Kato Go, Inada Hiroyuki, Wake Hiroaki, Akiyoshi Ryohei, Miyamoto Akiko, Eto Kei, Ishikawa Tatsuya, Moorhouse Andrew J, Strassman Andrew M, Nabekura Junichi
Divison of Homeostatic Development, National Institute for Physiological Sciences, Okazaki 444-8585, Japan; Department of Physiological Sciences, The Graduate University for Advanced Studies, Okazaki 444-8585, Nishigo-naka, Myodaiji-cho, Japan.
Divison of Homeostatic Development, National Institute for Physiological Sciences, Okazaki 444-8585, Japan; Department of Physiological Sciences, The Graduate University for Advanced Studies, Okazaki 444-8585, Nishigo-naka, Myodaiji-cho, Japan; Precursory Research for Embryonic Science and Technology, Japan Science and Technology Agency, Kawaguchi 332-0012, Saitama, Japan.
eNeuro. 2016 Jun 21;3(3). doi: 10.1523/ENEURO.0004-16.2016. eCollection 2016 May-Jun.
Microglia survey and directly contact neurons in both healthy and damaged brain, but the mechanisms and functional consequences of these contacts are not yet fully elucidated. Combining two-photon imaging and patch clamping, we have developed an acute experimental model for studying the role of microglia in CNS excitotoxicity induced by neuronal hyperactivity. Our model allows us to simultaneously examine the effects of repetitive supramaximal stimulation on axonal morphology, neuronal membrane potential, and microglial migration, using cortical brain slices from Iba-1 eGFP mice. We demonstrate that microglia exert an acute and highly localized neuroprotective action under conditions of neuronal hyperactivity. Evoking repetitive action potentials in individual layer 2/3 pyramidal neurons elicited swelling of axons, but not dendrites, which was accompanied by a large, sustained depolarization of soma membrane potential. Microglial processes migrated to these swollen axons in a mechanism involving both ATP and glutamate release via volume-activated anion channels. This migration was followed by intensive microglial wrapping of affected axons and, in some cases, the removal of axonal debris that induced a rapid soma membrane repolarization back to resting potentials. When the microglial migration was pharmacologically blocked, the activity-induced depolarization continued until cell death ensued, demonstrating that the microglia-axon contact served to prevent pathological depolarization of the soma and maintain neuronal viability. This is a novel aspect of microglia surveillance: detecting, wrapping, and rescuing neuronal soma from damage due to excessive activity.
在健康和受损的大脑中,小胶质细胞都会对神经元进行监测并直接与其接触,但这些接触的机制和功能后果尚未完全阐明。结合双光子成像和膜片钳技术,我们开发了一种急性实验模型,用于研究小胶质细胞在神经元活动亢进诱导的中枢神经系统兴奋性毒性中的作用。我们的模型使我们能够使用来自Iba-1 eGFP小鼠的大脑皮质切片,同时检测重复超强刺激对轴突形态、神经元膜电位和小胶质细胞迁移的影响。我们证明,在神经元活动亢进的情况下,小胶质细胞会发挥急性且高度局部化的神经保护作用。在单个第2/3层锥体神经元中诱发重复动作电位会导致轴突肿胀,但树突不会,同时伴随着胞体膜电位的大幅持续去极化。小胶质细胞突起通过一种涉及ATP和谷氨酸经由容积激活阴离子通道释放的机制迁移至这些肿胀的轴突。这种迁移之后是小胶质细胞对受影响轴突的密集包裹,在某些情况下,还会清除轴突碎片,从而使胞体膜迅速复极化回到静息电位。当小胶质细胞的迁移被药物阻断时,活动诱导的去极化会持续直至细胞死亡,这表明小胶质细胞与轴突的接触起到了防止胞体发生病理性去极化并维持神经元活力的作用。这是小胶质细胞监测的一个新方面:检测、包裹并拯救神经元胞体免受过度活动造成的损伤。
