苹果绵蚜在不同寄主果园中的种群数量动态比较

【背景】在我国,苹果绵蚜对苹果等寄主的危害日益严重,发生面积不断扩大,而品种抗性是害虫治理的一种重要手段。【方法12007—2009年于山东莱阳地区系统调查了苹果绵蚜在不同寄主果园的发生动态规律,比较了不同寄主对苹果绵蚜的抗性差异。【结果】苹果绵蚜在红富士、乔纳金、新红星苹果园和西府海棠果园中1a有2个发生高峰,5月底到7月下旬是第1个高峰,也是全年发生的最高峰,9月初到10月底是全年发生的第2个高峰,而7月底到8月底是苹果绵蚜发生的低谷期。苹果绵蚜在红富士苹果上的发生数量显著高于在乔纳金、新红星苹果和西府海棠上的发生数量。在3a的调查时间内,苹果绵蚜在红富士、乔纳金、新红星苹果上每次平均发生量分别为153．2、31．6、30．3头·株^-1。越冬前调查表明,苹果绵蚜对红富士的为害率显著高于青香蕉、乔纳金、新红星和小国光,小国光的被害率以及虫落数量最低。【结论与意义】红富士是苹果绵蚜的感虫品种,而小国光、乔纳金和新红星相对抗虫。文中讨论了苹果绵蚜抗性品种的筛选方法,为掌握不同寄主对苹果绵蚜的抗性差异以及制定苹果绵蚜的抗性治理策略提供了依据。     

温度对苹果绵蚜生长发育的影响

苹果绵蚜Eriosoma lanigerum(Hausm.)是云南苹果树的毁灭性害虫。苹果栽培面积不断扩大,由于检疫措施不严和防治工作跟不上,苹果绵蚜仍在蔓延。但云南过去未对苹果绵蚜生物学进行过系统研究。作者根据生产需要,对苹果绵蚜的有关生物学进行了观察研究。     

苹果绵蚜与苹果绵蚜日光蜂种间关系的模拟研究——Ⅱ.自然系统的模拟及灵敏度分析

本文在生物学特性研究的基础上,组建了苹果绵蚜(Eriosoma lanigerum)及其日光蜂(Aphelinus mali)寄主——天敌作用系统的Boxcar train模型,对苹果绵蚜猖獗期的二种群数量进行了模拟,其结果与果园调查基本吻合。用此模型做系统的灵敏度分析,结果表明系统的内部因子(如蚜蜂的基数比例)和外部因子(温湿度)对系统均有影响。温度升高,二种群数量增加,反之则下降。湿度增加,苹果绵蚜日光蜂种群数量上升,反之则下降。湿度变化对苹果绵蚜无不良影响。比较而言,温度对系统的影响比湿度大得多。减少苹果绵蚜基数比增加日光蜂基数对系统的影响大,据此可从理论上估计生物防治的局限性。     

苹果绵蚜在苹果树上空间分布型的研究

采用6种空间分布型聚集度指标,测楚了苹果绵蚜在苹果树新梢、侧枝、树干(环剥处)和根部的空间分布型。结果表明均呈聚集分布,据此提出了适宜的调查取样技术。     

基于EPG的三种刺吸式害虫在苹果苗上的取食行为比较

【目的】苹果绵蚜Eriosoma lanigerum、绣线菊蚜Aphis citricola和梨网蝽Stephanitis nashi是苹果园的一类重要害虫,它们以刺吸式口器对苹果树造成不同程度的危害。本研究旨在明确这3种刺吸式昆虫在苹果树上取食行为差异。【方法】利用刺吸电位(electrical penetration graph, EPG)技术对苹果绵蚜和绣线菊蚜成虫在苹果苗韧皮部和非韧皮部上的EPG指标,以及苹果绵蚜、绣线菊蚜和梨网蝽成虫苹果苗上的取食行为进行了比较分析,分析了这3种害虫的成虫在苹果苗上取食8 h各种波形平均持续时间的占比。【结果】结果表明,苹果绵蚜和绣线菊蚜成蚜在苹果苗上均产生6种取食波形,即非刺探波(np)、路径波(C)、意外穿刺细胞非主动取食细胞波(pd)、木质部取食波(G)、韧皮部唾液分泌波(E1)和韧皮部取食波(E2);而梨网蝽成虫取食过程中只产生非刺探波(np)、表皮刺穿波(A)、叶肉细胞取食波(Gc)和木质部取食波(E)4种波形。从蚜虫在苹果苗非韧皮部上取食的EPG指标看,苹果绵蚜成蚜pd波平均时间显著高于绣线菊蚜的,而刺探次数、np波总时间和pd波次数均显著低于绣线菊蚜的。从蚜虫在苹果苗韧皮部上取食的EPG指标来看,除第1次出现E2波的时间外,各指标没有显著差异。从3种害虫在苹果苗上取食8 h各波形的占比来看,梨网蝽成虫的np波总时间所占比例最高(53%),其次是绣线菊蚜成虫的(24%),苹果绵蚜成虫的最低(为1%)。同时,苹果绵蚜和绣线菊蚜成虫取食波为E2波,所占总时间比例分别为35%和25%,而梨网蝽的取食波为Gc波(占总时间比例为36%)和E波(占总时间比例为11%)。【结论】本研究阐释了苹果园刺吸式口器害虫的生态位分离和取食行为学机制,为果园刺吸式口器害虫的综合治理提供了理论依据。     

印度小裂绵蚜在土壤中的垂直分布及其种群消长

【目的】印度小裂绵蚜Schizoneurella indica Hille Ris Lambers是在云南昭通苹果上发现的一种新害虫,发生普遍且严重。研究印度小裂绵蚜种群在土壤中的垂直分布及其消长动态是为了掌握其发生与危害特点。【方法】2002—2006年,我们采用盆栽和田间调查的方法对印度小裂绵蚜在土壤中的垂直分布和种群消长开展了研究。【结果】印度小裂绵蚜田间种群数量高峰期主要集中发生在9—12月,5—7月份为其田间种群快速增长期,种群增长率可达200%~273%。印度小裂绵蚜无翅蚜种群在0~30 cm的土壤范围内占总虫量的49.0%,30~60 cm的占27.0%,>60 cm的占24.0%。无翅蚜的各虫龄全年均有发生,冬季以第4龄若虫和无翅成虫为主。有翅蚜的发生全年只有1个时期,为11月上旬至12月下旬。【结论】印度小裂绵蚜田间种群数量全年发生1个高峰期,主要集中在0~30 cm的土壤范围内,随着土壤深度的增加,印度小裂绵蚜种群数量亦逐渐下降。田间有翅蚜虫量极少,较难观察到。     

苹果绵蚜防治技术研究简报

苹果绵蚜 ( Eriosoma lanigerum Hausmann)俗称绵虫、棉花虫、血色蚜虫 ,是我国规定的植物检疫性有害生物 ,也是苹果属 ( Malus)果树的重要害虫。该虫在烟台发生较普遍 ,为害较严重 ,并有逐渐向非发生地区扩散蔓延为害趋势。为寻找经济、快速、有效的防治方法 ,笔者多年进行了这方面的研究 ,取得显著的效果 ,现简报如下 :1材料与方法在山东海阳、蓬莱、莱州等选择苹果绵蚜发生较重的老果园 ,树龄 2 0 - 30年之间 ,树势中等。供试药剂为 4 0 %氧化乐果乳油 (山东张店农药厂 )。设 5个处理 ,分别是 :( 1 )涂干 :在距地面 50 cm左右的主干处 …     

鲁西南地区苹果绵蚜(Eriosoma lanigerum)及其天敌种群动态与群落结构特征

通过田间蚜块计数、黄色粘虫板诱集、室内镜检等方法统计苹果绵蚜Eriosoma lanigerum (Hausmann)及其寄生性天敌日光蜂Aphelinus mali Haldeman种群数量,分析比较了它们的消长动态.利用群落结构特征指数研究比较了不同时期苹果绵蚜及其天敌群落多样性.连续2a调查发现,苹果绵蚜种群在鲁西南地区全年发生两个高峰,其中5月中、下旬～7月上旬为第一高峰期,8月下旬～10月中旬为第二高峰期.有翅蚜发生在4月上旬～6月上旬和9月上旬～10月上旬.不同时期,苹果绵蚜在苹果树体不同部位的种群数量存在差异,上半年,苹果绵蚜在根、树干及主枝部位分布密集,发生危害较重;7月中、下旬之后,苹果绵蚜在根及树干部位基本不再发生或发生较轻,而在枝干部位,包括主枝、侧枝和新梢,发生危害较重.7月份之前,日光蜂滞后于苹果绵蚜的发生高峰,其控制作用不很明显,7月份以后日光蜂跟随现象才比较明显,与苹果绵蚜的第二个发生高峰前期基本吻合,可以很好地控制苹果绵蚜的危害.鲁西南地区苹果绵蚜及其天敌群落多样性低,群落稳定性差,发现天敌23种,捕食性天敌亚群落中七星瓢虫Coccinella septempunctata Linnaeus、二星瓢虫Adalia bipunctata (Linnaeus)和叶色草蛉Chrysopa phyllochroma Waesmael等为优势种,特别是4、5月份,七星瓢虫和叶色草蛉可以很好地弥补因日光蜂跟随滞后而对苹果绵蚜控制作用的影响.这为保护利用自然天敌、可持续控制苹果绵蚜危害奠定了理论基础.     

不同地区苹果绵蚜对三种杀虫剂的抗性监测

【目的】了解苹果绵蚜Eriosomalanigerum对不同类别杀虫剂的抗药水平,为田间苹果绵蚜化学防控过程中的药剂选择提供理论基础。【方法】2018年6-7月间,采用玻璃管药膜法测定了3省14个地区苹果绵蚜对阿维菌素、高效氯氰菊酯和吡虫啉的抗药性。【结果】研究表明,西安杨凌地区苹果绵蚜种群对阿维菌素的抗性水平最低,LC50值仅为6.813 mg/L;烟台招远地区苹果绵蚜种群对阿维菌素的抗性水平最高,LC50值为79.496 mg/L。多数地区苹果绵蚜种群对高效氯氰菊酯的抗药水平较低,其中烟台龙口地区抗药水平最低,LC50值为4.341 mg/L,烟台栖霞地区抗药性最高,LC50值为37.689 mg/L。青岛即墨地区苹果绵蚜种群对吡虫啉的抗性水平最低,LC50值仅为5.261 mg/L;烟台招远地区苹果绵蚜种群对吡虫啉已经产生了中等水平的抗性(RR=10.859),LC50值为57.128 mg/L。不同虫态抗药性检测表明,除了烟台蓬莱地区的若蚜对阿维菌素和吡虫啉出现了抗药性提高的现象外,其它大部分苹果绵蚜3龄若蚜对药剂的抗性与成蚜相近。【结论】苹果绵蚜在北方大部分地区对常用杀虫剂的抗药性保持在低水平或敏感状态。在今后防治中应继续坚持交替轮换的用药原则,防止苹果绵蚜抗药性的产生。     

基于微卫星标记的苹果绵蚜种群遗传结构动态

【目的】苹果绵蚜是我国重要的入侵害虫,对苹果生产造成了严重危害。近年来,苹果绵蚜扩散面积增大,危害加重。了解苹果绵蚜入侵过程中的分子生态变化,可为该虫的综合防控提供依据。【方法】利用微卫星标记技术,选择6个微卫星位点对山东省6个地区(烟台、威海、青岛、潍坊、聊城、泰安)2012—2015年苹果绵蚜种群遗传结构变化规律进行分析。【结果】2012—2015年,山东省6个地区的苹果绵蚜遗传多样性随时间推移逐渐降低。其中,2012年的遗传多样性极显著高于2013—2015年;2013—2015年之间虽然差异不显著,但随时间推移,等位基因观测值(Na)和期望杂合度(He)等遗传多样性指数有逐渐降低的趋势。通过无限等位基因模型、双相突变模型和逐步突变模型分析发现,6个地区的苹果绵蚜均经历了瓶颈效应,是遗传多样性降低的主要原因。对6个微卫星位点分析发现,Erio20、Erio75和Erio78扩增到的苹果绵蚜等位基因数量以及这3个位点的多样性指数随时间推移逐渐降低。【结论】Erio20、Erio75和Erio78是引起苹果绵蚜遗传多样性降低的主要多态位点。苹果绵蚜可能进化出了"超级克隆"基因型,因此,其可在我国适应不同生态环境并增大扩散范围。     

苹果绵蚜在中国适生区预测及发生影响因子

苹果绵蚜是苹果上一种重要的检疫性害虫,每年给苹果产区造成严重的经济损失.预测苹果绵蚜适生性区域和影响其定殖扩散的环境因子,能够开展苹果绵蚜分布区域测报、制定有效的检疫措施并为防治决策提供依据.本研究基于最大熵算法的生态位模型MaxEnt和地理信息系统软件ArcGIS对苹果绵蚜进行适生区分析及预测,用受试者工作特征曲线(ROC)对预测模型和预测结果进行评估,并用Jackknife方法分析影响绵蚜发生的重要因子.结果表明,苹果绵蚜在我国适生范围很广,其中,辽宁、山东、河南、河北、安徽、江苏、陕西等省的适生性指数较高,对苹果绵蚜发生具有重要影响的是与温度相关的环境因子.     

Feeding and egg distribution studies of Heringia calcarata (Diptera: Syrphidae), a specialized predator of woolly apple aphid (Homoptera: Eriosomatidae) in Virginia apple orchards

Predation by the aphidophagous syrphid fly Heringia calcarata (Loew) on woolly apple aphid, Eriosoma lanigerum (Hausmann), was studied in the laboratory and in Virginia apple orchards. Feeding studies compared the prey suitability of three temporally sympatric aphid pests of apple: spirea aphid, Aphis spiraecola Patch; rosy apple aphid, Dysaphis plantaginea (Passerini); and woolly apple aphid. Significantly more H. calcarata larvae survived and completed development on a pure diet of woolly apple aphid than on rosy apple aphid, and none survived on spirea aphid. Final larval weights were significantly greater, and the larval developmental period was significantly shorter on woolly apple aphid than on rosy apple aphid, but neither the duration of pupal development nor adult weight differed between diets. H. calcarata larvae consumed an average of 105 woolly apple aphids during their development. Na?ve, neonate larvae given access to all possible pair combinations of woolly apple aphid, rosy apple aphid, and spirea aphid consumed significantly more woolly apple aphids in all pairings that included woolly apple aphid. When given a choice of rosy apple aphid and spirea aphid, significantly more rosy apple aphids were consumed. Weekly counts of syrphid eggs found in woolly apple aphid, rosy apple aphid, and spirea aphid colonies collected from apple trees showed that two generalist hover fly predators, Eupeodes americanus (Wiedemann) and Syrphus rectus Osten Sacken, were present in colonies of all three aphid species and that E. americanus was the most abundant syrphid predator in A. spiraecola and D. plantaginea colonies. H. calcarata eggs were found only in woolly apple aphid colonies and were more abundant there than E. americanus and S. rectus. These data suggest that H. calcarata is a specialized predator of woolly apple aphid in the apple ecosystem in Virginia.     

苹果绵蚜的生物学特性及其综合治理

苹果绵蚜是一种重要的外来人侵性害虫,在世界的各苹果种植区均有分布,对苹果造成严重危害。本文主要介绍了苹果绵蚜的生物学特性、发生危害特点以及各种防治措施,包括植物检疫、农业防治、生物防治、化学防治和抗性育种等,为在我国广大果区对苹果绵蚜进行综合治理提供依据。     

Genetic diversity of woolly apple aphid Eriosoma lanigerum (Hemiptera: Aphididae) populations in the Western Cape, South Africa

The woolly apple aphid Eriosoma lanigerum (Hausmann) is one of the most damaging apple pests in South Africa. Information on its genetic diversity is lacking and this study, in which the genetic structure of parthenogenetic E. lanigerum populations was characterized in the Western Cape Province of South Africa, represents the first local study of its kind. A total of 192 individuals from four different regions were collected and analysed using amplified fragment length polymorphism (AFLP). Using five selective AFLP primer pairs, 250 fragments were scored for analysis. Results indicated that a low level of genetic variation was apparent in E. lanigerum populations in the Western Cape (H = 0.0192). Furthermore, populations collected from geographically distant regions were very closely related, which can partly be explained by the fact that agricultural practices were responsible for dissemination of populations from a common ancestor to geographically distant areas. The low level of variation found indicated that the possibility of controlling E. lanigerum in the Western Cape using host plant resistance is favourable. This is the first report of AFLP being used to characterize the genetic structure of an aphid species. Results indicate that this marker may be useful for analysis of other aphid species.     

苹果绵蚜发生危害特点及防治对策

苹果绵蚜主要在我国辽东半岛、胶东半岛和昆明一带局部发生 ,每年 5～ 6月和 9～ 1 0月为害虫发生盛期。近几年来 ,危害逐年加重 ,并不断扩展蔓延 ,对我国苹果的产量和品质构成了严重威胁。该文介绍了苹果绵蚜在我国的危害情况和发生规律 ,分析了其发生与危害的特点 ,并提出了有效防治对策     

苹果绵蚜种群的空间分布型及其应用——Ⅰ.秋季种群

生物种群的空间分布是一种高度特化的生物学特性,是长期适应自然环境的结果。在理论上,研究种群的空间分布有助于理解种群的生态学特性以及种群与所处环境的相互关系;在实践中,种群的空间分布是确定生物统计分析的资料代换方法和制定抽样技术方案的依据。 苹果绵蚜Eriosoma lanigerum(Hausm.)是苹果树的毁灭性害虫。50年代云南仅昆明地区有苹果绵蚜的分布,现在苹果绵蚜已侵入到云南许多苹果产区。1978年苹果绵蚜侵入到丽江县,其危害相当严重。过去的工作主要集中在生物学和防治方面,空间分     

Conservation biological control of rosy apple aphid, Dysaphis plantaginea (Passerini), in eastern North America

Because of the potentially serious damage rosy apple aphid, Dysaphis plantaginea (Passerini) (Homoptera: Aphididae), can cause to apple fruit and branch development, prophylactic insecticides are often used for control. If biological control could be relied on, the amount of pesticide applied in orchards could be reduced. This study examined biological control of rosy apple aphid in eastern West Virginia and the potential for enhancement through conservation biological control, in particular, the effect of interplanting extrafloral nectar-bearing peach trees. By 20 d after first bloom, only 2% of fundatrices initially present survived to form colonies based on regression of data from 687 colonies. Exclusion studies showed that many of the early colonies were probably destroyed by predation; the major predator responsible seemed to be adult Harmonia axyridis (Pallas) (Coleoptera: Coccinellidae). Mortality before apple bloom was most important in controlling rosy apple aphid population growth but by itself is not sufficiently reliable to prevent economic injury. Interplanting of extrafloral nectar-bearing trees did not increase biological control, and interplanting with 50% trees with extrafloral nectar glands reduced biological control. The number of leaf curl colonies in the 50% interplanted orchards was lower than in monoculture orchards, suggesting a preference of alate oviparae for more diverse habitats, supporting the resource concentration hypothesis but not at a level sufficient to prevent injury. Predation and parasitism after the formation of leaf curl colonies was not adequate to control rosy apple aphid populations.     

Landscape composition modulates population genetic structure of Eriosoma lanigerum (Hausmann) on Malus domestica Borkh in central Chile

Landscape genetics have been particularly relevant when assessing the influence of landscape characteristics on the genetic variability and the identification of barriers to gene flow. Linking current practices of area-wide pest management information on pest population genetics and geographical barriers would increase the efficiency of these programs. The woolly apple aphid, Eriosoma lanigerum (Hausmann), an important pest of apple orchards worldwide, was collected on apple trees (Malus domestica Borkh) from different locations in a 400 km north-south transect trough central Chile. In order to determine if there was population structure, diversity and flow were assessed. A total of 215 individuals from these locations were analysed using Inter Simple Sequence Repeat (ISSR) markers. Four ISSR primers generated a total of 114 polymorphic loci. The percentage of molecular variation among locations was 18%. As the algorithm used by structure may be poorly suited for inferring the number of genetic clusters in a data set that has an IBD relationship, the number of genetic clusters in the samples was also analyzed using a Bayesian clustering method implemented in software Baps version 4.14. We inferred the presence of four genetic clusters in the study region. Clustering of individuals followed a pattern explained by some geographical barriers. Using partial Mantel tests, we detected barriers to gene flow other than distance, created by a combination of main rivers and mountains. Although landscape genetics are rarely used in pest management, our results suggest that these tools may be suitable for the design of area-wide pest management programs.