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An Introduction to Neurotransmission William Wisden Dept of Clinical Neurobiology INF 364 William.Wisden@urz.uni-heidelberg.de
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Fundamental Neuroscience - second edition Squire, Bloom, McConnell, Roberts, Spitzer, Zigmond Academic Press, 2003 http://faculty.washington.edu/chudler/neurok.html http://faculty.washington.edu/chudler/chnt1.html Explore the Brain and Spinal Cord The Neuron http://www.indstate.edu/thcme/mwking/home.html http://www.indstate.edu/thcme/mwking/nerves.html
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A neuron
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The action potential
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Hodgkin & Huxley, 1939
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Rate of action potential firing is information
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The dendrite
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Differences between axons and dendrites AxonsDendrites Take information away from the cell body Bring information to the cell body Smooth Surface Rough Surface (dendritic spines) Generally only 1 axon per cell Usually many dendrites per cell No ribosomes Have ribosomes Can have myelin No myelin insulation Branch further from the cell bodyBranch near the cell body
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Dendrites constitute a kind of neural microchip for complex computations
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Rate of action potential firing is information Frequency code of impulses within the axons Place/topological code depending on which axons are active
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Chemical synapse Axon-dendriteAxo-axonicAxon-soma
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Passing information between neurons Gap junctions -electrical transmission fast both directions Chemical transmission slower - unidirectional integrative amplifies and regenerates the signal
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The synapse
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IN OUT Calcium entry is excitatory Calcium is a second messenger which binds to target proteins e.g. Calmodulin
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Axon Terminal Spine Dendrite Action potential Ca2+ Diffusion of Neurotransmitters Across the Synaptic Cleft Neurotransmitter Mobilization and Release Electrical Trigger for Neurotransmission
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Ca2+ Action potential Depolarization
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Electrical properties
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How is the action potential generated? http://faculty.washington.edu/chudler/ap.html
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EXCITATORY + INHIBITORY - IN OUT
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Look at the animation! http://faculty.washington.edu/chudler/ap.html
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Neurotransmitters
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Excitatory Inhibitory Excitatory
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Simple transmitters: -aminobutyric acid (GABA) glutamic acid (glutamate) acetylcholine (Ach)
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OUT IN Acetylcholine receptor Cl - GABA A receptor GABAGABA Inhibition Na + Glutamate/AMPA receptor G lu Excitation Na + AChACh
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Neurons and glial cells
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The process of chemical neurotransmission can be divided into five steps 1. Synthesis of the neurotransmitter in the presynaptic neuron 2. Storage of the neurotransmitter and/or its precursor in the presynaptic nerve terminal 3. Release of the neurotransmitter into the synaptic cleft 4. Binding and recognition of the neurotransmitter by target receptors 5. Termination of the action of the released transmitter
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Life cycle of a neurotransmitter
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An excitatory (glutamatergic) synapse
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A synapse using -aminobutyric acid (GABA)
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A synapse that uses acetylcholine (ACh)
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Simple circuits
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Feed-forward inhibition
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Negative feedback Feedback inhibition
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Neocortex Interneuron - uses GABA Pyramidal neuron - uses glutamate
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Ionotropic and metabotropic receptors Fast Ion flow in/out milliseconds Slow Second messenger cascades seconds
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Ionotropic Metabotropic
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OUT IN Cl - Na + GABA A receptorGlutamate/AMPA receptor GABAGABA G lu Inhibition Excitation
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Neuromodulators Slow synaptic transmission
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