Saitoh Yurika, Ohno Nobuhiko, Yamauchi Junji, Sakamoto Takeharu, Terada Nobuo
Division of Health Sciences, Shinshu University Graduate School of Medicine, 3-1-1 Asahi, Matsumoto, Nagano, 390-8621, Japan.
Faculty of Medical Sciences, Department of Tokyo Physical Therapy, Teikyo University of Science, Adachi-ku, Tokyo, Japan.
Histochem Cell Biol. 2017 Dec;148(6):597-606. doi: 10.1007/s00418-017-1600-6. Epub 2017 Jul 28.
We previously demonstrated that a membrane skeletal molecular complex, 4.1G-membrane palmitoylated protein 6 (MPP6)-cell adhesion molecule 4, is incorporated in Schwann cells in the peripheral nervous system (PNS). In this study, we evaluated motor activity and myelin ultrastructures in 4.1G-deficient (-/-) mice. When suspended by the tail, aged 4.1G mice displayed spastic leg extension, especially after overwork. Motor-conduction velocity in 4.1G mice was slower than that in wild-type mice. Using electron microscopy, 4.1G mice exhibited myelin abnormalities: myelin was thicker in internodes, and attachment of myelin tips was distorted in some paranodes. In addition, we found a novel function of 4.1G for sorting a scaffold protein, Lin7, due to disappearance of the immunolocalization and reduction of the production of Lin7c and Lin7a in 4.1G sciatic nerves, as well as the interaction of MPP6 and Lin7 with immunoprecipitation. Thus, we herein propose 4.1G functions as a signal for proper formation of myelin in PNS.
我们之前证明,一种膜骨架分子复合物,即4.1G-膜棕榈酰化蛋白6(MPP6)-细胞黏附分子4,存在于外周神经系统(PNS)的雪旺细胞中。在本研究中,我们评估了4.1G基因缺陷(-/-)小鼠的运动活性和髓鞘超微结构。当被尾巴悬吊时,成年4.1G小鼠表现出腿部痉挛性伸展,尤其是在过度劳累后。4.1G小鼠的运动传导速度比野生型小鼠慢。通过电子显微镜观察,4.1G小鼠表现出髓鞘异常:节间髓鞘更厚,并且在一些 paranode 中髓鞘尖端的附着扭曲。此外,由于4.1G坐骨神经中Lin7的免疫定位消失、Lin7c和Lin7a的产生减少,以及MPP6和Lin7通过免疫沉淀相互作用,我们发现了4.1G在分选支架蛋白Lin7方面的新功能。因此,我们在此提出4.1G作为PNS中髓鞘正常形成的信号发挥作用。
