What happens when action potential reaches axon terminal

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What happens when action potential reaches axon terminal? Forms a synapse with another neuron

What happens when action potential reaches axon terminal? Forms a synapse with another neuron or muscle Two types: Electrical and Chemical

Chemical Synapse

Chemical Synapse

Action potential Synaptic vesicle active uptake Ca 2+ voltagegated Ca channel Ca 2+ docking

Action potential Synaptic vesicle active uptake Ca 2+ voltagegated Ca channel Ca 2+ docking protein Postsynaptic cell K+ Na+ 1. action potential arrives at terminal 2. voltage-gated Ca channels open 3. Ca triggers exocytosis of vesicles 4. neurotransmitter is released, binds to receptor 5. ligand-gated Na or K channels open 6. neurotransmitter broken down, taken up 7. synaptic vesicles reconstituted 8. neurotransmitter stored, awaits next impulse

Neuromuscular Junction acetylcholine botulinum toxin X X acetylcholinesterase nicotine (agonist) curare (antagonist) Nicotinic cholinergic

Neuromuscular Junction acetylcholine botulinum toxin X X acetylcholinesterase nicotine (agonist) curare (antagonist) Nicotinic cholinergic synapse

Muscarinic cholinergic synapse acetylcholine X muscarine (agonist) atropine (antagonist)

Muscarinic cholinergic synapse acetylcholine X muscarine (agonist) atropine (antagonist)

Post-Synaptic Events Graded vs Action Potentials Excitatory vs. Inhibitory PSPs Pre- vs. Post-Synaptic Inhibition

Post-Synaptic Events Graded vs Action Potentials Excitatory vs. Inhibitory PSPs Pre- vs. Post-Synaptic Inhibition Divergence vs. Convergence

Receptor binding results in opening of agonist-gated K and Cl channels e. g. muscarinic

Receptor binding results in opening of agonist-gated K and Cl channels e. g. muscarinic acetylcholine receptor of heart

Receptor binding results in opening of agonist-gated Na channel e. g. nicotinic acetylcholine receptor

Receptor binding results in opening of agonist-gated Na channel e. g. nicotinic acetylcholine receptor of neuromuscular junction

One synapse is generally not sufficient to generate a threshold stimulus at the axonal

One synapse is generally not sufficient to generate a threshold stimulus at the axonal hillock. Most neurons receive thousands of synaptic endings each of which contributes a postsynaptic potential (EPSP or IPSP) of less than 1 m. V. Each of these PSPs are conducted to the axonal hillock with decrement (decay). An action potential will only be generated if the sum of the IPSPs and EPSPs reaching the axonal hillock at any time exceed the threshold voltage.

Dendrite of postsynaptic neuron Axon terminals of presynaptic neuron Axon Glial cell processes Dendrite

Dendrite of postsynaptic neuron Axon terminals of presynaptic neuron Axon Glial cell processes Dendrite of postsynaptic neuron

Spatial summation

Spatial summation

excitatory inhibitory A D E B C electrode threshold A A+B+C D D+E A+B+C+E

excitatory inhibitory A D E B C electrode threshold A A+B+C D D+E A+B+C+E

Postsynaptic Inhibition

Postsynaptic Inhibition

Presynaptic Inhibition

Presynaptic Inhibition

Divergent circuit Allows for amplification of a signal:

Divergent circuit Allows for amplification of a signal:

single pyramidal cell in the motor cortex of the brain 15 -20 internuncial cells

single pyramidal cell in the motor cortex of the brain 15 -20 internuncial cells in CNS each stimulates several hundred motoneurons each of these stimulates 100 -300 muscle fibers Divergence results in 50, 000 -fold amplification

Convergent circuit Important for summing, correlating and sorting information in the CNS

Convergent circuit Important for summing, correlating and sorting information in the CNS