Ion channels, receptors and intracellular signalling

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acee

Cards (28)

Ion channels are protein complexes that span the entire cell membrane
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Ion channels
Allow charged ions (Na+, Ca2+, K+) to pass through the cell membrane
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Ion channels
Rate of ion conductance through the cell
Direction of conductance
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Ion channel classification
Voltage sensitive
Ligand dependent
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Many drugs target ion channels and change their status (either open or closed)
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Cation channels
Allow Na+, K+ or Ca2+ to pass through
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Anion channels
Allow anions to pass through
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Voltage-sensitive ion channels
Open in response to membrane potential
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Ligand-dependent ion channels
Open status changes in response to the binding of a ligand to its receptor site
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Resting potential
1. When no nerve impulse is being transported along axon, resting potential (-70 mV) is maintained across axon membrane
2. Stimulus causes Na+ channels to open and Na+ diffuses rapidly into axon down an electrochemical gradient
3. When threshold is exceeded, causes depolarisation of axon
4. Action potential is triggered and voltage-sensitive gates of Na+ close and K+ channels open
5. K+ ions leave the axon down their concentration gradient, causing repolarisation of axon
6. Slight overshoot of the K+ ions diffusing out results in hyperpolarisation
7. Sodium-potassium pump restores original Na+ and K+ concentrations, returning to resting potential
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Sodium-potassium pump
Transports 3 Na+ out and 2 K+ in per ATP, restoring resting potential
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Voltage-gated ion channels
Membrane potential dependent on inter/extracellular ion concentrations
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Voltage-gated ion channels have a 6-helix (S1-6) structure
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Ion channel structure
α-subunit forms the channel pore, with 4 transmembrane domains
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Drugs target ion channels by binding to specific sites on the channel structure
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Receptors
Macromolecular components of the cell that drugs bind to in order to exert their effects
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Receptor agonist
Binds to a specific receptor and activates it, causing a cellular response
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Receptor antagonist
Binds to a specific receptor but does not activate it, preventing binding of agonist
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Ligand binding to receptor
Rapidly reversible due to weak interactions (H-bonds, ionic bonds, Van der Waals forces)
Can be irreversible if interaction is mediated by covalent bonds
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Synaptic transmission
1. Arrival of electrical stimulus triggers release of neurotransmitter (acetylcholine) into synaptic cleft
2. Neurotransmitter binds to receptors on postsynaptic membrane, allowing Na+ influx and depolarisation
3. Neurotransmitter is hydrolysed by enzymes and reabsorbed for recycling
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Electrical synapse
Action potential triggers release of neurotransmitter, which binds to receptors and causes fast response
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Chemical synapse
Action potential triggers release of neurotransmitter, which binds to G-protein coupled receptors and causes slow response
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Drug A binds to receptor
Activates G-protein system to stimulate or inhibit effector system (adenylate cyclase)
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Drug binds to receptor...
and activates G protein system to stimulate or inhibit effector system (adenylate cyclase)
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If adenylate cyclase is stimulated
Effector system produces second messenger cAMP
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If adenylate cyclase is inhibited
cAMP levels decrease
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Active PKA
Phosphorylates proteins
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Intracellular receptors are DNA-linked nuclear receptors that regulate gene transcription
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