Population Density Drives Concerted Increase in Whole Brain Volume in a Wrasse Species Coris batuensis.

IF 1.8 4区心理学 Q3 BEHAVIORAL SCIENCES

Brain Behavior and Evolution Pub Date : 2025-01-01 Epub Date: 2025-02-05 DOI:10.1159/000543220

Yasmin Emery, Letizia Pessina, Redouan Bshary

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引用次数: 0

Abstract

Introduction: The factors shaping vertebrate brain evolution and cognition are broadly categorized as being either social or environmental. Yet, their relative importance is debated, partly due to the limitations associated with standard interspecific evolutionary comparisons. Here, we adopt a complementary strategy leveraging within-population variation in fish brain size to ask how variation in social and environmental factors correlates with individual brain size.

Methods: We investigated how overall brain size and brain part sizes varied between demes of the same population in the coral reef-associated batu coris Coris batuensis. This species is ideal for our approach because its local population densities are dissociated from both interspecific densities and habitat complexity.

Results: We found that individuals from demes with higher population densities possess larger overall brain volumes than those from lower population density environments, caused by an enlargement of all five main brain regions. Brain anatomical measures show no correlation with interspecific density or habitat complexity.

Conclusion: Our results suggest that variation in intraspecific social challenges is selected on individual batu coris brain size, either through phenotypic plasticity, differential survival, or habitat choice. These results conform with a broader version of the social brain hypothesis, emphasizing the importance of the entire brain over specific regions like the neocortex in mammals or the telencephalon in fishes.

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种群密度驱动濑鱼全脑容量的一致增加。

影响脊椎动物大脑进化和认知的因素大致可分为社会因素和环境因素。然而，它们的相对重要性是有争议的，部分原因是由于标准种间进化比较的局限性。在这里，我们采用了一种互补策略，利用鱼脑大小的种群内变化来询问社会和环境因素的变化如何与个体脑大小相关。方法：我们研究了在珊瑚礁相关的batu coris coris batuensis中，相同种群的脑大小和脑部分大小在不同的巢中是如何变化的。该物种是我们研究方法的理想选择，因为它的种群密度与种间密度和栖息地复杂性都是分离的。结果：我们发现，来自人口密度较高的环境的个体比来自人口密度较低环境的个体拥有更大的总体脑容量，这是由于所有五个主要大脑区域都扩大了。脑解剖测量显示与种间密度或生境复杂性没有相关性。结论：我们的研究结果表明，种内社会挑战的变化通过表型可塑性、差异生存或栖息地选择来选择个体脑大小。这些结果与社会大脑假说的一个更广泛的版本相一致，强调了整个大脑比特定区域（如哺乳动物的新皮层或鱼类的端脑）的重要性。

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

Brain Behavior and Evolution 医学-行为科学

CiteScore

3.10

自引率

23.50%

发文量

审稿时长

>12 weeks

期刊介绍： ''Brain, Behavior and Evolution'' is a journal with a loyal following, high standards, and a unique profile as the main outlet for the continuing scientific discourse on nervous system evolution. The journal publishes comparative neurobiological studies that focus on nervous system structure, function, or development in vertebrates as well as invertebrates. Approaches range from the molecular over the anatomical and physiological to the behavioral. Despite this diversity, most papers published in ''Brain, Behavior and Evolution'' include an evolutionary angle, at least in the discussion, and focus on neural mechanisms or phenomena. Some purely behavioral research may be within the journal’s scope, but the suitability of such manuscripts will be assessed on a case-by-case basis. The journal also publishes review articles that provide critical overviews of current topics in evolutionary neurobiology.