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模块化电路协调求偶策略的多样化。

A modular circuit coordinates the diversification of courtship strategies.

机构信息

Laboratory of Neurophysiology and Behavior, The Rockefeller University, New York, NY, USA.

Howard Hughes Medical Institute, New York, NY, USA.

出版信息

Nature. 2024 Nov;635(8037):142-150. doi: 10.1038/s41586-024-08028-1. Epub 2024 Oct 9.

DOI:10.1038/s41586-024-08028-1
PMID:39385031
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11540906/
Abstract

Mate recognition systems evolve rapidly to reinforce the reproductive boundaries between species, but the underlying neural mechanisms remain enigmatic. Here we leveraged the rapid coevolution of female pheromone production and male pheromone perception in Drosophila to gain insight into how the architecture of mate recognition circuits facilitates their diversification. While in some Drosophila species females produce unique pheromones that act to arouse their conspecific males, the pheromones of most species are sexually monomorphic such that females possess no distinguishing chemosensory signatures that males can use for mate recognition. We show that Drosophila yakuba males evolved the ability to use a sexually monomorphic pheromone, 7-tricosene, as an excitatory cue to promote courtship. By comparing key nodes in the pheromone circuits across multiple Drosophila species, we reveal that this sensory innovation arises from coordinated peripheral and central circuit adaptations: a distinct subpopulation of sensory neurons has acquired sensitivity to 7-tricosene and, in turn, selectively signals to a distinct subset of P1 neurons in the central brain to trigger courtship. Such a modular circuit organization, in which different sensory inputs can independently couple to parallel courtship control nodes, may facilitate the evolution of mate recognition systems by allowing novel sensory modalities to become linked to male arousal. Together, our findings suggest how peripheral and central circuit adaptations can be flexibly coordinated to underlie the rapid evolution of mate recognition strategies across species.

摘要

交配识别系统迅速进化,以强化物种间的生殖隔离,但背后的神经机制仍然神秘莫测。在这里,我们利用果蝇中雌性信息素产生和雄性信息素感知的快速共同进化,深入了解交配识别回路的结构如何促进其多样化。虽然在一些果蝇物种中,雌性产生独特的信息素,以唤起同种雄性,但大多数物种的信息素在性上是同态的,即雌性没有雄性可以用于交配识别的独特化学感觉特征。我们表明,果蝇 yakuba 雄性进化出了利用同态信息素 7-二十三碳烯作为促进求偶的兴奋性线索的能力。通过比较多个果蝇物种中信息素回路的关键节点,我们揭示了这种感觉创新源于外围和中枢回路的协调适应:一个独特的感觉神经元亚群获得了对 7-二十三碳烯的敏感性,进而选择性地向中枢大脑中特定的 P1 神经元发出信号,触发求偶。这种模块化的电路组织使得不同的感觉输入可以独立地与平行的求偶控制节点连接,从而促进了交配识别系统的进化,使新的感觉模式可以与雄性兴奋联系起来。总之,我们的研究结果表明,外围和中枢回路的适应可以灵活地协调,从而在物种间快速进化的交配识别策略中发挥作用。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6279/11540906/036af8de640b/41586_2024_8028_Fig15_ESM.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6279/11540906/036af8de640b/41586_2024_8028_Fig15_ESM.jpg

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