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Neuroscience: Exploring the Brain, 3e

Neuroscience: Exploring the Brain, 3e. Chapter 5: Synaptic Transmission. Introduction. Synaptic Transmission Information transfer at a synapse Plays role in all the operations of the nervous system 1897: Charles Sherrington- “synapse” Cajal vs Golgi (1906) Chemical and electrical synapses

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Neuroscience: Exploring the Brain, 3e

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  1. Neuroscience: Exploring the Brain, 3e Chapter 5: Synaptic Transmission

  2. Introduction • Synaptic Transmission • Information transfer at a synapse • Plays role in all the operations of the nervous system • 1897: Charles Sherrington- “synapse” • Cajal vs Golgi (1906) • Chemical and electrical synapses • 1921- Otto Loewi • 1959- Furshpan and Potter

  3. Types of Synapses • Direction of Information Flow • In one direction: Neuron to target cell • First neuron = Presynaptic neuron • Target cell = Postsynaptic neuron

  4. Type of Synapses Golgi – Continuous synapse Cajal – Contiguous synapse

  5. Electrical Synapse • Gap junction • Channel • Connexon- formed by six connexins • Cells are said to be “electrically coupled” • Flow of ions from cytoplasm to cytoplasm

  6. INSERT FIG. 5.1 (Yes, deliberately out of order)

  7. Electrical Synapse • Very fast transmission • Postsynaptic potentials (PSPs) • Synaptic integration: Several PSPs occurring simultaneously to excite a neuron (i.e. causes AP)

  8. Chemical Synapse

  9. Chemical Synapse

  10. Types of Synapses • CNS Synapses (Examples) • Axodendritic: Axon to dendrite • Axosomatic: Axon to cell body • Axoaxonic: Axon to axon • Dendrodendritic: Dendrite to dendrite

  11. Types of Synapses • CNS Synapses (Examples) • Gray’s Type I: Asymmetrical, excitatory • Gray’s Type II: Symmetrical, inhibitory

  12. Types of Synapses • The Neuromuscular Junction (NMJ) • Studies of NMJ established principles of synaptic transmission

  13. An Actual Neuromuscular Synapse Goodsell, D. S. (2009), Neuromuscular synapse. Biochem. Mol. Biol. Educ., 37: 204–210. doi: 10.1002/bmb.20297

  14. Principles of Chemical Synaptic Transmission • Basic Steps • Neurotransmitter synthesis • Load neurotransmitter into synaptic vesicles • Depolarization  Vesicles fuse to presynaptic terminal • Neurotransmitter spills into synaptic cleft • Binds to postsynaptic receptors • Biochemical/Electrical response elicited in postsynaptic cell • Removal of neurotransmitter from synaptic cleft

  15. Synaptic Transmission at Neuromuscular Junction

  16. Principles of Chemical Synaptic Transmission • Basic Steps • Neurotransmitter synthesis • Load neurotransmitter into synaptic vesicles • Depolarization  Vesicles fuse to presynaptic terminal • Neurotransmitter spills into synaptic cleft • Binds to postsynaptic receptors • Biochemical/Electrical response elicited in postsynaptic cell • Removal of neurotransmitter from synaptic cleft

  17. Neurotransmitters • Amino acids: Small organic molecules

  18. Neurotransmitters • Amino acids: Small organic molecules • Amines: Small organic molecules

  19. Neurotransmitters • Amino acids: Small organic molecules • Amines: Small organic molecules • Peptides: Short amino acid chains (i.e. proteins) stored in and released from secretory granules

  20. Neurotransmitters • ____ ____: Small organic molecules • e.g., Glutamate, Glycine, GABA • ____ : Small organic molecules • e.g., Dopamine, Acetylcholine, Histamine • ____ : Short amino acid chains (i.e. proteins) stored in and released from secretory granules • e.g., Dynorphin, Enkephalins

  21. Neurotransmitter Synthesis and Storage Loading Neurotransmitters

  22. Dense Core Vesicles Goodsell, D. S. (2009), Neuromuscular synapse. Biochem. Mol. Biol. Educ., 37: 204–210. doi: 10.1002/bmb.20297

  23. Neurotransmitter Release Exocytosis: Process by which vesicles release their contents

  24. Mechanism of Neurotransmitter release • Process of exocytosis stimulated by release of intracellular calcium, [Ca2+]i • Proteins alter conformation - activated • Vesicle membrane incorporated into presynaptic membrane • Neurotransmitter released • Vesicle membrane recovered by endocytosis (Clathrin-mediated endocytosis: http://biochem.web.utah.edu/iwasa/projects/clathrin.html)

  25. Neurotransmitter Receptors and Post-synaptic Response - Ionotropic: Transmitter-gated ion channels

  26. Neurotransmitter Receptors and Post-synaptic Response • Metabotropic: G-protein-coupled receptor

  27. Excitatory and Inhibitory Postsynaptic Potentials • EPSP:Transient postsynaptic membrane depolarization by presynaptic release of neurotransmitter • IPSP: Transient hyperpolarization of postsynaptic membrane potential caused by presynaptic release of neurotransmitter • Reversal potential

  28. Neurotransmitter Recovery and Degradation • Diffusion: Away from the synapse • Reuptake: Neurotransmitter re-enters presynaptic axon terminal • Enzymatic destruction inside terminal cytosol or synaptic cleft • Desensitization: despite continued presence of ACh, transmitter-gated channels close

  29. Neuropharmacology • Effect of drugs on nervous system tissue • Receptor antagonists: Inhibitors of neurotransmitter receptors • Curare • Receptor agonists: Mimic actions of naturally occurring neurotransmitters • Nicotine • Defective neurotransmission: Root cause of neurological and psychiatric disorders

  30. Principles of Synaptic Integration • Process by which multiple synaptic potentials combine within one postsynaptic neuron

  31. Quantal Analysis of EPSPs • Synaptic vesicles: Elementary units of synaptic transmission. Almost fixed amount of nerotransmitter • Quantum: An indivisible unit • Miniature postsynaptic potential (“mini”) • Quantal analysis: Used to determine number of vesicles that release during neurotransmission • Neuromuscular junction: About 200 synaptic vesicles, EPSP of 40mV or more • CNS synapse: Single vesicle, EPSP of few tenths of a millivolt

  32. Synaptic Integration - EPSP Summation • Allows for neurons to perform sophisticated computations • EPSP summation: EPSPs added together to produce significant postsynaptic depolarization • Spatial: EPSP generated simultaneously in different spaces • Temporal: EPSP generated at same synapse in rapid succession

  33. Synaptic Integration - EPSP Summation

  34. The Contribution of Dendritic Properties to Synaptic Integration • Assume: Dendrite as a straight cable (~spinal motor dendrite) • Membrane depolarization falls off exponentially with increasing distance • Vx = Vo/ex/  • Dendritic length constant (): at which, 37% of Vo • In reality, dendrites are very elaborate structures that contribute to more complex integrative properties

  35. The Contribution of Dendritic Properties to Synaptic Integration Vx=Vo * e-x/λ

  36. Excitable Dendrites • Dendrites of neurons: voltage-gated sodium, calcium, and potassium channels • Can act as amplifiers (vs. passive) • Dendritic sodium channels: May carry electrical signals in opposite direction, from soma outward along dendrites (Cajal?)

  37. Inhibition • Action of synapses to take membrane potential away from action potential threshold • Exerts powerful control over neuron output

  38. IPSPs and Shunting Inhibition • Excitatory vs. inhibitory synapses: Bind different neurotransmitters, allow different ions to pass through channels

  39. IPSPs and Shunting Inhibition • Excitatory vs. inhibitory synapses: Bind different neurotransmitters, allow different ions to pass through channels • Membrane potential more negative: hyperpolarizing IPSP • ECl = -65 mV ? • Shunting Inhibition: Inhibiting current flow from soma to axon hillock

  40. Shunting Inhibition

  41. The Geometry of Excitatory and Inhibitory Synapses • Excitatory synapses • Gray’s type I morphology • Spines: Excitatory synapses • Inhibitory synapses • Gray’s type II morphology • Clustered on soma and near axon hillock

  42. Concluding Remarks • Chemical synaptic transmission • Rich diversity allows for complex behavior • Provides explanations for drug effects • Defective transmission is the basis for many neurological and psychiatric disorders • Key to understanding the neural basis of learning and memory

  43. Question of the Day How stepping on a rusty nail mayresult in muscle spasms and even eventual death? Hint: It involves synaptic transmission. In general, what molecular/cellular events happened? Are there effective treatments? Does the behavior a result of (mostly) defects in inhibitory or excitatory synapse? How do these defects affect synaptic integration?

  44. Principles of Synaptic Integration • Modulation • Synaptic transmission that modifies effectiveness of EPSPs generated by other synapses with transmitter-gated ion channels • Example: Activating NE β receptor

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