Kato Daisuke, Aoyama Yuki, Nishida Kazuki, Takahashi Yutaka, Sakamoto Takumi, Takeda Ikuko, Tatematsu Tsuyako, Go Shiori, Saito Yutaro, Kunishima Shiho, Cheng Jinlei, Hou Lingnan, Tachibana Yoshihisa, Sugio Shouta, Kondo Reon, Eto Fumihiro, Sato Shumpei, Moorhouse Andrew J, Yao Ikuko, Kadomatsu Kenji, Setou Mitsutoshi, Wake Hiroaki
Department of Anatomy and Molecular Cell Biology, Nagoya University Graduate School of Medicine, Nagoya, Japan.
Division of Multicellular Circuit Dynamics, National Institute for Physiological Sciences, National Institutes of Natural Sciences, Okazaki, Japan.
Glia. 2023 Nov;71(11):2591-2608. doi: 10.1002/glia.24441. Epub 2023 Jul 20.
Brain function relies on both rapid electrical communication in neural circuitry and appropriate patterns or synchrony of neural activity. Rapid communication between neurons is facilitated by wrapping nerve axons with insulation by a myelin sheath composed largely of different lipids. Recent evidence has indicated that the extent of myelination of nerve axons can adapt based on neural activity levels and this adaptive myelination is associated with improved learning of motor tasks, suggesting such plasticity may enhance effective learning. In this study, we examined whether another aspect of myelin plasticity-changes in myelin lipid synthesis and composition-may also be associated with motor learning. We combined a motor learning task in mice with in vivo two-photon imaging of neural activity in the primary motor cortex (M1) to distinguish early and late stages of learning and then probed levels of some key myelin lipids using mass spectrometry analysis. Sphingomyelin levels were elevated in the early stage of motor learning while galactosylceramide levels were elevated in the middle and late stages of motor learning, and these changes were correlated across individual mice with both learning performance and neural activity changes. Targeted inhibition of oligodendrocyte-specific galactosyltransferase expression, the enzyme that synthesizes myelin galactosylceramide, impaired motor learning. Our results suggest regulation of myelin lipid composition could be a novel facet of myelin adaptations associated with learning.
脑功能依赖于神经回路中的快速电信号传导以及神经活动的适当模式或同步性。神经元之间的快速通讯是通过由主要由不同脂质组成的髓鞘包裹神经轴突来实现的。最近的证据表明,神经轴突的髓鞘化程度可以根据神经活动水平进行调整,这种适应性髓鞘化与运动任务学习的改善相关,表明这种可塑性可能会增强有效的学习。在本研究中,我们研究了髓鞘可塑性的另一个方面——髓鞘脂质合成和组成的变化——是否也与运动学习有关。我们将小鼠的运动学习任务与初级运动皮层(M1)神经活动的体内双光子成像相结合,以区分学习的早期和晚期阶段,然后使用质谱分析探测一些关键髓鞘脂质的水平。在运动学习的早期阶段,鞘磷脂水平升高,而在运动学习的中期和后期阶段,半乳糖基神经酰胺水平升高,并且这些变化在个体小鼠中与学习表现和神经活动变化均相关。靶向抑制少突胶质细胞特异性半乳糖基转移酶的表达(该酶合成髓鞘半乳糖基神经酰胺)会损害运动学习。我们的结果表明,髓鞘脂质组成的调节可能是与学习相关的髓鞘适应性的一个新方面。
