结构型长时程增强:从突触发生到受调控的突触增大和聚集。
Structural LTP: from synaptogenesis to regulated synapse enlargement and clustering.
机构信息
University of Texas at Austin, United States.
出版信息
Curr Opin Neurobiol. 2020 Aug;63:189-197. doi: 10.1016/j.conb.2020.04.009. Epub 2020 Jul 10.
Abstract
Nature teaches us that form precedes function, yet structure and function are intertwined. Such is the case with synapse structure, function, and plasticity underlying learning, especially in the hippocampus, a crucial brain region for memory formation. As the hippocampus matures, enduring changes in synapse structure produced by long-term potentiation (LTP) shift from synaptogenesis to synapse enlargement that is homeostatically balanced by stalled spine outgrowth and local spine clustering. Production of LTP leads to silent spine outgrowth at P15, and silent synapse enlargement in adult hippocampus at 2hours, but not at 5 or 30min following induction. Here we consider structural LTP in the context of developmental stage and variation in the availability of local resources of endosomes, smooth endoplasmic reticulum and polyribosomes. The emerging evidence supports a need for more nuanced analysis of synaptic plasticity in the context of subcellular resource availability and developmental stage.
摘要
自然告诉我们,形式先于功能,然而结构和功能是相互交织的。突触结构、功能和可塑性在学习中就是如此,特别是在海马体中,海马体是记忆形成的关键脑区。随着海马体的成熟,由长时程增强(LTP)产生的突触结构的持久变化从突触发生转变为突触扩大,这是通过停滞的棘突生长和局部棘突聚集来平衡的。LTP 的产生导致 P15 时沉默的棘突生长,以及成年海马体中 2 小时时沉默的突触扩大,但在诱导后 5 或 30 分钟时则没有。在这里,我们考虑了结构 LTP 在发育阶段和内体、光滑内质网和多核糖体等局部资源可用性方面的差异。新出现的证据支持在亚细胞资源可用性和发育阶段的背景下,更细致地分析突触可塑性的必要性。
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