Smith Jennifer N, Emlen Douglas J, Pearson Dean E
Division of Biological Sciences, University of Montana, Missoula, Montana, United States of America.
Rocky Mountain Research Station, United States Department of Agriculture, Forest Service, Missoula, Montana, United States of America.
PLoS One. 2016 Apr 15;11(4):e0153661. doi: 10.1371/journal.pone.0153661. eCollection 2016.
Theoretically, the functional traits of native species should determine how natives respond to invader-driven changes. To explore this idea, we simulated a large-scale plant invasion using dead spotted knapweed (Centaurea stoebe) stems to determine if native spiders' web-building behaviors could explain differences in spider population responses to structural changes arising from C. stoebe invasion. After two years, irregular web-spiders were >30 times more abundant and orb weavers were >23 times more abundant on simulated invasion plots compared to controls. Additionally, irregular web-spiders on simulated invasion plots built webs that were 4.4 times larger and 5.0 times more likely to capture prey, leading to >2-fold increases in recruitment. Orb-weavers showed no differences in web size or prey captures between treatments. Web-spider responses to simulated invasion mimicked patterns following natural invasions, confirming that C. stoebe's architecture is likely the primary attribute driving native spider responses to these invasions. Differences in spider responses were attributable to differences in web construction behaviors relative to historic web substrate constraints. Orb-weavers in this system constructed webs between multiple plants, so they were limited by the overall quantity of native substrates but not by the architecture of individual native plant species. Irregular web-spiders built their webs within individual plants and were greatly constrained by the diminutive architecture of native plant substrates, so they were limited both by quantity and quality of native substrates. Evaluating native species traits in the context of invader-driven change can explain invasion outcomes and help to identify factors limiting native populations.
从理论上讲,本地物种的功能性状应能决定其对入侵者引发的变化的反应方式。为探究这一观点,我们用死亡的斑点矢车菊(Centaurea stoebe)茎模拟了一场大规模的植物入侵,以确定本地蜘蛛的结网行为能否解释蜘蛛种群对由C. stoebe入侵引起的结构变化的反应差异。两年后,与对照相比,模拟入侵地块上不规则结网蜘蛛的数量多出30倍以上,圆网蜘蛛的数量多出23倍以上。此外,模拟入侵地块上的不规则结网蜘蛛所结的网面积大4.4倍,捕获猎物的可能性高5.0倍,导致繁殖量增加2倍以上。不同处理之间,圆网蜘蛛在网的大小或猎物捕获方面没有差异。结网蜘蛛对模拟入侵的反应模仿了自然入侵后的模式,证实C. stoebe的结构可能是驱动本地蜘蛛对这些入侵做出反应的主要因素。蜘蛛反应的差异归因于相对于历史网底物限制而言的结网行为差异。该系统中的圆网蜘蛛在多株植物之间结网,因此它们受到本地底物总量的限制,但不受单个本地植物物种结构的限制。不规则结网蜘蛛在单株植物内结网,受到本地植物底物微小结构的极大限制,因此它们受到本地底物数量和质量的双重限制。在入侵者引发的变化背景下评估本地物种性状可以解释入侵结果,并有助于确定限制本地种群数量的因素。
