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Active zone stability:insights from fly neuromuscular junction

Active zone stability:insights from fly neuromuscular junction
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摘要 The presynaptic active zone is a dynamic structure that orchestrates regulated release of neurotrans- mitters. Developmental and aging processes, and changes in neuronal network activity can all modulate the number, size and composition of active zone and thereby synaptic efficacy. However, very little is known about the mechanism that controls the structural stability of active zone. By study- ing a model synapse, the Drosophila neuromuscular iunction, our recent work shed light on how two scaffolding proteins at the active zone regulate active zone stability by promoting a localized dephos- phorylation event at the nerve terminal. Here we discuss the major insights from our findings and their implications for future research. The presynaptic active zone is a dynamic structure that orchestrates regulated release of neurotrans- mitters. Developmental and aging processes, and changes in neuronal network activity can all modulate the number, size and composition of active zone and thereby synaptic efficacy. However, very little is known about the mechanism that controls the structural stability of active zone. By study- ing a model synapse, the Drosophila neuromuscular iunction, our recent work shed light on how two scaffolding proteins at the active zone regulate active zone stability by promoting a localized dephos- phorylation event at the nerve terminal. Here we discuss the major insights from our findings and their implications for future research.
作者 Xiaolin Tian Chunlai Wu
机构地区 Neuroscience Center of Excellence
出处 《Neural Regeneration Research》 SCIE CAS CSCD 2015年第5期677-678,共2页 中国神经再生研究(英文版)
关键词 active zone stability DROSOPHILA neuromuscular junction DEPHOSPHORYLATION Liprin-α Syd-1 PP2A GSK-3β active zone stability Drosophila neuromuscular junction dephosphorylation Liprin-α Syd-1 PP2A GSK-3β
分类号 Q42 [生物学—神经生物学]
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Neural Regeneration Research
2015年 第5期

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