Defects in exosome biogenesis are associated with sensorimotor defects in zebrafish vps4a mutants.

IF 4.4 2区 医学 Q1 NEUROSCIENCES
Anna Shipman, Yan Gao, Desheng Liu, Shan Sun, Jingjing Zang, Peng Sun, Zoha Syed, Amol Bhagavathi, Eliot Smith, Timothy Erickson, Matthew Hill, Stephan Neuhauss, Sen-Fang Sui, Teresa Nicolson
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引用次数: 0

Abstract

Mutations in human VPS4A are associated with neurodevelopmental defects, including motor delays and defective muscle tone. VPS4A encodes a AAA-ATPase required for membrane scission, but how mutations in VPS4A lead to impaired control of motor function is not known. Here we identified a mutation in zebrafish vps4a, T248I, that affects sensorimotor transformation. Biochemical analyses indicate that the T248I mutation reduces the ATPase activity of Vps4a and disassembly of ESCRT filaments, which mediate membrane scission. Consistent with the role for Vps4a in exosome biogenesis, vps4aT248I larvae have enlarged endosomal compartments in the CNS and decreased numbers of circulating exosomes in brain ventricles. Resembling the central form of hypotonia in VPS4A patients, motor neurons and muscle cells are functional in mutant zebrafish. Both somatosensory and vestibular inputs robustly evoke tail and eye movements, respectively. In contrast, optomotor responses, vestibulospinal, and acoustic startle reflexes are absent or strongly impaired in vps4aT248I larvae, indicating a greater sensitivity of these circuits to the T248I mutation. ERG recordings revealed intensity-dependent deficits in the retina, and in vivo calcium imaging of the auditory pathway identified a moderate reduction in afferent neuron activity, partially accounting for the severe motor impairments in mutant larvae. Further investigation of central pathways in vps4aT248I mutants showed that activation of descending vestibulospinal and midbrain motor command neurons by sensory cues is strongly reduced. Our results suggest that defects in sensorimotor transformation underly the profound yet selective effects on motor reflexes resulting from the loss of membrane scission mediated by Vps4a.Significance Statement Here we present a T248I mutation in vps4a, which causes sensorimotor defects in zebrafish larvae. Vps4a plays a key role in membrane scission. Spanning biochemical to systems level analyses, our study indicates that a reduction in Vps4a enzymatic activity leads to abnormalities in membrane-scission dependent processes such as endosomal protein trafficking and exosome biogenesis, resulting in pronounced deficits in sensorimotor transformation of visual, auditory, and vestibular cues. We suggest that the mechanisms underlying this type of dysfunction in zebrafish may also contribute to the condition seen in human patients with de novo mutations in the human VPS4A orthologue.

外泌体生物生成缺陷与斑马鱼 vps4a 突变体的感觉运动缺陷有关。
人类 VPS4A 基因突变与神经发育缺陷有关,包括运动迟缓和肌张力缺陷。VPS4A 编码膜裂解所需的 AAA-ATP 酶,但 VPS4A 突变如何导致运动功能控制受损尚不清楚。在这里,我们发现了斑马鱼 vps4a 的一个突变 T248I,它会影响感觉运动的转化。生化分析表明,T248I突变降低了Vps4a的ATP酶活性和ESCRT细丝的解体,而ESCRT细丝介导了膜的裂解。与 Vps4a 在外泌体生物发生中的作用相一致,vps4aT248I 幼虫的中枢神经系统内的内泌体分区增大,脑室中的循环外泌体数量减少。与 VPS4A 患者的中枢性肌张力低下相似,突变斑马鱼的运动神经元和肌肉细胞都具有功能。躯体感觉和前庭输入分别能强有力地诱发尾部和眼部运动。与此相反,vps4aT248I 幼体的视运动反应、前庭神经和声惊吓反射消失或严重受损,这表明这些回路对 T248I 突变更敏感。ERG记录显示视网膜存在强度依赖性缺陷,听觉通路的活体钙成像发现传入神经元活动适度减少,这部分解释了突变体幼虫的严重运动障碍。对 vps4aT248I 突变体的中枢通路的进一步研究表明,感觉线索对前庭脊髓和中脑运动指令神经元的下行激活作用大大降低。我们的研究结果表明,Vps4a介导的膜裂缺失对运动反射产生了深远但具有选择性的影响,而这正是感觉运动转化缺陷的基础。 意义声明 我们在这里发现了vps4a的T248I突变,它导致斑马鱼幼体的感觉运动缺陷。Vps4a 在膜裂解中起着关键作用。从生物化学到系统水平的分析,我们的研究表明,Vps4a酶活性的降低会导致膜裂解依赖过程(如内体蛋白贩运和外泌体生物生成)的异常,从而导致视觉、听觉和前庭信号的感觉运动转换出现明显缺陷。我们认为,斑马鱼这种功能障碍的基本机制也可能导致人类 VPS4A 同源物发生新突变的人类患者出现这种情况。
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来源期刊
Journal of Neuroscience
Journal of Neuroscience 医学-神经科学
CiteScore
9.30
自引率
3.80%
发文量
1164
审稿时长
12 months
期刊介绍: JNeurosci (ISSN 0270-6474) is an official journal of the Society for Neuroscience. It is published weekly by the Society, fifty weeks a year, one volume a year. JNeurosci publishes papers on a broad range of topics of general interest to those working on the nervous system. Authors now have an Open Choice option for their published articles
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