Efferent axons in the zebrafish lateral line degenerate following sensory hair cell ablation

IF 2.6 3区 医学 Q3 NEUROSCIENCES Molecular and Cellular Neuroscience Pub Date : 2023-09-13 DOI:10.1016/j.mcn.2023.103900
Melek Umay Tuz-Sasik, Remy Manuel, Henrik Boije
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Abstract

The zebrafish lateral line is a frequently used model to study the mechanisms behind peripheral neuronal innervation of sensory organs and the regeneration thereof. The lateral line system consists of neuromasts, a cluster of protruding hair cells, which are innervated by sensory afferent and modulatory efferent neurons. These flow-sensing hair cells are similar to the hair cells in the mammalian ear. Though, while hair cell loss in humans is irreversible, the zebrafish neuromasts are regarded as the fastest regenerating structure in vertebrates, making them an ideal model to study regeneration. However, one component of the lateral line system, the efferent projections, has largely been omitted in regenerative studies. Here, for the first time, we bring insights into the fate of efferent axons during ablation and regeneration of the hair cells in the zebrafish lateral line. Our behavioral analysis showed functional recovery of hair cells and sensory transmission within 48 h and their regeneration were in line with previous studies. Analysis of the inhibitory efferent projections revealed that in approximately half the cases the inhibitory efferent axons degenerated, which was never observed for the sensory afferent axons. Quantification of hair cells following ablation suggests that the presence of mature hair cells in the neuromast may prevent axon degeneration. Within 120 h, degenerated efferent axons regenerated along the axonal tract of the lateral line. Reanalysis of published single cell neuromast data hinted to a role for Bdnf in the survival of efferent axons. However, sequestering Bdnf, blocking the Trk-receptors, and inhibiting the downstream ERK-signaling, did not induce axon degeneration, indicating that efferent survival is not mediated through neurotrophic factors. To further explore the relation between hair cells and efferent projections, we generated atoh1a mutants, where mature hair cells never form. In larvae lacking hair cells, inhibitory efferent projections were still present, following the tract of the sensory afferent without displaying any innervation. Our study reveal the fate of efferent innervation following hair cell ablation and provide insights into the inherent differences in regeneration between neurons in the peripheral and central nervous system.

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斑马鱼侧线的传出轴突在感觉毛细胞消融后退化
斑马鱼侧线是研究感觉器官的外周神经元神经支配及其再生机制的常用模型。侧线系统由神经瘤组成,神经瘤是一簇突出的毛细胞,由感觉传入和调节传出神经元支配。这些流动感应毛细胞与哺乳动物耳朵中的毛细胞相似。尽管人类的毛细胞损失是不可逆转的,但斑马鱼神经瘤被认为是脊椎动物中再生最快的结构,是研究再生的理想模型。然而,在再生研究中,侧线系统的一个组成部分,传出投射,在很大程度上被忽略了。在这里,我们首次深入了解了斑马鱼侧线毛细胞消融和再生过程中传出轴突的命运。我们的行为分析显示,毛细胞的功能恢复和感觉传递在48小时内,其再生与先前的研究一致。对抑制性传出投射的分析显示,在大约一半的病例中,抑制性传出轴突退化,而在感觉传入轴突中从未观察到这种情况。消融后毛细胞的定量表明,神经基质中成熟毛细胞的存在可以防止轴突变性。在120小时内,退化的传出轴突沿着侧线的轴突束再生。对已发表的单细胞神经母细胞数据的重新分析提示Bdnf在传出轴突存活中的作用。然而,螯合Bdnf、阻断Trk受体和抑制下游ERK信号传导并没有诱导轴突变性,这表明传出存活不是通过神经营养因子介导的。为了进一步探索毛细胞和传出投射之间的关系,我们产生了atoh1a突变体,在这种突变体中,成熟的毛细胞永远不会形成。在缺乏毛细胞的幼虫中,抑制性传出投射仍然存在,沿着感觉传入通道,没有表现出任何神经支配。我们的研究揭示了毛细胞消融后传出神经支配的命运,并深入了解了外周神经系统和中枢神经系统神经元再生的内在差异。
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来源期刊
CiteScore
5.60
自引率
0.00%
发文量
65
审稿时长
37 days
期刊介绍: Molecular and Cellular Neuroscience publishes original research of high significance covering all aspects of neurosciences indicated by the broadest interpretation of the journal''s title. In particular, the journal focuses on synaptic maintenance, de- and re-organization, neuron-glia communication, and de-/regenerative neurobiology. In addition, studies using animal models of disease with translational prospects and experimental approaches with backward validation of disease signatures from human patients are welcome.
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