植食性昆虫的寄主选择机理及行为调控策略

害虫是影响农作物生产的重要因素,过度使用化学农药已带来严重的“3R”问题。为了长期有效地控制害虫的危害,基于植食性昆虫寄主选择机制的行为调控策略已成为害虫治理研究的重要方向。天然植物资源（如驱避植物、诱集植物与诱集枝把）、物理模拟材料（如诱集色、驱避色与诱集模型）和人工合成物质（如引诱剂、驱避剂、刺激剂与抑制剂）等研发工作皆取得了突破性的进展。除单一措施的使用外,多种诱集措施协同利用的“诱集＋诱集”策略、诱集措施与趋避措施结合使用的“排斥-诱集”策略也已被广泛应用。     

诱集植物在农业中的应用研究进展与展望

全世界每年因病虫害导致严重的农业经济损失, 为了减少病虫害的发生, 实际生产中通常使用大量化学农药, 然而农药的大量施用, 不仅造成环境污染和农产品安全问题, 还会使病虫害产生抗药性, 天敌种群受损, 从而导致病虫害爆发日益严重。种植诱集植物是一种环境友好型病虫害防控方法, 该方法主要是通过诱集植物吸引虫害和降低病害, 从而减少病虫害对主栽作物的危害, 达到保护主栽作物的目的, 最终减少农业上化学农药的使用。根据诱集植物自身特性, 将其分为五种主导作用类型: 传统诱集植物、致死型诱集植物、基因工程型诱集植物、生物辅助控制型诱集植物、化学信息素辅助作用型诱集植物等, 根据种植和利用方式, 将其分为: 围种诱集、间种诱集、连作诱集、与其它方式结合等。尽管关于诱集植物的研究已有近160年历史, 但有关高效诱集植物的筛选、诱集植物与主栽作物的优化配置模式与配套种植技术、诱集植物对靶标病虫害的作用机理、诱集植物在农业生产中的生态风险评估等仍不清楚, 且诱集植物仍具有较大开发潜力和应用价值, 如(1)开发应用诱集植物的环境污染修复功能及相关技术; (2)开发应用诱集植物的景观生态与休闲旅游功能及相关技术; (3)开发利用诱集植物对土壤的养分转化与固持提升功能(如固氮、固碳、固土功能等)、生物质能源功能、节能减排功能及相关技术; (4)开发应用诱集植物及其废弃物的经济产品功能及其可持续生产技术。论文综述了近年来国内外有关诱集植物的相关研究与实践应用, 旨在为诱集植物在农业生产中进行病虫害防治研究和应用提供相关参考。     

昆虫趋色性及诱虫色板的研究和应用进展

昆虫与植物之间色彩通讯是彼此信息交流的渠道之一,基于害虫趋色性研发的诱虫板作为一种绿色防控手段,已广泛用于农林害虫的虫情监测、预测预报、大量诱杀以及天敌诱集和指引,效果良好.本文概述了昆虫趋光趋色机理、诱虫板诱杀害虫机制和诱虫板色彩、形状、大小、高度、密度、方向、诱虫时长、植株形态和害虫生理状态等对于诱捕效果的影响,总结了诱虫板在茶园、菜地和大棚等作物环境中的多种实用技术,解析了诱虫板与昆虫性诱剂、植物源引诱剂等配合使用方法及其功效,评价了诱虫板治虫的优缺点并提出改进措施,讨论了诱虫板诱效的评价方法和成本核算.展望了新一代诱虫板研发方向、诱虫板与信息素等产品在有害生物综合治理(IPM)中的集成应用和诱虫板产业前景.     

害虫天敌的植物支持系统

保护天敌,使天敌长期有效地控制害虫是保护性生物防治的核心内容。其中,植物在维持和促进天敌控制害虫中的重要性和作用越来越受到关注。本文概述了各种支持天敌发挥效能的植物类群,论述了蜜源植物、储蓄植物、栖境植物、诱集植物、指示植物、护卫植物等在支持天敌生存和繁殖方面的生物功能,评述了研究和应用这些植物时需注意的问题,提出了科学利用这些植物以维持和增强农业生态系统中天敌发挥控害作用的植物支持系统,并指出了由于对这些植物类别的界定和定义模糊所带来的不便,给出了相应的建议。     

斜纹夜蛾种群控制的研究概况

斜纹夜蛾Spodoptera litura(Fabricius)是重要的农业害虫之一。为了控制斜纹夜蛾,使农作物免受危害,前人研究了化学防治、杀虫灯和性诱捕器诱杀、植物诱集和驱避、转基因抗虫品种以及生物防治对其种群控制作用。化学防治在压制斜纹夜蛾种群暴发、减轻农作物遭受损失方面作出了巨大贡献,但日益增强的抗药性、农药残留造成的环境污染、对天敌的杀伤和人畜安全的影响等问题不断受到关注,人们开始对该害虫的一些新的治理策略进行了探讨。在这些无公害的控制技术中,植物诱集和生物防治是2种值得提倡的有效措施。不少植物源提取物和昆虫生长调节剂对斜纹夜蛾幼虫具有极好的效果,是值得研发的2种新型生物制剂。香芋和蓖麻等诱集作物对斜纹夜蛾有较好的诱集效果,如果能将作物诱集和释放天敌昆虫或病原微生物制剂结合,使之成为一套有效的生态控制体系,将可现实斜纹夜蛾种群的持续控制。     

不同波长诱虫灯对红树林主要害虫的诱集作用

为了明确红树林几种主要害虫的最佳诱集波长,本文利用18种波长的太阳能自动诱虫灯在深圳福田红树林保护区虫害高发期进行野外诱集实验,分析了不同波长对3种主要红树林害虫的诱集作用。结果显示,灯诱昆虫共81种,优势种为海榄雌瘤斑螟Acrobasis sp.、八点广翅蜡蝉Ricania speculum(Walker)和毛颚小卷蛾Lasiognatha mormopa(Meyrick)。18种波长的诱虫灯中,368 nm(Y)对海榄雌瘤斑螟的诱集作用最强,日均诱集量为4.55头,340 nm波长对毛颚小卷蛾的诱集效果最好,日均诱集量达到5.45头,400 nm波长对八点广翅蜡蝉的诱集效果最佳,日均诱集量为2.64头。18种不同波长的诱虫灯对红树林3种主要害虫均有一定的诱集作用,对两种鳞翅目昆虫诱集作用较强的诱虫灯波长均集中在UV-A波段。     

温室害虫防治研究进展与展望

本文从温室害虫防治实践角度,对近20年来温室害虫研究进行了综述,主要内容包括:温室害虫种类与鉴定、重要害虫基础生物学研究、温室害虫共生微生物研究等温室害虫基础研究成果;从农业、物理、化学、生物等防治途径综述了温室害虫防治技术的主要进展。从加强植物检疫、重视温室内外害虫辗转规律研究、新型生防产品研发与应用、组合技术方案研发与应用、智慧温室害虫防控技术研发与应用及诱集及天敌庇护植物应用等方面进行了展望。     

频振式杀虫灯在茶树害虫测报、防治中的应用

应用佳多频振式杀虫灯进行了茶树害虫的预测预报和防治试验。结果表明,该灯对茶园中的茶细蛾Caloptiliatheivora(walsingham)、茶毛虫EuproctispseudoconspersaStrand、斜纹夜蛾Prodenialitura(Fabricius)等茶树主要害虫有明显的诱集作用;同时,根据害虫成虫诱集时间、数量与面上生育期观察,其动态变化基本一致,可以用于幼虫的发生期、发生量预报,在面上应用频振式杀虫灯对3种的防治试验中取得明显的效果。认为该灯是一种安全、经济、有效、无污染的茶树害虫预测预报和防治工具。     

植物源挥发物对玉米田天敌昆虫的诱集效果比较

【目的】比较7种植物源挥发物反式-β-法尼烯、橙花叔醇、6-甲基-5-庚烯-2-酮、顺-3-己烯乙酸酯、丁香酚、芳樟醇、顺式茉莉酮在玉米田中对天敌昆虫的诱集效果,为利用植物源挥发物对玉米田害虫进行生物防治提供参考。【方法】将7种植物源挥发物制作挥发物引诱球,利用水盆诱捕器、粘虫板和五点取样法调查百株虫量,比较7种植物源挥发物对捕食性和寄生性天敌昆虫的诱集效果。【结果】在7种植物源挥发物的筛选中,橙花叔醇对黄缘蜾蠃Anterhynchium flavomarginatum较其它6种化合物和对照的诱集效果有明显差异,顺式茉莉酮对黑带食蚜蝇Episyrphus balteatus较其它6种化合物和对照的诱集效果有明显差异,反式-β-法尼烯和顺式茉莉酮对龟纹瓢虫Propylaea japonica较其它5种化合物和对照的诱集效果有明显差异;在橙花叔醇和顺式茉莉酮的小区试验中,2种挥发物对龟纹瓢虫和异色瓢虫Harmonia axyridis的诱集效果明显优于对照,橙花叔醇对黑带食蚜蝇和虎斑食虫虻Astochia virgatipes的诱集效果明显优于对照。【结论】在7种植物源挥发物中,对玉米田天敌昆虫的诱集效果,橙花叔醇较好,顺式茉莉酮和反式-β-法尼烯次之。     

桤木叶中三萜成分的研究

桤木(Alnus hirsuta Turcz.)是桦木科赤杨属植物,为落叶乔木。据植保人员观察,种植在猕猴桃果园四周的桤木对危害猕猴桃的害虫有诱集作用,当猕猴桃果园四周种上桤木时,象鼻虫和金龟子等害虫倾向于聚集在这种树上。为阐明其内在原因,我们首次对该植物叶的化学成分进行了初步研究。     

Modelling the interplay between pest movement and the physical design of trap crop systems

Abstract 1 The interplay between pest movement and trap crop physical design is modelled in a situation where the pest moves by a random walk with spatially variable mobility. Questions addressed are: (i) how does the proportion of trap crop area of the total field area influence the equilibrium distribution of pests among the crop and the trap crop and (ii) how do crop patch size and shape influence the speed of pest redistribution from the crop to the trap crop. 2 When pest mobility in the trap crop is clearly lower than that in the crop, the pest population in the crop decreases very sharply for small trap crop proportions. When mobility in the trap crop is slightly closer to that in the crop, the pest population in the crop decreases much more gradually with increasing trap crop proportion. Thus finding a trap crop that the pest distinctly prefers over the crop appears to be crucial for developing efficient trap crop systems. 3 The rate of decay in the pest population in the crop increases with increasing perimeter to area ratio of the crop patch. Hence, designing field layouts to increase the perimeter to area ratio of crop patches may be beneficial.     

Managing the pepper maggot (Diptera: Tephritidae) using perimeter trap cropping

A perimeter trap crop barrier of hot cherry peppers, border-row insecticide applications, and a combination of the two management strategies were evaluated to see if they could protect a centrally located main crop of bell peppers from oviposition and infestation by the pepper maggot, Zonosemata electa (Say). In large plots, the main cash crop of bell peppers was protected from the majority of the oviposition and infestation by all three barriers. The combination sprayed/trap crop barrier provided the best protection against both oviposition and infestation and resulted in over 98% pest-free fruit at harvest. Maggots infested only 1.7% of the main crop fruit when protected by a sprayed or unsprayed trap crop barrier, compared with 15.4% in control plots. The perimeter sprayed/trap crop strategy was employed in three commercial fields in 2000 and 2001. The combination barrier resulted in superior insect control and reduced insecticide use at all commercial locations, compared with the same farms' past history or to farms using conventional and integrated pest management (IPM) methods. Economic analysis showed that the technique is more cost effective and profitable than relying on whole-field insecticide applications to control the pepper maggot. Farmer users were surveyed and found the perimeter trap crop technique simple to use, with many hard-to-measure benefits associated with worker protection issues, marketing, personnel/management relations, pest control and the environment. Use of the perimeter trap crop technique as part of an IPM or organic program can help improve crop quality and overall farm profitability, while reducing pesticide use and the possibility of secondary pest outbreaks.     

Comparison of management strategies for squash bugs (Hemiptera: Coreidae) in watermelon

Two watermelon pest management practices, a squash trap crop and a standard recommendation using soil-applied carbofuran, were compared using large-scale field plots to assess trap crop suitability as a replacement for the standard in 2000, 2001, and 2002. In both systems, foliar insecticide applications were used to control squash bugs when populations exceeded threshold levels. During 2001 and 2002, a treatment of untreated watermelon was used. Early season adult insects, from seedling to fruit set, are most critical for watermelon. Significantly fewer early adult bugs were found on watermelon in the trap crop than in the standard recommended practice in 1 of 3 yr. In both years, significantly fewer adult squash bugs were found in watermelon in the trap crop than in untreated fields. The standard recommended practice significantly reduced adult squash bugs in watermelon compared with the untreated in 1 of 2 yr. There was no significant correlation of watermelon yield and squash bug density, indicating that squash bug densities were too low to impact yield. Although squash bugs were reduced significantly by the trap crop, marketable watermelon yields were lower in the squash trap crop than in untreated watermelon, suggesting that pest management treatments may interfere with crop productivity factors other than squash bug colonization. Results suggest that mid-season production squash bug should be managed by monitoring populations and using insecticides as needed rather than using at-plant treatment. Further research is needed to compare treatments during early-season production.     

Bt-maize as a potential trap crop for management of Eldana saccharina Walker (Lep., Pyralidae) in sugarcane

Abstract:  Notwithstanding the introduction of several pest management tactics, the stalk borer Eldana saccharina Walker (Lep., Pyralidae) remains the most serious pest in South African sugarcane. A novel tactic for managing this pest in sugarcane would be the use of a dead-end trap crop that attracts moths for oviposition and curtails subsequent larval development, thereby reducing pest population size. Glasshouse bioassays, in which moths chose to oviposit on maize producing Bacillus thuringiensis Cry1Ab toxin ( Bt -maize), non- Bt -maize or sugarcane of two cultivars (borer-resistant and -susceptible), showed that E. saccharina laid significantly more eggs and egg batches per dry leaf and unit mass of dry leaf on maize ( Bt or non- Bt ) than on either of the cane cultivars. When moths had a choice of ovipositing on 2-, 3-, 4- or 5-month-old maize ( Bt and non- Bt ), dry leaf number and mass of dry leaf material was significantly correlated with number of eggs and egg batches, indicating that older plants, which carried larger amounts of dry leaf matter, were more attractive for oviposition. Finally, glasshouse assays in which hatching larvae fed on 2.5-, 3.5- and 4.5-month-old Bt and non- Bt -maize plants, showed that the Cry1Ab toxin was effective in killing E. saccharina larvae in all Bt -maize plant growth stages, confirming that Bt -maize fulfilled the third requirement (curtailing larval development) of a dead-end trap crop for this pest. We argue that Bt -maize warrants further testing in the field as a trap crop, both alone and as a component of a 'push–pull' or habitat management system for E. saccharina in sugarcane.     

Laboratory evaluations of a wild crucifer Barbarea vulgaris as a management tool for the diamondback moth Plutella xylostella (Lepidoptera: Plutellidae)

The term 'dead-end trap cropping' has recently been proposed to identify a plant that is highly attractive for oviposition by an insect pest, but on which offspring of the pest cannot survive. The potential of the wild crucifer Barbarea vulgaris R. Br. to allure and serve as a dead-end trap crop for the diamondback moth Plutella xylostella (L.), an important pest of cruciferous crops worldwide, was examined in laboratory experiments. When P. xylostella adults were provided with a dual-choice of plants of B. vulgaris, and Chinese cabbage Brassica campestris (L.), in one arena, adult moths laid 2.5-6.8 times more eggs on the former than on the latter. When P. xylostella adults were provided with a dual-choice of plants of B. vulgaris and common cabbage Brassica oleracea L., adult moths laid virtually all their eggs on the former and ignored the latter. Nearly all P. xylostella eggs laid on the three species of plants hatched successfully, but nearly all individuals on plants of B. vulgaris died as neonates or early instar larvae, while 87-100% of the larvae on Chinese cabbage and common cabbage survived to pupation. Dual choice tests with a Y-tube olfactometer showed that volatiles from B. vulgaris were much more attractive to P. xylostella adults than those from common cabbage. The results demonstrate that B. vulgaris has a great potential as a dead-end trap crop for improving management of P. xylostella. Factors that may influence the feasibility of using B. vulgaris as a trap crop in the field are discussed, and ways to utilize this plant are proposed.     

21世纪害虫管理的一些特征展望

分析了近年来国内外IPM研究的进展 ,认为未来的害虫管理是以作物的控害作用为中心 ,以农田生态系统或区域性生态系统为对象 ,以大量信息管理为基础 ,以发展新技术 (转基因作物和昆虫性信息素 )和农民参与为重点 ,以生态调控为手段 ,以持续发展为方向。从而使害虫管理提高到一个新的境界     

Exploiting volatile organic compounds in crop protection: A systematic review of 1-octen-3-ol and 3-octanone

The 21st century has brought new challenges to the agri-food industry due to population growth, global warming, and greater public awareness of environmental issues. Ensuring global food security for future generations is crucial. However, pests, weeds, and diseases still significantly contribute to crop losses, and the availability of effective conventional synthetic pesticides is decreasing. To address this, new and diverse pest management tools are needed. One pest management tool showing potential for invertebrate pest management is the exploitation of volatile organic compounds (VOCs)—in particular, the compounds 1-octen-3-ol and 3-octanone. This review aims to explore the extent to which 1-octen-3-ol and 3-octanone show potential in the future management of invertebrate crop and animal pests. A significant increase in the rate of publication of literature on the use of 1-octen-3-ol and 3-octanone in crop protection since 2018 is identified by this review, therefore, showing the potential importance of these compounds for use in future pest management. This review also identifies key interactions between naturally occurring biosynthesised 1-octen-3-ol and 3-octanone, and a range of invertebrate targets. Many of these interactions with key crop pests are sourced from the taxonomic families Lamiaceae, Fabaceae, and Trichomaceae. However, analysis of the practical application of these sources in an integrated pest management programme identifies clear limitations with the use of naturally occurring biosynthesised 1-octen-3-ol and 3-octanone. Rather, future focus should be placed on the development and exploitation of synthesised nature identical 1-octen-3-ol and 3-octanone for use as a biopesticide product. Overall, 1-octen-3-ol and 3-octanone show potential for exploitation in future crop protection, being abundant in source and diversity of invertebrate interactions. However, their use as a naturally occurring biosynthesised chemical is likely not practical for direct implementation in crop protection. Rather, focus should be placed on the development and exploitation of synthesised nature identical variants of these compounds for use as a biopesticide.     

A degree-day simulation model for the population dynamics of the rice bug, Leptocorisa acuta (Thunb.)

The rice bug, Leptocorisa acuta (Thunb.) is a major pest of the rice crop in India. A computer simulation model of the bug's population dynamics was formulated using the information generated on the thermal requirements of development stages. It is a mechanistic model which follows the state variable–rate variable approach. The model works based on the accumulation of heat units over stage-specific thresholds of development. Validation using light trap catches has shown that the model has satisfactory predictive value. Simulated population dynamics over the years were compared and the influence of global warming on bug population dynamics was predicted. The model can forecast the pest population in the field and help in timely adoption of management practices.     

Sticky trap monitoring of a pest–predator system in glasshouse tomato crops: are available trap colours sufficient?

Monitoring of pest presence and population development in the crop during the season is essential for integrated pest management. Although many tools, for instance coloured sticky traps, have been developed, the full advantage of available information is rarely taken into account in decision‐making. The reasons behind include high workload in practice but also the poorly studied relationships between trap catches and populations in the crop. Here, we investigate whether commercially available coloured sticky traps can be used as tool to monitor population densities of a pest–predator system in glasshouse tomato. The response of Macrolophus pygmaeus (Rambur) (Hemiptera, Miridae) to blue and yellow sticky traps was tested in laboratory and glasshouse experiments. The results indicate that M. pygmaeus can be monitored equally well with both trap colours. The number of trapped insects showed good correlation with the population densities on the crop. Under growing conditions, more M. pygmaeus were trapped on blue compared with yellow sticky traps. However, due to the known preference of Trialeurodes vaporariorum (Westwood) (Hemiptera, Aleyrodidae), yellow traps should be used for a combined pest–predator monitoring.     

Effect of a turnip rape <Emphasis Type="Italic">(Brassica rapa)</Emphasis> trap crop on stem-mining pests and their parasitoids in winter oilseed rape <Emphasis Type="Italic">(Brassica napus)</Emphasis>

Concerns about the negative effects of chemical control of oilseed rape (Brassica napus L.) pests on non-target species, human safety, and development of insecticide resistance, require alternative control strategies such as the use of trap crops and biocontrol to be developed. Psylliodes chrysocephala(L.) (Coleoptera: Chrysomelidae) (cabbage stem flea beetle) and Ceutorhynchus pallidactylus (Marsh.) (Coleoptera: Curculionidae) (cabbage stem weevil) are two major stem-mining pests of oilseed rape. This study investigated the phenology of these pests and their main parasitoids in the UK, the potential use of turnip rape (Brassica rapa L.) as a trap crop to reduce oilseed rape infestation, and the effects of insecticide treatment on pest incidence and larval parasitism. Water trap samples, plant dissections and pest larval dissections were done to determine: the incidence of adult pests and their parasitoids, the level of plant infestation by the pests and percentage larval parasitism, respectively. The turnip rape trap crop borders reduced P. chrysocephalabut not C. pallidactylus infestation of oilseed rape plots. Treatment of the trap crop with insecticide had little effect on either pest or parasitoid incidence in the oilseed rape. TersilochusmicrogasterSzép. andT. obscurator Aub. (Hymenoptera: Ichneumonidae) were the main larval parasitoids of P. chrysocephalaand C. pallidactylus, respectively. Tersilochus microgasteris reported for the first time in the UK. The implications for integrated pest management are discussed.