Abstract
Actin cytoskeletal remodeling plays a critical role in transforming the morphology of subcellular structures across various cell types. In the brain, restructuring of dendritic spines through actin cytoskeleletal reorganization is implicated in the regulation of synaptic efficacy and the storage of information in neural circuits. However, the upstream pathways that provoke actin-based spine changes remain only partly understood. Here we show that EphA receptor signaling remodels spines by triggering a sequence of events involving actin filament rearrangement and synapse/spine reorganization. Rapid EphA signaling over minutes activates the actin filament depolymerizing/severing factor cofilin, alters F-actin distribution in spines, and causes transient spine elongation through the phosphatases slingshot 1 (SSH1) and calcineurin/protein phosphatase 2B (PP2B). This early phase of spine extension is followed by synaptic reorganization events that take place over minutes to hours and involve the relocation of pre/postsynaptic components and ultimately spine retraction. Thus, EphA receptors utilize discrete cellular and molecular pathways to promote actin-based structural plasticity of excitatory synapses.
Highlights
The actin cytoskeleton regulates the structure of synapses formed on dendritic spines in the brain
We found that EphA signaling elicits rapid activation of the actin filament depolymerizing/severing factor cofilin [22] through the phosphatase slingshot 1 (SSH1) [42] and the upstream activator calcineurin/phosphatase 2B (PP2B) [43]
EphA Signaling Causes F-actin Reorganization in Spines—To study how early EphA-induced spine remodeling is related to the reorganization of the F-actin network and postsynaptic structure in spines, we investigated the distribution of F-actin in dissociated neurons following ephrin-A treatment and manipulations that block SSH1 and calcineurin function
Summary
The actin cytoskeleton regulates the structure of synapses formed on dendritic spines in the brain. Rapid EphA signaling over minutes activates the actin filament depolymerizing/severing factor cofilin, alters F-actin distribution in spines, and causes transient spine elongation through the phosphatases slingshot 1 (SSH1) and calcineurin/protein phosphatase 2B (PP2B). This early phase of spine extension is followed by synaptic reorganization events that take place over minutes to hours and involve the relocation of pre/postsynaptic components and spine retraction. We found that EphA signaling elicits rapid activation of the actin filament depolymerizing/severing factor cofilin [22] through the phosphatase slingshot 1 (SSH1) [42] and the upstream activator calcineurin/PP2B [43]. This study uncovers a novel molecular pathway utilized by EphAs to restructure excitatory synaptic connections and reveals the time course for these reorganization events
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