TUBA1A 微管蛋白减少导致转运缺陷和成年运动行为障碍。

Reduced TUBA1A Tubulin Causes Defects in Trafficking and Impaired Adult Motor Behavior.

机构信息

Department of Pediatrics, University of Colorado Anschutz Medical Campus, Aurora CO 80045.

Department of Cell and Developmental Biology, University of Colorado Anschutz Medical Campus, Aurora, CO 80045.

出版信息

eNeuro. 2020 Apr 27;7(2). doi: 10.1523/ENEURO.0045-20.2020. Print 2020 Mar/Apr.

DOI:10.1523/ENEURO.0045-20.2020

PMID:32184299

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7218002/

Abstract

Newly born neurons express high levels of TUBA1A α-tubulin to assemble microtubules for neurite extension and to provide tracks for intracellular transport. In the adult brain, expression decreases dramatically. A mouse that harbors a loss-of-function mutation in the gene encoding TUBA1A ( ) allows us to ask whether TUBA1A is important for the function of mature neurons. α-Tubulin levels are about half of wild type in juvenile brains, but are close to normal in older animals. In postnatal day (P)0 cultured neurons, reduced TUBA1A allows for assembly of less microtubules in axons resulting in more pausing during organelle trafficking. While mouse behavior is indistinguishable from wild-type siblings at weaning, mice develop adult-onset ataxia. Neurons important for motor function in remain indistinguishable from wild-type with respect to morphology and number and display no evidence of axon degeneration. neuromuscular junction (NMJ) synapses are the same size as wild-type before the onset of ataxia, but are reduced in size in older animals. Together, these data indicate that the TUBA1A-rich microtubule tracks that are assembled during development are essential for mature neuron function and maintenance of synapses over time.

摘要

新生神经元表达高水平的 TUBA1Aα-微管蛋白，用于组装微管以促进轴突延伸，并为细胞内运输提供轨道。在成年大脑中，其表达水平显著降低。携带 TUBA1A 基因编码功能丧失突变的小鼠（）使我们能够研究 TUBA1A 是否对成熟神经元的功能很重要。在幼年大脑中，α-微管蛋白的水平约为野生型的一半，但在年龄较大的动物中接近正常。在出生后第 0 天（P0）培养的神经元中，减少 TUBA1A 导致轴突中微管组装减少，从而在细胞器运输过程中产生更多的停顿。虽然小鼠在断奶时的行为与野生型兄弟姐妹无异，但会出现成年发病的共济失调。对于运动功能很重要的神经元在形态和数量上与野生型没有区别，并且没有轴突退化的证据。运动神经元-肌肉接点（NMJ）突触在共济失调发作前与野生型大小相同，但在年龄较大的动物中减小。这些数据表明，在发育过程中组装的富含 TUBA1A 的微管轨道对于成熟神经元的功能和维持突触的长期稳定至关重要。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/5ace/7218002/4026699ae506/SN-ENUJ200064F001.jpg

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TUBA1A 微管蛋白减少导致转运缺陷和成年运动行为障碍。

Reduced TUBA1A Tubulin Causes Defects in Trafficking and Impaired Adult Motor Behavior.

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