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掠食性鱼类的声音可以改变螃蟹的觅食行为,并影响双壳类动物的丰度。

Predatory fish sounds can alter crab foraging behaviour and influence bivalve abundance.

机构信息

Marine Science Center, Northeastern University, 430 Nahant Rd., Nahant, MA 01908, USA

Loggerhead Instruments, 6576 Palmer Park Circle, Sarasota, FL 34238, USA.

出版信息

Proc Biol Sci. 2014 Aug 7;281(1788):20140715. doi: 10.1098/rspb.2014.0715.

DOI:10.1098/rspb.2014.0715
PMID:24943367
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4083791/
Abstract

The risk of predation can have large effects on ecological communities via changes in prey behaviour, morphology and reproduction. Although prey can use a variety of sensory signals to detect predation risk, relatively little is known regarding the effects of predator acoustic cues on prey foraging behaviour. Here we show that an ecologically important marine crab species can detect sound across a range of frequencies, probably in response to particle acceleration. Further, crabs suppress their resource consumption in the presence of experimental acoustic stimuli from multiple predatory fish species, and the sign and strength of this response is similar to that elicited by water-borne chemical cues. When acoustic and chemical cues were combined, consumption differed from expectations based on independent cue effects, suggesting redundancies among cue types. These results highlight that predator acoustic cues may influence prey behaviour across a range of vertebrate and invertebrate taxa, with the potential for cascading effects on resource abundance.

摘要

捕食风险可以通过改变猎物的行为、形态和繁殖来对生态群落产生重大影响。尽管猎物可以使用多种感觉信号来探测捕食风险,但对于捕食者声音线索对猎物觅食行为的影响,人们知之甚少。在这里,我们表明,一种具有重要生态意义的海洋蟹类可以在一系列频率范围内探测到声音,可能是对颗粒加速的反应。此外,螃蟹在受到来自多种掠食性鱼类的实验声刺激时会抑制其资源消耗,而这种反应的迹象和强度与由水载化学线索引起的反应相似。当声信号和化学信号结合时,消耗与基于独立信号效果的预期不同,这表明信号类型之间存在冗余。这些结果表明,捕食者的声音线索可能会影响多种脊椎动物和无脊椎动物的猎物行为,从而对资源丰度产生级联效应。

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