核周室控制海马神经元轴突生长的钙调磷酸酶/MEF2信号。

IF 3.5 3区医学 Q2 NEUROSCIENCES

Frontiers in Molecular Neuroscience Pub Date : 2024-11-25 eCollection Date: 2024-01-01 DOI:10.3389/fnmol.2024.1494160

Joanna Mackiewicz, Malwina Lisek, Julia Tomczak, Agata Sakowicz, Feng Guo, Tomasz Boczek

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引用次数: 0

摘要

轴突伸长过程的核心是区隔化信号传导的概念，它涉及不同亚细胞结构域内a激酶锚定蛋白（AKAP）依赖的信号通路组织。这种空间组织对于将电活动转化为生化事件也至关重要。尽管进行了深入的研究，但信号通路的空间分离控制轴突生长和寻路的详细机制仍未解决。在这项研究中，我们证明了位于海马初级神经元核周间隙的mAKAPα (AKAP6)为钙调磷酸酶、NFAT和MEF2转录因子的活性依赖性轴突伸长提供了支架。通过使用锚定干扰物，我们发现mAKAPα/ calcalineurin /MEF2信号通路驱动轴突生长过程，而不是NFAT。此外，makap α控制的轴突伸长与Ca2+/cAMP信号相关基因的表达变化有关。这些发现揭示了轴突生长的一种新的调控机制，可以靶向治疗神经保护和再生。

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Perinuclear compartment controls calcineurin/MEF2 signaling for axonal outgrowth of hippocampal neurons.

Central to the process of axon elongation is the concept of compartmentalized signaling, which involves the A-kinase anchoring protein (AKAP)-dependent organization of signaling pathways within distinct subcellular domains. This spatial organization is also critical for translating electrical activity into biochemical events. Despite intensive research, the detailed mechanisms by which the spatial separation of signaling pathways governs axonal outgrowth and pathfinding remain unresolved. In this study, we demonstrate that mAKAPα (AKAP6), located in the perinuclear space of primary hippocampal neurons, scaffolds calcineurin, NFAT, and MEF2 transcription factors for activity-dependent axon elongation. By employing anchoring disruptors, we show that the mAKAPα/calcineurin/MEF2 signaling pathway, but not NFAT, drives the process of axonal outgrowth. Furthermore, mAKAPα-controlled axonal elongation is linked to the changes in the expression of genes involved in Ca²⁺/cAMP signaling. These findings reveal a novel regulatory mechanism of axon growth that could be targeted therapeutically for neuroprotection and regeneration.

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来源期刊

Frontiers in Molecular Neuroscience NEUROSCIENCES-

CiteScore

5.70

自引率

2.10%

发文量

669

审稿时长

14 weeks

期刊介绍： Frontiers in Molecular Neuroscience is a first-tier electronic journal devoted to identifying key molecules, as well as their functions and interactions, that underlie the structure, design and function of the brain across all levels. The scope of our journal encompasses synaptic and cellular proteins, coding and non-coding RNA, and molecular mechanisms regulating cellular and dendritic RNA translation. In recent years, a plethora of new cellular and synaptic players have been identified from reduced systems, such as neuronal cultures, but the relevance of these molecules in terms of cellular and synaptic function and plasticity in the living brain and its circuits has not been validated. The effects of spine growth and density observed using gene products identified from in vitro work are frequently not reproduced in vivo. Our journal is particularly interested in studies on genetically engineered model organisms (C. elegans, Drosophila, mouse), in which alterations in key molecules underlying cellular and synaptic function and plasticity produce defined anatomical, physiological and behavioral changes. In the mouse, genetic alterations limited to particular neural circuits (olfactory bulb, motor cortex, cortical layers, hippocampal subfields, cerebellum), preferably regulated in time and on demand, are of special interest, as they sidestep potential compensatory developmental effects.