Departments of Otolaryngology, Neuroscience & Physiology, and the Neuroscience Institute, New York University Grossman School of Medicine, New York, New York 10016.
National Institutes of Natural Sciences, Exploratory Research Center on Life and Living Systems (ExCELLS), National Institute for Basic Biology, Okazaki, Aichi 444-8787, Japan.
J Neurosci. 2024 Jul 24;44(30):e2315232024. doi: 10.1523/JNEUROSCI.2315-23.2024.
Mature vertebrates maintain posture using vestibulospinal neurons that transform sensed instability into reflexive commands to spinal motor circuits. Postural stability improves across development. However, due to the complexity of terrestrial locomotion, vestibulospinal contributions to postural refinement in early life remain unexplored. Here we leveraged the relative simplicity of underwater locomotion to quantify the postural consequences of losing vestibulospinal neurons during development in larval zebrafish of undifferentiated sex. By comparing posture at two timepoints, we discovered that later lesions of vestibulospinal neurons led to greater instability. Analysis of thousands of individual swim bouts revealed that lesions disrupted movement timing and corrective reflexes without impacting swim kinematics, and that this effect was particularly strong in older larvae. Using a generative model of swimming, we showed how these disruptions could account for the increased postural variability at both timepoints. Finally, late lesions disrupted the fin/trunk coordination observed in older larvae, linking vestibulospinal neurons to postural control schemes used to navigate in depth. Since later lesions were considerably more disruptive to postural stability, we conclude that vestibulospinal contributions to balance increase as larvae mature. Vestibulospinal neurons are highly conserved across vertebrates; we therefore propose that they are a substrate for developmental improvements to postural control.
成熟的脊椎动物通过前庭脊髓神经元来维持姿势,这些神经元将感知到的不稳定性转化为对脊髓运动回路的反射性指令。姿势稳定性在发育过程中会逐渐提高。然而,由于陆地运动的复杂性,前庭脊髓神经元对早期生命中姿势调整的贡献仍未得到探索。在这里,我们利用水下运动的相对简单性,量化了在未分化性别幼鱼发育过程中失去前庭脊髓神经元后对姿势的影响。通过比较两个时间点的姿势,我们发现后期前庭脊髓神经元的损伤会导致更大的不稳定性。对数千个单独游泳回合的分析表明,损伤会破坏运动的时机和纠正反射,而不会影响游泳运动学,并且这种影响在较老的幼虫中更为强烈。使用游泳的生成模型,我们展示了这些干扰如何解释在两个时间点增加的姿势可变性。最后,晚期损伤破坏了在较大幼虫中观察到的鳍/躯干协调,将前庭脊髓神经元与用于在深度中导航的姿势控制方案联系起来。由于后期损伤对姿势稳定性的破坏要大得多,我们得出结论,前庭脊髓神经元对平衡的贡献随着幼虫的成熟而增加。前庭脊髓神经元在脊椎动物中高度保守;因此,我们提出它们是姿势控制发育改善的基础。