Environmental complexity and predator density mediate a stable earwig-woolly apple aphid interaction

IF 3 2区 环境科学与生态学 Q2 ECOLOGY
Robert Bischoff , Prayan Pokharel , Paul Miedtke , Hans-Peter Piepho , Georg Petschenka
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引用次数: 0

Abstract

Regulation of insect pests by predators is an integral component of biological pest control. However, predator-prey interactions often reach a stable state leading to coexistence, which can be problematic for plant protection if the persisting herbivores exceed a damage threshold. Consequently, understanding the factors mediating this stability is crucial for successful biocontrol. Here, we investigated the predator-prey interaction of an important apple pest, the woolly apple aphid (WAA) (Eriosoma lanigerum Hausm.) (Hemiptera: Aphididae), and its predator, the omnivorous common earwig (Forficula auricularia L.) (Dermaptera: Forficulidae). To this end, we introduced increasing densities of earwigs in gauze-bagged branches harbouring defined amounts of WAA and recorded predation on individual WAA colonies for almost one month. We showed that the spatial complexity of the predation environment and the earwig density determined the predation efficiency on WAAs. Earwigs could eradicate WAAs regardless of density on short apple branches without lateral twigs (first trial). However, on longer, more complex branches (second trial), stable states of WAAs and earwigs were observed. Only the highest earwig density could completely consume WAA regardless of branch complexity. We introduce a conceptual model to describe the searching capability of earwigs, which determines their efficiency in locating prey. Our model predicts that searching capability is reduced by environmental complexity; this effect is alleviated by increased earwig density, as more predators possess a higher searching capability. Conclusively, our model explains why only the highest earwig density could completely consume WAA irrespective of complexity and illustrates how predator density and environmental complexity jointly influence predation. Thus environmental characteristics not inherent to our predator-prey interaction were a decisive factor for effective predation on gauze-bagged branches. Based on these results, reducing tree complexity by pruning or augmenting earwig populations in orchards can increase biocontrol of the WAA.

环境复杂性和捕食者密度对稳定的蠼螋-羊毛苹果蚜相互作用起着中介作用
捕食者对害虫的调控是害虫生物防治不可或缺的组成部分。然而,捕食者与被捕食者之间的相互作用通常会达到一种稳定状态,从而导致共存,但如果持续存在的食草动物超过了损害阈值,则会给植物保护带来问题。因此,了解促成这种稳定的因素对于成功的生物防治至关重要。在这里,我们研究了一种重要的苹果害虫羊毛苹果蚜(WAA)(Eriosoma lanigerum Hausm.)(半翅目:蚜科)和它的天敌杂食性普通蠼(Forficula auricularia L.)(Dermaptera: Forficulidae)之间天敌与猎物的相互作用。为此,我们在装有一定量WAA的纱布袋树枝中引入了密度不断增加的蠼,并在近一个月的时间里记录了单个WAA群落的捕食情况。结果表明,捕食环境的空间复杂性和蠼的密度决定了对WAA的捕食效率。在没有侧枝的短苹果枝上(第一次试验),无论密度如何,蠼都能消灭WAA。然而,在较长、较复杂的枝条上(第二次试验),WAAs 和蠼的状态保持稳定。无论枝条的复杂程度如何,只有最高密度的蠼才能完全消耗掉 WAA。我们引入了一个概念模型来描述蠼螋的搜索能力,它决定了蠼螋寻找猎物的效率。我们的模型预测,环境的复杂性会降低搜索能力;蠼的密度增加会缓解这种影响,因为更多的捕食者拥有更高的搜索能力。最后,我们的模型解释了为什么无论环境复杂程度如何,只有蠼密度最高的蠼才能完全吃掉WAA,并说明了捕食者密度和环境复杂程度是如何共同影响捕食的。因此,并非捕食者与被捕食者相互作用所固有的环境特征是纱袋树枝被有效捕食的决定性因素。基于这些结果,通过修剪或增加果园中的蠼种群来降低树木的复杂性,可以增加对WAA的生物控制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Basic and Applied Ecology
Basic and Applied Ecology 环境科学-生态学
CiteScore
6.90
自引率
5.30%
发文量
103
审稿时长
10.6 weeks
期刊介绍: Basic and Applied Ecology provides a forum in which significant advances and ideas can be rapidly communicated to a wide audience. Basic and Applied Ecology publishes original contributions, perspectives and reviews from all areas of basic and applied ecology. Ecologists from all countries are invited to publish ecological research of international interest in its pages. There is no bias with regard to taxon or geographical area.
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