Abstract
Alterations in the strength of excitatory synapses in the hippocampus is believed to serve a vital function in the storage and recall of new information in the mammalian brain. These alterations involve the regulation of both functional and morphological features of dendritic spines, the principal sites of excitatory synaptic contact. New protein synthesis has been implicated extensively in the functional changes observed following long-term potentiation (LTP), and changes to spine morphology have similarly been documented extensively following synaptic potentiation. However, mechanistic links between de novo translation and the structural changes of potentiated spines are less clear. Here, we assess explicitly the potential contribution of new protein translation under control of the mechanistic target of rapamycin (mTOR) to LTP-associated changes in spine morphology. Utilizing genetic and pharmacological manipulations of mTORC1 function in combination with confocal microscopy in live dissociated hippocampal cultures, we demonstrate that chemically-induced LTP (cLTP) requires do novo protein synthesis and intact mTORC1 signaling. We observed a striking diversity in response properties across morphological classes, with mushroom spines displaying a particular sensitivity to altered mTORC1 signaling across varied levels of synaptic activity. Notably, while pharmacological inhibition of mTORC1 signaling significantly diminished glycine-induced changes in spine morphology, transient genetic upregulation of mTORC1 signaling was insufficient to produce spine enlargements on its own. In contrast, genetic upregulation of mTORC1 signaling promoted rapid expansion in spine head diameter when combined with otherwise sub-threshold synaptic stimulation. These results suggest that synaptic activity-derived signaling pathways act in combination with mTORC1-dependent translational control mechanisms to ultimately regulate changes in spine morphology. As several monogenic neurodevelopmental disorders with links to Autism and Intellectual Disability share a common feature of dysregulated mTORC1 signaling, further understanding of the role of this signaling pathway in regulating synapse function and morphology will be essential in the development of novel therapeutic interventions.
Highlights
Dendritic spines comprise the primary sites of excitatory synaptic contact in the mammalian central nervous system
(See figure on previous page.) Fig. 1 Long lasting changes in dendritic spine morphology induced by chemically-induced LTP (cLTP) in vitro. (a-d) Example traces and mean (+SEM) mEPSC amplitude (b), frequency (c), and decay time (d) for cultured rat hippocampal neurons recorded after treatment with glycine-based cLTP (400 μM) stimulus or HEPES-buffered saline (HBS) alone as a control (n = 7 recordings in each condition)
We show that cLTP induction caused an expansion in dendritic spine heads in cultured hippocampal neurons (Fig. 1), a specific form of structural plasticity that is widely believed to be necessary for persistent strengthening of excitatory synaptic connections
Summary
Dendritic spines comprise the primary sites of excitatory synaptic contact in the mammalian central nervous system. At mature synapses, these actin-rich protrusions are typically composed of a large head compartment. Cytoskeletal rearrangement is necessary for the expression of long lasting plasticity at excitatory synapses, as inhibitors of actin polymerization impair LTP in the CA1 region of the hippocampus [25, 26]. An emerging model of the signaling dynamics involved in spine enlargement during LTP suggests that calcium influx through NMDARs activates CaMKIIα, leading to the subsequent recruitment of multiple RhoGTPases, wherein RhoA is critical for the initial enlargement of spine size and Cdc is necessary for sustaining these structural changes over time [29, 39, 40]
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