Sex Differences in the Neural Song Circuit and Its Relationship to Song Acoustic Complexity in House Wrens (Troglodytes aedon).

IF 2.1 4区心理学 Q3 BEHAVIORAL SCIENCES

Brain Behavior and Evolution Pub Date : 2023-01-01 Epub Date: 2023-07-24 DOI:10.1159/000531959

Cara A Krieg, Juli Wade

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引用次数: 0

Abstract

The song circuit in passerine birds is an outstanding model system for understanding the relationship between brain morphology and behavior, in part due to varying degrees of sex differences in structure and function across species. House wrens (Troglodytes aedon) offer a unique opportunity to advance our understanding of this relationship. Intermediate sex differences in song rate and complexity exist in this species compared to other passerines, and, among individual females, song complexity varies dramatically. Acoustic complexity in wild house wrens was quantified using a new machine learning approach. Volume, cell number, cell density, and neuron soma size were then measured for three song circuit regions, Area X, HVC (used as a proper name), and the robust nucleus of the arcopallium (RA), and one control region, the nucleus rotundus (Rt). For each song control area, males had a larger volume with more cells, larger somas, and lower cell density. Male songs had greater acoustic complexity than female songs, but these distributions overlapped. In females, increased acoustic complexity was correlated with larger volumes of and more cells in Area X and RA, as well as larger soma size in RA. In males, song complexity was unrelated to morphology, although our methods may underestimate male song complexity. This is the first study to identify song control regions in house wrens and one of few examining individual variation in both sexes. Parallels between morphology and the striking variability in female song in this species provide a new model for understanding relationships between neural structure and function.

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家燕（Troglodytes aedon）神经歌声回路的性别差异及其与歌声复杂性的关系。

雀形目鸟类的鸣叫回路是理解大脑形态和行为之间关系的杰出模型系统，部分原因是不同物种在结构和功能上存在不同程度的性别差异。House wrens（Troglodytes aedon）提供了一个独特的机会来加深我们对这种关系的理解。与其他雀形目相比，该物种在鸣叫频率和复杂性方面存在中等性别差异，而且在雌性个体中，鸣叫复杂性差异很大。使用一种新的机器学习方法对野生家燕的声学复杂性进行了量化。然后测量三个song回路区域，即X区、HVC（用作专有名称）和强健的横纹肌核（RA），以及一个对照区域，即圆核（Rt）的体积、细胞数量、细胞密度和神经元胞体大小。对于每个歌曲控制区，雄性的体积更大，细胞更多，胞体更大，并且细胞密度更低。男性歌曲比女性歌曲具有更大的声学复杂性，但这些分布是重叠的。在女性中，声学复杂性的增加与X区和RA中细胞体积更大、数量更多以及RA中胞体大小更大有关。在雄性中，歌曲的复杂性与形态学无关，尽管我们的方法可能低估了雄性歌曲的复杂性。这是第一项确定家燕鸣叫控制区域的研究，也是少数几个检测两性个体变异的研究之一。形态和该物种雌性歌声显著变异之间的相似性为理解神经结构和功能之间的关系提供了一个新的模型。

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.