Meta-analysis of the acoustic adaptation hypothesis reveals no support for the effect of vegetation structure on acoustic signalling across terrestrial vertebrates.

IF 11 1区 生物学 Q1 BIOLOGY
Bárbara Freitas, Pietro B D'Amelio, Borja Milá, Christophe Thébaud, Tim Janicke
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引用次数: 0

Abstract

Acoustic communication plays a prominent role in various ecological and evolutionary processes involving social interactions. The properties of acoustic signals are thought to be influenced not only by the interaction between signaller and receiver but also by the acoustic characteristics of the environment through which the signal is transmitted. This conjecture forms the core of the so-called "acoustic adaptation hypothesis" (AAH), which posits that vegetation structure affects frequency and temporal parameters of acoustic signals emitted by a signaller as a function of their acoustic degradation properties. Specifically, animals in densely vegetated "closed habitats" are expected to produce longer acoustic signals with lower repetition rates and lower frequencies (minimum, mean, maximum, and peak) compared to those inhabiting less-vegetated "open habitats". To date, this hypothesis has received mixed results, with the level of support depending on the taxonomic group and the methodology used. We conducted a systematic literature search of empirical studies testing for an effect of vegetation structure on acoustic signalling and assessed the generality of the AAH using a meta-analytic approach based on 371 effect sizes from 75 studies and 57 taxa encompassing birds, mammals and amphibians. Overall, our results do not provide consistent support for the AAH, neither in within-species comparisons (suggesting no overall phenotypically plastic response of acoustic signalling to vegetation structure) nor in among-species comparisons (suggesting no overall evolutionary response). However, when considering birds only, we found weak support for the AAH in within-species comparisons, which was mainly driven by studies that measured frequency bandwidth, suggesting that this variable may exhibit a phenotypically plastic response to vegetation structure. For among-species comparisons in birds, we also found support for the AAH, but this effect was not significant after excluding comparative studies that did not account for phylogenetic non-independence. Collectively, our synthesis does not support a universal role of vegetation structure in the evolution of acoustic communication. We highlight the need for more empirical work on currently under-studied taxa such as amphibians, mammals, and insects. Furthermore, we propose a framework for future research on the AAH. We specifically advocate for a more detailed and quantitative characterisation of habitats to identify frequencies with the highest detection probability and to determine if frequencies with greater detection distances are preferentially used. Finally, we stress that empirical tests of the AAH should focus on signals that are selected for increased transmission distance.

对声学适应假说的元分析表明,植被结构对陆生脊椎动物的声学信号没有影响。
声学通讯在涉及社会互动的各种生态和进化过程中发挥着重要作用。人们认为,声学信号的特性不仅受信号发出者和接收者之间互动的影响,而且还受信号传播环境的声学特性的影响。这一猜想构成了所谓的 "声适应假说"(AAH)的核心,该假说认为植被结构会影响信号发出者发出的声信号的频率和时间参数,这是其声学退化特性的函数。具体来说,与植被较少的 "开放生境 "中的动物相比,植被茂密的 "封闭生境 "中的动物发出的声信号会更长,重复率更低,频率(最小值、平均值、最大值和峰值)也更低。迄今为止,这一假设得到的结果不一,支持程度取决于分类群和所用方法。我们对检验植被结构对声学信号影响的实证研究进行了系统的文献检索,并根据来自鸟类、哺乳动物和两栖动物等 57 个分类群、75 项研究的 371 个效应大小,采用元分析方法评估了 AAH 的普遍性。总体而言,无论是在物种内比较(表明声信号对植被结构没有整体的表型可塑性响应)还是在物种间比较(表明没有整体的进化响应),我们的结果都没有为 AAH 提供一致的支持。然而,当仅考虑鸟类时,我们发现在种内比较中,AAH得到了微弱的支持,这主要是由测量频率带宽的研究驱动的,表明这一变量可能对植被结构表现出表型上的可塑性响应。在鸟类的种间比较中,我们也发现了AAH的支持,但在排除了未考虑系统发育非独立性的比较研究后,这种影响并不显著。总之,我们的综合结果并不支持植被结构在声学通讯进化中的普遍作用。我们强调需要对目前研究不足的类群(如两栖动物、哺乳动物和昆虫)开展更多的实证工作。此外,我们还提出了未来研究 AAH 的框架。我们特别主张对栖息地进行更详细、更量化的描述,以确定具有最高探测概率的频率,并确定探测距离更远的频率是否被优先使用。最后,我们强调,对 AAH 的实证检验应重点关注那些被选择用于增加传播距离的信号。
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来源期刊
Biological Reviews
Biological Reviews 生物-生物学
CiteScore
21.30
自引率
2.00%
发文量
99
审稿时长
6-12 weeks
期刊介绍: Biological Reviews is a scientific journal that covers a wide range of topics in the biological sciences. It publishes several review articles per issue, which are aimed at both non-specialist biologists and researchers in the field. The articles are scholarly and include extensive bibliographies. Authors are instructed to be aware of the diverse readership and write their articles accordingly. The reviews in Biological Reviews serve as comprehensive introductions to specific fields, presenting the current state of the art and highlighting gaps in knowledge. Each article can be up to 20,000 words long and includes an abstract, a thorough introduction, and a statement of conclusions. The journal focuses on publishing synthetic reviews, which are based on existing literature and address important biological questions. These reviews are interesting to a broad readership and are timely, often related to fast-moving fields or new discoveries. A key aspect of a synthetic review is that it goes beyond simply compiling information and instead analyzes the collected data to create a new theoretical or conceptual framework that can significantly impact the field. Biological Reviews is abstracted and indexed in various databases, including Abstracts on Hygiene & Communicable Diseases, Academic Search, AgBiotech News & Information, AgBiotechNet, AGRICOLA Database, GeoRef, Global Health, SCOPUS, Weed Abstracts, and Reaction Citation Index, among others.
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