AMPA receptor: Difference between revisions
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AMPA receptors are [[Ligand-gated ion channel|Ligand gated ion channels]].The ligand (signalling molecule) they are complementary to is a[[Glutamate|Glutamate]] which is the main excitatory [[Neurotransmitter|neurotransmitter]] in the [[Central nervous system|CNS]], this means there is a high proportion of these AMPA receptors on postsynaptic neurons in the brain. | AMPA receptors are [[Ligand-gated ion channel|Ligand gated ion channels]].The ligand (signalling molecule) they are complementary to is a [[Glutamate|Glutamate]] which is the main excitatory [[Neurotransmitter|neurotransmitter]] in the [[Central nervous system|CNS]], this means there is a high proportion of these AMPA receptors on postsynaptic neurons in the brain. | ||
When Glutamate binds to AMPA receptors it causes a conformational change and the ion channel opens allowing Na<sup>+</sup> ions to flood into the postsynaptic cell. The increase in Na<sup>+</sup> concentration causes depolarisation of the postsynaptic membrane generating an [[EPSP|EPSP]] ( which if strong enough can go on to initiate an [[Action potential|action potential]] at the axon hillock). Repetitive stimulation of these synapses in the brain can cause LTP [[Long term potentiation|(Long-term potentiation]]) , due to more Glutamate being released across the synaptic cleft binding to more AMPA receptors which leads to a higher influx of Na<sup>+</sup> ions into the cell generating a stronger EPSP. This strong depolarisation of the post-synaptic member aids to the activation of [[NMDA receptor|NMDA receptors]] (along with glutamate binding) which allow Ca<sup>2+</sup> ions to enter the post synaptic cell. This increase in Ca<sup>2+</sup> concentration can cause new AMPA receptors to be inserted in to the post-synaptic membrane increasing the sensitivity of the post-synaptic cell to Glutamate <ref>Bruce Alberts, e. a., 2008. Molecular Biology of the cell. 5th ed (pg 690). New York: Garland Science.</ref>.<br> | When Glutamate binds to AMPA receptors it causes a conformational change and the ion channel opens allowing Na<sup>+</sup> ions to flood into the postsynaptic cell. The increase in Na<sup>+</sup> concentration causes depolarisation of the postsynaptic membrane generating an [[EPSP|EPSP]] ( which if strong enough can go on to initiate an [[Action potential|action potential]] at the axon hillock). Repetitive stimulation of these synapses in the brain can cause LTP [[Long term potentiation|(Long-term potentiation]]) , due to more Glutamate being released across the synaptic cleft binding to more AMPA receptors which leads to a higher influx of Na<sup>+</sup> ions into the cell generating a stronger EPSP. This strong [[Depolarisation|depolarisation]] of the post-synaptic member aids to the activation of [[NMDA receptor|NMDA receptors]] (along with glutamate binding) which allow Ca<sup>2+</sup> ions to enter the post synaptic cell. This increase in Ca<sup>2+</sup> concentration can cause new AMPA receptors to be inserted in to the post-synaptic membrane increasing the sensitivity of the post-synaptic cell to Glutamate <ref>Bruce Alberts, e. a., 2008. Molecular Biology of the cell. 5th ed (pg 690). New York: Garland Science.</ref>.<br> | ||
=== References === | === References === | ||
<references /> | <references /> | ||
Latest revision as of 12:59, 20 October 2015
AMPA receptors are Ligand gated ion channels.The ligand (signalling molecule) they are complementary to is a Glutamate which is the main excitatory neurotransmitter in the CNS, this means there is a high proportion of these AMPA receptors on postsynaptic neurons in the brain.
When Glutamate binds to AMPA receptors it causes a conformational change and the ion channel opens allowing Na+ ions to flood into the postsynaptic cell. The increase in Na+ concentration causes depolarisation of the postsynaptic membrane generating an EPSP ( which if strong enough can go on to initiate an action potential at the axon hillock). Repetitive stimulation of these synapses in the brain can cause LTP (Long-term potentiation) , due to more Glutamate being released across the synaptic cleft binding to more AMPA receptors which leads to a higher influx of Na+ ions into the cell generating a stronger EPSP. This strong depolarisation of the post-synaptic member aids to the activation of NMDA receptors (along with glutamate binding) which allow Ca2+ ions to enter the post synaptic cell. This increase in Ca2+ concentration can cause new AMPA receptors to be inserted in to the post-synaptic membrane increasing the sensitivity of the post-synaptic cell to Glutamate [1].
References
- ↑ Bruce Alberts, e. a., 2008. Molecular Biology of the cell. 5th ed (pg 690). New York: Garland Science.