Loss of MEGF10 Decreases the Number of Perisynaptic Schwann Cells and Innervation of Neuromuscular Junctions in Aging Mice

IF 3.9 3区医学 Q1 CLINICAL NEUROLOGY

Journal of the Peripheral Nervous System Pub Date : 2025-03-18 DOI:10.1111/jns.70014

Devin Juros, Robert Louis Hastings, Ariane Pendragon, Jeremy Kay, Gregorio Valdez

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引用次数: 0

Abstract

Background and Aims

At the neuromuscular junction (NMJ), the synapse between motor neurons and muscle fibers, reside perisynaptic Schwann cells (PSCs) which are specialized glia that regulate the maintenance and repair of this synapse. While we know how PSC morphology and numbers change in aging and various neuromuscular disorders that adversely affect the NMJ, the molecular mechanisms that alter PSC functions remain unknown. In this study, we investigated whether MEGF10 in PSCs modulates NMJ stability in developing, healthy young adult, middle-aged, and axotomized mice. MEGF10 is a glial phagocytic receptor that is enriched in PSCs compared to other Schwann cells (SCs).

Methods

We isolated PSCs from a transgenic reporter mouse line to assess Megf10 expression at different ages and following nerve injury using qPCR. We then used a conditional mouse lacking Megf10 in all SCs, including PSCs (Megf10 SC-KO mice). We examined NMJs and axonal debris clearance in Megf10 SC-KO mice using confocal microscopy.

Results

We found that Megf10 expression in PSCs peaks during development and decreases during aging and following denervation of NMJs. NMJs were morphologically normal in developing and young adult Megf10 SC-KO mice. This was not the case in middle-aged Megf10 SC-KO mice, in which NMJs presented with fewer PSCs, decreased PSC coverage of the endplate, and decreased innervation in comparison to control mice. Following nerve injury-induced damage, axonal debris at the NMJ was cleared faster in Megf10 SC-KO mice; yet, the rate of reinnervation was unchanged compared to control mice.

Interpretation

The data in this study suggest that MEGF10 in PSCs functions to maintain PSC number and NMJ innervation during aging. This study also suggests important roles for MEGF10 in mediating the clearance of axonal debris at NMJs following nerve injury.

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缺失 MEGF10 会减少老龄小鼠突触周围许旺细胞的数量和神经肌肉接头的神经支配能力

背景与目的在神经肌肉连接处（NMJ），即运动神经元和肌纤维之间的突触，存在着突触周围雪旺细胞（PSCs），它是一种特化的胶质细胞，调节该突触的维持和修复。虽然我们知道PSC的形态和数量在衰老和各种不利影响NMJ的神经肌肉疾病中如何变化，但改变PSC功能的分子机制仍然未知。在这项研究中，我们研究了psc中的MEGF10是否调节发育中、健康的青壮年、中年和axocut小鼠的NMJ稳定性。MEGF10是一种胶质吞噬受体，与其他雪旺细胞（SCs）相比，在PSCs中富集。方法从转基因报告小鼠系中分离PSCs，采用qPCR检测不同年龄和神经损伤后Megf10的表达。然后，我们在包括PSCs在内的所有SCs中使用缺乏Megf10的条件小鼠（Megf10 SC-KO小鼠）。我们使用共聚焦显微镜检测Megf10 SC-KO小鼠的NMJs和轴突碎片清除。结果我们发现，Megf10在PSCs中的表达在发育期间达到峰值，在衰老和NMJs去神经支配后下降。在发育和年轻成年Megf10 SC-KO小鼠中，NMJs形态正常。在中年Megf10 SC-KO小鼠中情况并非如此，与对照小鼠相比，NMJs呈现出更少的PSC，终板上PSC覆盖范围减少，神经支配减少。在神经损伤后，Megf10 SC-KO小鼠NMJ轴突碎片被更快地清除；然而，与对照小鼠相比，神经再生率没有变化。本研究数据表明，在衰老过程中，PSC中的MEGF10具有维持PSC数量和NMJ神经支配的功能。该研究还提示MEGF10在神经损伤后介导NMJs轴突碎片清除中发挥重要作用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of the Peripheral Nervous System 医学-临床神经学

CiteScore

6.10

自引率

7.90%

发文量

审稿时长

>12 weeks

期刊介绍： The Journal of the Peripheral Nervous System is the official journal of the Peripheral Nerve Society. Founded in 1996, it is the scientific journal of choice for clinicians, clinical scientists and basic neuroscientists interested in all aspects of biology and clinical research of peripheral nervous system disorders. The Journal of the Peripheral Nervous System is a peer-reviewed journal that publishes high quality articles on cell and molecular biology, genomics, neuropathic pain, clinical research, trials, and unique case reports on inherited and acquired peripheral neuropathies. Original articles are organized according to the topic in one of four specific areas: Mechanisms of Disease, Genetics, Clinical Research, and Clinical Trials. The journal also publishes regular review papers on hot topics and Special Issues on basic, clinical, or assembled research in the field of peripheral nervous system disorders. Authors interested in contributing a review-type article or a Special Issue should contact the Editorial Office to discuss the scope of the proposed article with the Editor-in-Chief.