects of fungicides. An alternative approach is to examine the exploitation of entomopathogenic fungi in soil, to which many species of entomopathogenic fungi are adapted ecologically. Apple and pear orchards provide long-term stable habitats where populations of entomopathogenic fungi in soil are likely to be large. There are few important soil pests of apple or pear. However, many species spend part of their life in soil, mainly to pupate or overwinter, where they may be targeted by fungal entomopathogenic biocontrol agents. Entomopathogenic nematodes have many attributes which favour them as biological control agents. However, their requirement for surface moisture for survival and movement means there are only limited prospects for using them as biological control agents for foliar pests. As with entomopathogenic fungi, there are better prospects for control of pests that occur in soil. Microbial pathogens and entomopathogenic nematodes are important components of the natural enemy complex of apple and pear orchards and more effort needs to be devoted to fostering them and exploiting them as biocontrol agents in sustainable, biologically-based Integrated Pest Management programmes. They can in many cases be mass produced at low cost by bulk fermentation processes and applied as sprays (as 'biopesticides') and are, at least potentially, ideal biological control agents for many apple or pear pests. Important general characteristics are their comparative environmental and human safety, compatibility with other control strategies in Integrated Pest Management programmes and reproductive capacity. They tend to be effective in a narrower range of environmental conditions than pesticides, but there is considerable potential to improve their effectiveness by improved formulation, strain selection and genetic manipulation. They are often host-specific and thus, offer restricted marketing opportunities, which is a significant barrier to development and commercialisation. Registration procedures and associated fees for microbial agents are a further significant barrier. Such requirements do not apply currently to nematodes.     

Overwintering of codling moth (Lepidoptera: Tortricidae) larvae in apple harvest bins and subsequent moth emergence.

Codling moths, Cydia pomonella (L.), have long been suspected of emerging from stacks of harvest bins in the spring and causing damage to nearby apple and pear orchards. With increased use of mating disruption for codling moth control, outside sources of infestation have become more of a concern for growers using pheromone based mating disruption systems. Studies were designed to provide information on bins as a source of codling moth and the pattern of codling moth emergence from stacks of bins. In these studies, codling moth larvae colonized wood harvest bins at a much higher frequency than harvest bins made of injection molded plastic (189 moths emerged from wood compared with five from plastic). There was no statistical difference in the number of moths infesting bins that had been filled with infested fruit compared with bins left empty at harvest. This suggests that codling moth enter the bins during the time that the bins are in the orchard before harvest. Emergence of laboratory reared adult codling moth from wood bins placed in stacks was found to be prolonged compared with field populations. Temperature differences within the bin stacks accounted for this attenuated emergence pattern. Covering bin stacks with clear plastic accelerated codling moth development in the upper levels of the stack. Codling moth emergence patterns from plastic-covered stacks more closely coincided with male flight in field populations. This information could be important in developing a technique for neutralizing codling moth-infested bins, and in understanding how infested bins may influence pest management in fruit orchards that are located near bin piles. Implications for control of codling moth in conventional orchards and in those using mating disruption as the principal component of an integrated pest management system include increased numbers of treatments directed at areas affected by infested bins.     

甘肃苹果蠹蛾的发生现状与研究进展

苹果蠹蛾是果园最重要的害虫之一,1987年入侵甘肃敦煌,2005年苹果蠹蛾在河西地区严重发生。各地先后开展了一系列的防控与监测工作,并对苹果蠹蛾的发生规律及防治技术进行了大量的研究。本文就甘肃苹果蠹蛾的发生历史、为害与防控现状及其生物学、生态学及防治技术方面的研究进展进行概述,以期为全国苹果蠹蛾的防控提供参考。     

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。