Forebrain NgR1 Overexpression Impairs DA Release Suggesting Synergy of Local and Global Synaptic Plasticity Mechanisms.

IF 2.8 4区 医学 Q2 NEUROSCIENCES Frontiers in Synaptic Neuroscience Pub Date : 2020-12-10 eCollection Date: 2020-01-01 DOI:10.3389/fnsyn.2020.545854
Emma Arvidsson, Sarolta Gabulya, Alvin Tore Brodin, Tobias Erik Karlsson, Lars Olson
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引用次数: 2

Abstract

Structural synaptic reorganizations needed to permanently embed novel memories in the brain involve complex plasticity-enhancing and plasticity-inhibiting systems. Increased neural activity is linked to rapid downregulation of Nogo receptor 1 (NgR1), needed to allow local structural synaptic plasticity. This local regulation of plasticity is thought to be moderated by global systems, such as the ascending cholinergic and monoaminergic systems, adding significance to locally increased neural activity. Here we address the reverse possibility that the global systems may also be influenced by the status of local plasticity. Using NgR1-overexpressing mice, with impaired plasticity and long-term memory, we measured the ability to release dopamine (DA), implicated in regulating plasticity and memory. In vivo chronoamperometric recording with high temporal and spatial resolution revealed severe impairment of potassium chloride (KCl)-induced increase of extracellular DA in the dorsal striatum of mice overexpressing NgR1 in forebrain neurons. A similar, but lesser, impairment of DA release was seen following amphetamine delivery. In contrast, potassium chloride-evoked DA release in NgR1 knockout (KO) mice led to increased levels of extracellular DA. That NgR1 can impair DA signaling, thereby further dampening synaptic plasticity, suggests a new role for NgR1 signaling, acting in synergy with DA signaling to control synaptic plasticity. Significance Statement:The inverse correlation between local NgR1 levels and magnitude of KCl-inducible amounts of DA release in the striatum reinforces the rule of NgR1 as a regulator of structural synaptic plasticity and suggests synergy between local and global plasticity regulating systems.

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前脑NgR1过表达损害DA释放提示局部和全局突触可塑性机制协同作用
在大脑中永久嵌入新记忆所需的结构性突触重组涉及复杂的可塑性增强和可塑性抑制系统。神经活动的增加与Nogo受体1 (NgR1)的快速下调有关,这是允许局部结构突触可塑性所必需的。这种局部调节的可塑性被认为是由全局系统调节的,如上升的胆碱能和单胺能系统,增加了局部增加的神经活动的意义。在这里,我们提出了相反的可能性,即全球系统也可能受到局部可塑性状态的影响。我们使用可塑性和长期记忆受损的ngr1过表达小鼠,测量其释放多巴胺(DA)的能力,多巴胺参与调节可塑性和记忆。高时间和空间分辨率的体内计时电流记录显示,在过表达NgR1的小鼠前脑神经元中,氯化钾(KCl)诱导的背纹状体细胞外DA增加严重受损。服用安非他明后,DA释放也出现类似但较轻的损伤。相反,在NgR1敲除(KO)小鼠中,氯化钾诱发的DA释放导致细胞外DA水平升高。NgR1可以损害DA信号,从而进一步抑制突触可塑性,这表明NgR1信号可能与DA信号协同作用,控制突触可塑性。意义说明:纹状体中局部NgR1水平与kcl诱导的DA释放量的大小呈负相关,强化了NgR1作为结构突触可塑性调节剂的作用,表明局部和全局可塑性调节系统之间存在协同作用。
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来源期刊
CiteScore
7.10
自引率
2.70%
发文量
74
审稿时长
14 weeks
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