苹果绵蚜蚜小蜂——对苹果绵蚜有控制潜能的寄生蜂

苹果绵蚜蚜小蜂是苹果绵蚜的重要寄生蜂。本文综述了苹果绵蚜蚜小蜂的研究概况,包括该寄生蜂的引种与分布、寄主范围、生物学特性、控制效果与影响因素、重寄生蜂及合理利用等,指出应加快苹果绵蚜蚜小蜂的规模化生产,充分发挥其对苹果绵蚜的控制作用。     

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。     

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.     

苹果绵蚜寄生蜂(Aphelinus mali Haldeman)的生物学特性和其利用研究

1.本研究工作自1953年开始至1956年,1957至1958年作了一些大量繁殖散放工作,均在山东青岛进行。通过室内外的饲养观察,了解苹果绵蚜寄生蜂一年发生代数、生物学特性及其在田间与寄主的消长情况。通过生态条件的分析,找出寄生蜂不能全年抑制绵蚜发生为害的原因所在,然后根据米丘林的生物科学原理,运用远缘的种内杂交方法,提高当地寄生蜂的生活力,向苏联克里米亚地区引进寄生蜂进行杂交试验。证明有效之后乃在田间实际散放。通过1957年的调查,指出确实有效。对今后农业害虫的生物防除利用分布区内的迁移,改善生物群落的方法。提供理论基础。 2,绵蚜寄生蜂在青岛以老熟幼虫在寄主尸体内越冬,翌年3月下旬气温平均达6—7℃时变转为蛹,4月中旬气温平均达9—11℃时成虫羽化。一年发生10—12代。最少9代,最多可达13代。每代发育的时间长短与大气温度有密切的关系。其发育最适宜的温度范围为22—27℃左右,大气相对湿度约在80—90％之间。较绵蚜要求的最适宜温湿度各为16.5—22℃及60—70％略高。这是年中绵蚜发生前期,寄生蜂不能控制它的主要原因之一。此蜂寄生性专一,在青岛田间以寄生苹果绵蚜为主,极少数能在加拿大白杨绵蚜上寄生。在人工强迫接种的情况下,能在榆树叶瘤蚜及野艾的绵蚜体上产卵并发育成长为老熟     

苹果绵蚜与苹果绵蚜蚜小蜂种间关系的模拟研究——Ⅰ.两种群生物学的数量特征比较

本研究通过对苹果绵蚜(Eriosoma lanigerum Haus.)和苹果绵蚜蚜小蜂(Aphelinus mali Hald.)的生物学和生态学特性的比较分析,得到如下结论:(1)苹果绵蚜完成一世代的积温要求和发育起点温度均低于苹果绵蚜蚜小蜂,二者的有效积温分别为352.19日度和375.51日度,发育起点温度分别为7.62度和7.95度。因此,苹果绵蚜较其寄生蜂更适合于昆明地区的气候条件;(2)苹果绵蚜种群的增长能力大于苹果绵蚜蚜小蜂,二者的内禀增长率在20℃下分别为0.1390和0.1146,在25℃下分别为0.2647和0.1628。这可能是昆明地区苹果绵蚜蚜小蜂不能控制苹果绵蚜为害的主要原因。另外,本研究首次利用卡方密度函数对各种温度下的昆虫产卵的时间分布进行了拟合,取得了较好的效果。     

球孢白僵菌对烟蚜茧蜂生命参数及控害效果的影响

在室内评价了球孢白僵菌对烟蚜茧蜂生命参数及控害效果的影响。分别在烟蚜茧蜂寄生桃蚜后不同时间进行高剂量（1900孢子/mm^{2）接菌,检测蚜虫感病率和寄生蜂形成的僵蚜率及僵蚜出蜂率。结果表明,球孢白僵菌对僵蚜率和僵蚜出蜂率的影响随接菌时间不同而变化。在烟蚜茧蜂寄生前1d、寄生当天和寄生后3d接菌,蚜虫感病率分别为59.6%、56.2%和34.8%;与对照相比,僵蚜率分别下降94%、59%和47%,僵蚜出蜂率分别减少83%、54%和49%。在寄生后5d或7d接菌,僵蚜率和僵蚜出蜂率不受明显影响,但蚜虫感病率降低到8.2%以下。对蚜尸内白僵菌菌体含量检测表明,随着烟蚜茧蜂寄生后接菌时间的推移,菌体数量迅速下降。寄生蜂寄生后5d或7d接菌,蚜尸内几乎检测不到菌体。直接喷雾接菌烟蚜茧蜂,成蜂寿命缩短4d左右,且81.8%的蜂尸受白僵菌感染。接菌后的寄生蜂对蚜虫寄生率几乎无影响,但寄生蜂在蚜虫体内的存活时间缩短了27.8%。}     

球孢白僵菌对烟蚜茧蜂生命参数及控害效果的影响

在室内评价了球孢白僵菌对烟蚜茧蜂生命参数及控害效果的影响。分别在烟蚜茧蜂寄生桃蚜后不同时间进行高剂量(1900孢子/mm2)接菌,检测蚜虫感病率和寄生蜂形成的僵蚜率及僵蚜出蜂率。结果表明,球孢白僵菌对僵蚜率和僵蚜出蜂率的影响随接菌时间不同而变化。在烟蚜茧蜂寄生前1d、寄生当天和寄生后3d接菌,蚜虫感病率分别为59.6%、56.2%和34.8%;与对照相比,僵蚜率分别下降94%、59%和47%,僵蚜出蜂率分别减少83%、54%和49%。在寄生后5d或7d接菌,僵蚜率和僵蚜出蜂率不受明显影响,但蚜虫感病率降低到8.2%以下。对蚜尸内白僵菌菌体含量检测表明,随着烟蚜茧蜂寄生后接菌时间的推移,菌体数量迅速下降。寄生蜂寄生后5d或7d接菌,蚜尸内几乎检测不到菌体。直接喷雾接菌烟蚜茧蜂,成蜂寿命缩短4d左右,且81.8%的蜂尸受白僵菌感染。接菌后的寄生蜂对蚜虫寄生率几乎无影响,但寄生蜂在蚜虫体内的存活时间缩短了27.8%。     

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。     

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     

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.     

Abundance and natural control of the woolly aphid <Emphasis Type="Italic">Eriosoma lanigerum</Emphasis> in an Australian apple orchard IPM program

Woolly aphid (Eriosoma lanigerum Hausmann) (Hemiptera: Aphididae), was monitored over three growing seasons (1995--1998) to assess its abundance and management under apple IPM programs at Bathurst on the Central Tablelands of NSW, Australia. Woolly aphid infestations were found to be extremely low in IPM programs utilising mating disruption and fenoxycarb for codling moth Cydia pomonella L. (Lepidoptera: Tortricidae) control. This was the direct result of increased numbers of natural enemies. No insecticides were applied for woolly aphid control. Under the IPM strategies tested the principal control agent was identified as European earwig (Forficula auricularia L.) (Dermaptera: Forficulidae). Earwigs in combination with Aphelinus mali (Haldeman) (Hymenoptera: Aphelinidae) reduced woolly aphid infestations below the action threshold set by commercial growers. However, A. mali together with other flying natural enemies, e.g., ladybirds, lacewings and hoverflies, did not provide commercially acceptable control of woolly aphid in the absence of earwigs. Under the conventional spray program, using the broad-spectrum insecticide azinphos-methyl for codling moth control, the level of woolly aphid infestation increased with each successive season and biological control was not established. When azinphos-methyl was withdrawn, natural enemies migrated in and provided control of woolly aphid within one season. This is the first study to show that the biological control of woolly aphid can be achieved in a commercially viable IPM program.     

Effect of trap color and orientation on the capture of Aphelinus mali (Hymenoptera: Aphelinidae), a parasitoid of woolly apple aphid (Hemiptera: Aphididae)

The factors affecting trap capture of adult Aphelinus mali (Haldeman) (Hymenoptera: Aphelinidae) were studied in 2010-2011 in eastern Washington apple (Malus spp.) orchards infested with its host woolly apple aphid, Eriosoma lanigerum (Hausmann) (Hemiptera: Aphididae). The initial study of white sticky cards indicated that traps stapled to the trunk in a vertical orientation had the highest capture. A factorial experiment of three colors (clear, white, and yellow) by three orientations (trunk, scaffold, and hanging) indicated that yellow traps and traps on trunks caught higher numbers ofA. mali. For this reason, the recommended trap for this natural enemy is a yellow trap stapled to the trunk. Having a readily available and effective sampling method for this species may be helpful in implementing biological control programs and assessing the impact of different spray regimes.     

Comparison of a Canadian and a Dutch strain of the parasitoid Aphelinus mali (Hald) (Hym., Aphelinidae) for control of woolly apple aphid Eriosoma lanigerum (Haussmann) (Hom., Aphididae) in the Netherlands: a simulation approach

Woolly apple aphid, Eriosoma lanigerum is one of the important apple pests in the Netherlands. Weather conditions and natural enemies determine whether woolly apple aphid (WAA) will reach pest status. WAA may escape control by natural enemies and therefore it must be controlled using chemical insecticides. To prevent unnecessary applications of insecticides and to promote biological and natural control of WAA more knowledge is needed about the role of natural enemies, weather and their effects on the development of WAA populations. The monophagous parasitoid Aphelinus mali (Hald.) has been introduced into most of apple growing areas to control WAA, but success is variable and depends on climatological conditions. In the Netherlands the level of parasitization is often too low, especially after warm winters. The biological control potential of a strain of A. mali from Nova Scotia (Canada) was compared with a Dutch strain by simulating population growth of both WAA and the Dutch and Canadian strain of the parasitoid for three different years The results indicate that the Canadian strain would perform in general better than the Dutch strain under Dutch weather conditions.     

Phenological dynamics of Dasineura mali (Diptera: Cecidomyiidae) and its parasitoid Platygaster demades (Hymenoptera: Platygasteridae) in apple orchards

The midge Dasineura mali Kieffer (Diptera: Cecidomyiidae) is an important pest of apple (Malus domestica Borkh.) and a potential fresh fruit contaminant, causing quarantine concerns. The phenological dynamics of D. mali and its egg parasitoid Platygaster demades Walker (Hymenoptera: Platygasteridae) were studied in the field in Palmerston North, New Zealand, for 2 yr. Both shoot infestation rate by D. mali and D. mali density per shoot sharply increased in the second generation, reaching approximately 65% and 100-200 eggs, respectively. However, although the infestation rate in the third generation remained as high as in the second generation, the pest density per shoot significantly decreased to 40-60 eggs in the third generation. In the fourth generation, both infestation rate and pest density per shoot decreased to approximately 30% and 10 eggs. Due to the simultaneous decline of the apple shoot number and D. mali density in the third and fourth D. mali generations, the absolute number of D. mali in the orchard also has declined proportionally during the same period. The parasitism and superparasitism rates significantly increased as the season progressed, from 45 to 55 and 37% in the first generation to 87 and 82% in the fourth generation, respectively. Our results suggest that P. demades contributes to the continuous decline of D. mali numbers in the field; it is a good searcher, particularly when its hosts become increasingly scarcer over the season, and it avoids overshooting the host population later in the season by increasing superparasitism. The frequency of P. demades aestivation increases from late spring to midsummer and then decreases during the late summer and early autumn. Although the emergence of P. demades was approximately 2 to 3 wk behind that of D. mali in each generation, the increasing parasitism rates from the first to the fourth generations indicate that P. demades is synchronized with D. mali in the field.     

Genome mapping of an apple scab,a powdery mildew and a woolly apple aphid resistance gene from open-pollinated Mildew Immune Selection

Apple is host to a wide range of pests and diseases, with several of these, such as apple scab, powdery mildew and woolly apple aphid, being major causes of damage in most areas around the world. Resistance breeding is an effective way of controlling pests and diseases, provided that the resistance is durable. As the gene pyramiding strategy for increasing durability requires a sufficient supply of resistance genes with different modes of action, the identification and mapping of new resistance genes is an ongoing process in breeding. In this paper, we describe the mapping of an apple scab, a powdery mildew and a woolly apple aphid gene from progeny of open-pollinated mildew immune selection. The scab resistance gene Rvi16 was identified in progeny 93.051 G07-098 and mapped to linkage group 3 of apple. The mildew and woolly aphid genes were identified in accession 93.051 G02-054. The woolly aphid resistance gene Er4 mapped to linkage group 7 to a region close to where previously the genes Sd1 and Sd2, for resistance to the rosy apple leaf-curling aphid, had been mapped. The mildew resistance gene Pl-m mapped to the same region on linkage group 11 where Pl2 had been mapped previously. Flanking markers useful for marker-assisted selection have been identified for each gene.     

用海棠苗饲养苹果绵蚜的方法

报道了用1年生海棠苗作为寄主植物饲养苹果绵蚜Eriosomalanigerum(Hausmann)的方法,包括寄主植物的选取、栽培管理、接虫方法及试验结果。该方法既能为苹果绵蚜提供长期新鲜的寄主植物,又能使仔蚜很快定殖成活,十分有利于试验的连续进行,且简单经济。     

Optimal profit of the parasitation by Aphelinus mali in an IPM complementary strategy for the control of Eriosoma lanigerum

During summer the parasitoid Aphelinus mali may certainly reduce the infestation of woolly apple aphid (Eriosoma lanigerum), but studies on the single interaction rarely indicate sufficient biological control in the period May-June. In this period chemical control by spirotetramat or pirimicarb remains indispensable in order to anticipate on dense migration waves and subsequent colonization of extension shoots by E. lanigerum. The limited parasitation by A. mali around flowering is linked with a delayed emergence from diapause and with a slower reproduction rate than its host. In 2010 and 2011 the first adult flights monitored on yellow sticky traps corresponded perfectly with the currently used prediction models for A. mali. Further accurate monitoring all along the season enabled also to determine a well defined endo-parasitic phase of A. mali occurring after the small peak observed around flowering. During this endo-parasitic phase A. mali larvae reside inside their mummified host. Compounds with higher acute toxicity on A. mali adults, like chloronicotinyl insecticides (CNI's), are preferably positioned here. Selectivity in the time can then be claimed. Respecting this principle, the further parasitation potential of A. mali in summer is not hampered. Preservation of the first peak of flights of A. mali in the pre-flowering period is essential for an exponential flight increase. This is essential for the parasitation of E. lanigerum in summer, which constitutes a valuable complement in the integrated control strategy.