Presentation is loading. Please wait.

Presentation is loading. Please wait.

Neural Mechanisms of Learning & Memory Lesson 24.

Published byEllen McKenzie Modified over 8 years ago

Similar presentations

Presentation on theme: "Neural Mechanisms of Learning & Memory Lesson 24."— Presentation transcript:

1 Neural Mechanisms of Learning & Memory Lesson 24

2 Neural Mechanism of Memory n Short-term Memory l Change in neural activity l Reverberatory Circuits n Long-Term Memory l structural change in brain l Hebb Synapse l simultaneous activity in pre- & postsynaptic neurons ~

3 Neural Plasticity n Nervous System is malleable l learning occurs l Structural changes at synapses n Changes in synaptic efficiency l Long-term potentiation (LTP) l Long-term depression (LTD) n Studied in hippocampus l and other places ~

4 Inducing LTP Stimulating electrode Record Presynaptic Neuron Postynaptic Neuron

5 -70mv - + Postsynaptic Potential Single elec. stimulation 100 Hz. burst Single stim.

6 LTP Duration n In humans: years n Experimentally-induced LTP l Strong, high frequency stimulation l 100 Hz n Intact animals l seconds - months n HC slice l 40 hrs ~

7 LTP: Molecular Mechanisms n Presynaptic & Postsynaptic changes n HC: Glutamate l excitatory n 2 postsynaptic receptor subtypes l AMPA-R  Na+ l NMDA-R  Ca++ n Glu NT for both ~

8 NMDA Receptor n N-methyl-D-aspartate l chemically-gated l voltage-gated n Activation requires l Membrane depolarization and l Glu bound to receptor~

9 Single Action Potential n Glu  AMPA-R l Na+ influx l depolarization n Glu  NMDA-R l does not open l Mg++ blocks channel l no Ca++ into postsynaptic cell n Followed by more APs ~

10 Activation of NMDA-R n Postsynaptic membrane depolarized l Mg++ dislodged l Glu binding opens channel n Ca++ influx  post-synaptic changes l strengthens synapse ~

11 AMPA NMDA Mg G Ca++ Na+ G G

12 NMDA Mg G Ca++ G AMPA Na+ G

13 NMDA Mg GG Ca++ AMPA Na+ G

14 NMDA G Ca++ G Mg AMPA Na+ G

15 LTP: Postsynaptic Changes n Receptor synthesis n More synapses n Shape of dendritic spines n Nitric Oxide synthesis ~

16 Presynaptic Axon Terminal Dendritic Spine Before LTP

17 Presynaptic Axon Terminal Dendritic Spine After LTP less Fodrin Less resistance

18 Nitric Oxide - NO n Retrograde messenger l Hi conc.  poisonous gas n Hi lipid solubility l storage? n Synthesis on demand l Ca++  NO synthase  NO n Increases NT synthesis in presynaptic neuron l more released during AP ~

19 G Ca++ G NOSNO Glu G

20 Long-term Depression: Hippocampus n Decreased synaptic efficiency l Forgetting? n Glutamamte-R l AMPA-R & NMDA-R n Stimulation pattern? l 1 Hz for 10-15 min l Low Ca++ influx n Decrease # of AMPA-R l Weaker EPSPs ~

21 Hippocampus: LTP vs LTD n Same receptors l Different stimulation frequency l Different Ca++ concentrations n LTD can reverse LTP n LTP can reverse LTD n Similar mechanisms in other areas l Not necessarily identical ~

Download ppt "Neural Mechanisms of Learning & Memory Lesson 24."

Similar presentations

Neural Signaling: Postsynaptic Potentials Lesson 9.

Neural Signaling: Postsynaptic Potentials Lesson 9.
Molecular Mechanisms of Learning and Memory

Molecular Mechanisms of Learning and Memory
Announcements Mid term room assignments posted to webpage A – HoS361 (Pavilion) Hoang – LischkaS309 Lishingham - NguiS143 Nguyen – SeguinS128 Sek – Zia.

Announcements Mid term room assignments posted to webpage A – HoS361 (Pavilion) Hoang – LischkaS309 Lishingham - NguiS143 Nguyen – SeguinS128 Sek – Zia.
Long-term Potentiation as a Physiological Phenomenon

Long-term Potentiation as a Physiological Phenomenon
Nervous System FUNCTION: Senses, processes, interprets, and determines the response to stimuli from the environment Central Nervous System (CNS) - made.

Nervous System FUNCTION: Senses, processes, interprets, and determines the response to stimuli from the environment Central Nervous System (CNS) - made.
LECTURE 9: INTEGRATION OF SYNAPTIC INPUTS (Ionotropic Receptors) REQUIRED READING: Kandel text, Chapter 12 At neuromuscular synapse, single axonal action.

LECTURE 9: INTEGRATION OF SYNAPTIC INPUTS (Ionotropic Receptors) REQUIRED READING: Kandel text, Chapter 12 At neuromuscular synapse, single axonal action.
Spike Timing-Dependent Plasticity Presented by: Arash Ashari Slides mostly from: www.mbi.osu.edu 1  Woodin MA, Ganguly K, and Poo MM. Coincident pre-

Spike Timing-Dependent Plasticity Presented by: Arash Ashari Slides mostly from: 1  Woodin MA, Ganguly K, and Poo MM. Coincident pre-
Spike timing dependent plasticity Homeostatic regulation of synaptic plasticity.

Spike timing dependent plasticity Homeostatic regulation of synaptic plasticity.
Synaptic Plasticity.

Synaptic Plasticity.
Figure 8.1 Forms of short-term synaptic plasticity.

Figure 8.1 Forms of short-term synaptic plasticity.
Part Fundamentals of Physiology Part II Food, Energy, and Temperature Part III Integrating systems Part IV Movement and Muscle Part V Oxygen, Carbon dioxide,

Part Fundamentals of Physiology Part II Food, Energy, and Temperature Part III Integrating systems Part IV Movement and Muscle Part V Oxygen, Carbon dioxide,
Neural Mechanisms of Memory Storage Molecular, synaptic, and cellular events store information in the nervous system. New learning and memory formation.

Neural Mechanisms of Memory Storage Molecular, synaptic, and cellular events store information in the nervous system. New learning and memory formation.
Before we start: What is the question? Why is it interesting?

Before we start: What is the question? Why is it interesting?
Synapses are everywhere 10 11 neurons 10 14 synapses Synapse change continuously –From msec –To hours (memory) Lack HH type model for the synapse.

Synapses are everywhere neurons synapses Synapse change continuously –From msec –To hours (memory) Lack HH type model for the synapse.
Long term potentiation (LTP) of an excitatory synaptic inputs is input specific.

Long term potentiation (LTP) of an excitatory synaptic inputs is input specific.
J. Kauer, R. Malenka, and R. Nicoll

J. Kauer, R. Malenka, and R. Nicoll
Neural communication How do neurons send messages to each other?

Neural communication How do neurons send messages to each other?
F model system: sea hare ( Aplysia californica ) F behavior: the gill & siphon withdrawal reflex F even more cell biology: learning & memory F summary.

F model system: sea hare ( Aplysia californica ) F behavior: the gill & siphon withdrawal reflex F even more cell biology: learning & memory F summary.
DAVID SANTUCCI QUANTITATIVE BIOLOGY BOOTCAMP 2009 A BRIEF HISTORY OF THE SYNAPSE.

DAVID SANTUCCI QUANTITATIVE BIOLOGY BOOTCAMP 2009 A BRIEF HISTORY OF THE SYNAPSE.
Bi/CNS 150 Lecture 20 Friday November 15, 2014 Learning & Memory 1. Synaptic plasticity Bruce Cohen Kandel,Chap. 12: pp. 281-295, Chap. 67 1.

Bi/CNS 150 Lecture 20 Friday November 15, 2014 Learning & Memory 1. Synaptic plasticity Bruce Cohen Kandel,Chap. 12: pp , Chap

Similar presentations

Ads by Google