Sociality does not predict signal complexity in response to playback in apteronotid weakly electric fishes.

IF 1.9 2区生物学 Q3 BEHAVIORAL SCIENCES

Behavioral Ecology and Sociobiology Pub Date : 2025-01-01 Epub Date: 2025-07-10 DOI:10.1007/s00265-025-03619-y

Megan K Freiler, G Troy Smith

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引用次数: 0

Abstract

Evolution of signal structure should be influenced by the social environment in which signals are sent and received. The "social complexity hypothesis" for communicative complexity postulates that individuals living in complex social groups require complex signals to communicate effectively. This hypothesis has been supported in many vocalizing animals. In other systems and modalities, however, relationships between sociality and signal complexity are less clear. Weakly electric knifefishes represent a novel model for investigating the relationship between signal structure and social structure. South American apteronotid knifefish continuously produce quasi-sinusoidal electric organ discharges (EODs) from their tail to communicate species, sex, and status. Fish also rapidly modulate EOD frequency to produce chirps, which coordinate agonistic and courtship interactions. Sociality and chirp structure vary extensively across apteronotids. Here, we quantified chirp complexity and variation in chirp structure across six species that vary in group size: three territorial species (Apteronotus albifrons, Parapteronotus hasemani, and 'Apteronotus' bonapartii), two gregarious species (Adontosternarchus devenanzii and Adontosternarchus balaenops), and a semi-social species (Apteronotus leptorhynchus). Chirp complexity and variation in chirp structure differed substantially across species but were unrelated to sociality. Within the Apteronotus and Adontosternarchus species pairs, one species produced complex chirps, whereas the other produced relatively simple chirps. Thus, neither phylogenetic relatedness nor social structure explained variation in chirp structure or complexity in the species we examined.

Supplementary information: The online version contains supplementary material available at 10.1007/s00265-025-03619-y.

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社会性不能预测无尾纲弱电鱼对重放反应的信号复杂性。

信号结构的演变应受到信号发送和接收的社会环境的影响。交际复杂性的“社会复杂性假说”认为，生活在复杂社会群体中的个体需要复杂的信号才能进行有效的交际。这一假设在许多会发声的动物身上得到了支持。然而，在其他系统和模式中，社会性和信号复杂性之间的关系不太清楚。弱电刀鱼为研究信号结构与社会结构之间的关系提供了一个新的模型。南美无翼刀鱼不断地从它们的尾巴发出准正弦电子器官放电（eod）来交流物种、性别和地位。鱼类也会快速调节EOD频率以产生啁啾，从而协调竞争和求爱的相互作用。群居性和啁啾结构在各类人猿中差别很大。在这里，我们量化了六种不同群体大小的物种的啁啾复杂性和啁啾结构的变化：三种领地物种（albirons， parteronotus hasemani和'Apteronotus bonapartii），两种群居物种（Adontosternarchus devenanzii和Adontosternarchus balaenops），以及一种半社会物种（aponotus leptorhynchus）。啁啾的复杂性和啁啾结构的变化在不同物种之间存在很大差异，但与社会性无关。在Apteronotus和Adontosternarchus物种对中，一个物种发出复杂的啁啾，而另一个物种发出相对简单的啁啾。因此，系统发育亲缘关系和社会结构都不能解释我们所研究的物种啁啾结构或复杂性的变化。补充信息：在线版本包含补充资料，可在10.1007/s00265-025-03619-y获得。

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来源期刊

Behavioral Ecology and Sociobiology 生物-动物学

CiteScore

3.90

自引率

8.70%

发文量

146

审稿时长

3 months

期刊介绍： The journal publishes reviews, original contributions and commentaries dealing with quantitative empirical and theoretical studies in the analysis of animal behavior at the level of the individual, group, population, community, and species.