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与鸟鸣相关的大脑和行为中性别差异程度的物种变化:适应性与局限性

Species variation in the degree of sex differences in brain and behaviour related to birdsong: adaptations and constraints.

作者信息

Ball Gregory F

机构信息

Department of Psychology, University of Maryland, College Park, MD 20742, USA

出版信息

Philos Trans R Soc Lond B Biol Sci. 2016 Feb 19;371(1688):20150117. doi: 10.1098/rstb.2015.0117. Epub 2016 Feb 1.

DOI:10.1098/rstb.2015.0117
PMID:26833837
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4785902/
Abstract

The song-control system, a neural circuit that controls the learning and production of birdsong, provided the first example in vertebrates of prominent macro-morphological sex differences in the brain. Forebrain nuclei HVC, robust nucleus of the arcopallium (RA) and area X all exhibit prominent male-biased sex differences in volume in zebra finches and canaries. Subsequent studies compared species that exhibited different degrees of a sex difference in song behaviour and revealed an overall positive correlation between male biases in song behaviour and male biases in the volume of the song nuclei. However, several exceptions have been described in which male biases in HVC and RA are observed even though song behaviour is equal or even female-biased. Other phenotypic measures exhibit lability in both sexes. In the duetting plain-tailed wren (Pheugopedius euophrys), males and females have auditory cells in the song system that are tuned to the joint song the two sexes produce rather than just male or female components. These findings suggest that there may be constraints on the adaptive response of the song system to ecological conditions as assessed by nucleus volume but that other critical variables regulating song can respond so that each sex can modify its song behaviour as needed.

摘要

鸣唱控制系统是一种控制鸟类鸣叫学习和发声的神经回路,它是脊椎动物大脑中显著宏观形态性别差异的首个例子。前脑核团HVC、古纹状体粗核(RA)和X区在斑胸草雀和金丝雀的体积上均表现出明显的雄性偏向性性别差异。后续研究比较了在鸣叫行为中表现出不同程度性别差异的物种,发现鸣叫行为中的雄性偏向与鸣叫核团体积的雄性偏向之间总体呈正相关。然而,也有一些例外情况被描述,即尽管鸣叫行为相同甚至偏向雌性,但在HVC和RA中仍观察到雄性偏向。其他表型测量在两性中都表现出易变性。在二重唱的纯色尾鹩莺中,雄性和雌性在鸣叫系统中都有听觉细胞,这些细胞被调整到两性共同发出的鸣叫上,而不仅仅是雄性或雌性的成分。这些发现表明,根据核团体积评估,鸣叫系统对生态条件的适应性反应可能存在限制,但调节鸣叫的其他关键变量可以做出反应,以便两性都能根据需要改变其鸣叫行为。

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