Division of Biological Science, Graduate School of Science, Nagoya University, Nagoya, Aichi, Japan.
HHMI Janelia Research Campus, Ashburn, Virginia.
J Comp Neurol. 2020 Aug;528(12):2068-2098. doi: 10.1002/cne.24877. Epub 2020 Feb 19.
Many animals rely on acoustic cues to decide what action to take next. Unraveling the wiring patterns of the auditory neural pathways is prerequisite for understanding such information processing. Here, we reconstructed the first step of the auditory neural pathway in the fruit fly brain, from primary to secondary auditory neurons, at the resolution of transmission electron microscopy. By tracing axons of two major subgroups of auditory sensory neurons in fruit flies, low-frequency tuned Johnston's organ (JO)-B neurons and high-frequency tuned JO-A neurons, we observed extensive connections from JO-B neurons to the main second-order neurons in both the song-relay and escape pathways. In contrast, JO-A neurons connected strongly to a neuron in the escape pathway. Our findings suggest that heterogeneous JO neuronal populations could be recruited to modify escape behavior whereas only specific JO neurons contribute to courtship behavior. We also found that all JO neurons have postsynaptic sites at their axons. Presynaptic modulation at the output sites of JO neurons could affect information processing of the auditory neural pathway in flies.
许多动物依赖声学线索来决定下一步采取什么行动。揭示听觉神经通路的布线模式是理解这种信息处理的前提。在这里,我们在透射电子显微镜的分辨率下重建了果蝇大脑中听觉神经通路的第一步,从初级到次级听觉神经元。通过追踪果蝇中两个主要亚群听觉感觉神经元的轴突,低频调谐的约翰斯顿氏器(JO)-B 神经元和高频调谐的 JO-A 神经元,我们观察到来自 JO-B 神经元的广泛连接到歌曲传递和逃避途径中的主要二级神经元。相比之下,JO-A 神经元与逃避途径中的一个神经元强烈连接。我们的研究结果表明,不同的 JO 神经元群体可以被招募来改变逃避行为,而只有特定的 JO 神经元有助于求偶行为。我们还发现所有的 JO 神经元在它们的轴突上都有突触后位点。JO 神经元输出位点的突触前调制可能会影响果蝇听觉神经通路的信息处理。
