Silent synapse

In neuroscience, a silent synapse is an excitatory glutamatergic synapse whose postsynaptic membrane contains NMDA-type glutamate receptors but no AMPA-type glutamate receptors. These synapses are named 'silent' because normal AMPA receptor-mediated signaling is not present, rendering the synapse inactive under typical conditions. Silent synapses are typically considered to be immature glutamatergic synapses. As the brain matures, the relative number of silent synapses decreases. However, recent research on hippocampal silent synapses shows that while they may indeed be a developmental landmark in the formation of a synapse, that synapses can be 'silenced' by activity, even once they have acquired AMPA receptors. Thus, silence may be a state that synapses can visit many times during their lifetimes. In neuroscience, a silent synapse is an excitatory glutamatergic synapse whose postsynaptic membrane contains NMDA-type glutamate receptors but no AMPA-type glutamate receptors. These synapses are named 'silent' because normal AMPA receptor-mediated signaling is not present, rendering the synapse inactive under typical conditions. Silent synapses are typically considered to be immature glutamatergic synapses. As the brain matures, the relative number of silent synapses decreases. However, recent research on hippocampal silent synapses shows that while they may indeed be a developmental landmark in the formation of a synapse, that synapses can be 'silenced' by activity, even once they have acquired AMPA receptors. Thus, silence may be a state that synapses can visit many times during their lifetimes. Normal transmission across a glutamatergic synapse relies on the neurotransmitter glutamate, the glutamate-specific AMPA receptor (AMPAR), and calcium ions. Calcium ion entry into the presynaptic terminal causes the presynaptic release of glutamate, which diffuses across the synaptic cleft, binding to glutamate receptors on the postsynaptic membrane. There are four subtypes of glutamate receptors: AMPA receptors (AMPARs) (formerly known as quisqualate receptors), NMDA receptors (NMDARs), kainate receptors, and metabotropic glutamate receptors (mGluRs). Most research has been focused on the AMPARs and the NMDARs. When glutamate binds to AMPARs located on the postsynaptic membrane, they permit a mixed flow of Na+ and K+ to cross the cells membrane, causing a depolarization of the postsynaptic membrane. This localized depolarization is called an excitatory postsynaptic potential (EPSP). Silent synapses release glutamate as do prototypical glutamatergic synapses, but their postsynaptic membranes contain only NMDA—and possibly mGlu—receptors able to bind glutamate. Though AMPA receptors are not expressed in the postsynaptic membranes of silent synapses, they are stored in vesicles inside the postsynaptic cells, where they cannot detect extracellular glutamate, but can be quickly inserted into the postsynaptic cell membrane in response to a tetanizing stimulus. The NMDAR is functionally similar to AMPAR except for two major differences: NMDARs carry ion currents composed of Na+, K+, but also (unlike most AMPAR) Ca2+; NMDARs also have a site inside their ion channel that binds magnesium ions (Mg2+). This magnesium binding site is located in the pore of the channel, at a place within the electrical field generated by the membrane potential. Normally, current will not flow through the NMDAR channel, even when it has bound glutamate. This is because the ion channel associated with this receptor is plugged by magnesium, acting like a cork in a bottle. However, since the Mg2+ is charged and is bound within the membrane's electric field, depolarization of the membrane potential above threshold can dislodge the magnesium, allowing current flow through the NMDAR channel. This gives the NMDAR the property of being voltage-dependent, in that it requires strong postsynaptic depolarization to allow ion flux. Silent synapses were proposed as an explanation for differences in quantal content of excitatory postsynaptic currents (EPSCs) mediated by AMPARs and NMDARs in hippocampal neurons. More direct evidence came from experiments where only a few axons were stimulated. The stimulation of a silent synapse does not elicit EPSCs when the postsynaptic cell is clamped at -60 mV. Stimulation of a silent synapse will elicit EPSCs when the postsynaptic cell is depolarized beyond -40 mV. This is because they lack surface AMPAR to pass current at hyperpolarized potentials, but do possess NMDARs that will pass current at more positive potentials (because of relief of magnesium block). Moreover, the EPSCs elicited with depolarized membrane potentials can be completely blocked by D-APV, a selective NMDAR blocker. Silent synapses are activated via the insertion of AMPARs into the postsynaptic membrane, a phenomenon commonly called 'AMPA receptor trafficking.' When glutamate binds to a strongly-depolarized postsynaptic cell (e.g., during Hebbian LTP), Ca2+ quickly enters and binds to calmodulin. Calmodulin activates calcium/calmodulin-dependent protein kinase II (CaMKII), which — among other things — acts on AMPAR-containing vesicles near the postsynaptic membrane. CaMKII phosphorylates these AMPARs, which serves as a signal to insert them into the postsynaptic membrane. Once AMPARs are inserted, the synapse is no longer silent; activated synapses no longer require simultaneous pre- and postsynaptic activity in order to elicit EPSPs.