Ultrastructural Evidence for a Role of Astrocytes and Glycogen-Derived Lactate in Learning-Dependent Synaptic Stabilization

E. Vezzoli, C. Calì, M. De Roo, L. Ponzoni, E. Sogne, N. Gagnon, M. Francolini, D. Braida, M. Sala, D. Muller, A. Falqui, P. Magistretti
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引用次数: 39

Abstract

Abstract Long-term memory formation (LTM) is a process accompanied by energy-demanding structural changes at synapses and increased spine density. Concomitant increases in both spine volume and postsynaptic density (PSD) surface area have been suggested but never quantified in vivo by clear-cut experimental evidence. Using novel object recognition in mice as a learning task followed by 3D electron microscopy analysis, we demonstrate that LTM induced all aforementioned synaptic changes, together with an increase in the size of astrocytic glycogen granules, which are a source of lactate for neurons. The selective inhibition of glycogen metabolism in astrocytes impaired learning, affecting all the related synaptic changes. Intrahippocampal administration of l-lactate rescued the behavioral phenotype, along with spine density within 24 hours. Spine dynamics in hippocampal organotypic slices undergoing theta burst-induced long-term potentiation was similarly affected by inhibition of glycogen metabolism and rescued by l-lactate. These results suggest that learning primes astrocytic energy stores and signaling to sustain synaptic plasticity via l-lactate.
星形胶质细胞和糖原来源乳酸在学习依赖性突触稳定中的作用的超微结构证据
长期记忆形成(LTM)是一个伴随着能量需求的突触结构变化和脊柱密度增加的过程。脊柱体积和突触后密度(PSD)表面积同时增加,但从未在体内通过明确的实验证据进行量化。利用小鼠的新物体识别作为学习任务,然后进行3D电子显微镜分析,我们证明LTM诱导了上述所有突触变化,以及星形细胞糖原颗粒大小的增加,星形细胞糖原颗粒是神经元乳酸的来源。星形胶质细胞糖原代谢的选择性抑制损害了学习,影响了所有相关的突触变化。海马内给药l-乳酸可在24小时内恢复行为表型和脊柱密度。海马器官型切片接受θ波爆发诱导的长时程增强时,脊柱动力学同样受到糖原代谢抑制的影响,并由l-乳酸恢复。这些结果表明,学习启动星形细胞能量储存和信号传导,通过l-乳酸维持突触可塑性。
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