Presentation is loading. Please wait.

Presentation is loading. Please wait.

F model system: sea hare ( Aplysia californica ) F behavior: the gill & siphon withdrawal reflex F even more cell biology: learning & memory F summary.

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "F model system: sea hare ( Aplysia californica ) F behavior: the gill & siphon withdrawal reflex F even more cell biology: learning & memory F summary."— Presentation transcript:

1 F model system: sea hare ( Aplysia californica ) F behavior: the gill & siphon withdrawal reflex F even more cell biology: learning & memory F summary PART 4: BEHAVIORAL PLASTICITY #21: LEARNING & MEMORY of a SIMPLE REFLEX in APLYSIA II

2 F model system: sea hare ( Aplysia californica ) F behavior: the gill & siphon withdrawal reflex F even more cell biology: learning & memory F summary PART 4: BEHAVIORAL PLASTICITY #21: LEARNING & MEMORY of a SIMPLE REFLEX in APLYSIA II

3 F mechanistic analysis of classical conditioning F convergence of CS & US in sensory neuron F adenylyl cyclase (AC) = coincidence detector? F sensitization: F Ca ++ channels closed F Ca ++ not bound to calmodulin F calmodulin not bound to AC F some cAMP... CELL BIOLOGY OF LEARNING & MEMORY

4 F mechanistic analysis of classical conditioning F convergence of CS & US in sensory neuron F adenylyl cyclase (AC) = coincidence detector? F associative learning: F Ca ++ channels open F Ca ++ bound to calmodulin F calmodulin bound to AC F lots of cAMP... CELL BIOLOGY OF LEARNING & MEMORY

5 F mechanistic analysis of classical conditioning F postsynaptic factors F glutamate, excitatory transmitter F activates N-methyl-D-aspartate (NMDA) receptor CELL BIOLOGY OF LEARNING & MEMORY

6 F mechanistic analysis of classical conditioning F postsynaptic factors F glutamate, excitatory transmitter F activates N-methyl-D-aspartate (NMDA) receptor F no signal... F NMDA channel closed F no Ca ++ enters cell CELL BIOLOGY OF LEARNING & MEMORY

7 F mechanistic analysis of classical conditioning F postsynaptic factors F glutamate, excitatory transmitter F activates N-methyl-D-aspartate (NMDA) receptor F signal... F glutamate binds to receptor F postsynaptic membrane depolarizes F postsynaptic neuron fires F test this model? CELL BIOLOGY OF LEARNING & MEMORY

8 F mechanistic analysis of classical conditioning F postsynaptic factors F differential conditioning CELL BIOLOGY OF LEARNING & MEMORY

9 F mechanistic analysis of classical conditioning F postsynaptic factors F differential conditioning F aminophosphonovalerate (APV) block of NMDA receptor… CELL BIOLOGY OF LEARNING & MEMORY

10 F mechanistic analysis of classical conditioning F postsynaptic factors F differential conditioning F block NMDA receptor with APV during training CELL BIOLOGY OF LEARNING & MEMORY

11 F mechanistic analysis of classical conditioning F postsynaptic factors F differential conditioning F block NMDA receptor with APV during training F associative synaptic facilitation  CELL BIOLOGY OF LEARNING & MEMORY

12 F mechanistic analysis of classical conditioning F postsynaptic factors F differential conditioning F block NMDA receptor with APV during training F associative synaptic facilitation  F NMDA receptor necessary CELL BIOLOGY OF LEARNING & MEMORY

13 F mechanistic analysis of classical conditioning F postsynaptic factors F differential conditioning F same result during training if F postsynaptic neuron: F hyperpolarized F Ca ++ blocked F presynaptic neuron: F PKA blocked F Ca ++  CELL BIOLOGY OF LEARNING & MEMORY

14 F mechanistic analysis of classical conditioning F postsynaptic factors F implication that the postsynaptic neuron communicates with the presynaptic neuron F retrograde (backward) signaling F evidence (not shown) – associative facilitation mechanism in postsynaptic neuron changes signaling properties in the presynaptic neuron F neurons communicate in both directions F but... what is the signal? CELL BIOLOGY OF LEARNING & MEMORY

15 F mechanistic analysis of classical conditioning F revised model F 2 sites of CS-US coincidence F presynaptic AC CELL BIOLOGY OF LEARNING & MEMORY

16 F mechanistic analysis of classical conditioning F revised model F 2 sites of CS-US coincidence F presynaptic AC F postsynaptic NMDA receptor gated channels CELL BIOLOGY OF LEARNING & MEMORY

17 F mechanistic analysis of classical conditioning F revised model F 2 sites of CS-US coincidence F presynaptic AC F postsynaptic NMDA receptor gated channels F retrograde signal (hypothetical) CELL BIOLOGY OF LEARNING & MEMORY

18 F mechanistic analysis of long-term memory F long-term synaptic facilitation in sensory neurons F terminology: F long-term memory (LTM) behavioral measure F long-term facilitation (LTF) physiological measure CELL BIOLOGY OF LEARNING & MEMORY

19 F mechanistic analysis of long-term memory F long-term synaptic facilitation in sensory neurons F distributed sensitization training CELL BIOLOGY OF LEARNING & MEMORY

20 F mechanistic analysis of long-term memory F long-term synaptic facilitation in sensory neurons F distributed sensitization training: F siphon withdrawal  CELL BIOLOGY OF LEARNING & MEMORY

21 F mechanistic analysis of long-term memory F long-term synaptic facilitation in sensory neurons F distributed sensitization training F siphon withdrawal  F sensory EPSPs  CELL BIOLOGY OF LEARNING & MEMORY

22 F mechanistic analysis of long-term memory F long-term synaptic facilitation in sensory neurons F distributed sensitization training F siphon withdrawal  F sensory EPSPs  F S-current  (data not given) CELL BIOLOGY OF LEARNING & MEMORY

23 F mechanistic analysis of long-term memory F long-term synaptic facilitation in sensory neurons F distributed sensitization training F siphon withdrawal  F sensory EPSPs  F S-current  F serotonin-induced presynaptic transmitter release  (data not given) CELL BIOLOGY OF LEARNING & MEMORY

24 F mechanistic analysis of long-term memory F long-term synaptic facilitation in sensory neurons F distributed sensitization training F siphon withdrawal  F sensory EPSPs  F S-current  F serotonin-induced presynaptic transmitter release  (data not given) F presynaptic neuronal plasticity CELL BIOLOGY OF LEARNING & MEMORY

25 F mechanistic analysis of long-term memory F long-term synaptic facilitation in sensory neurons F distributed sensitization training F serotonin substitutes for tail shock @ sensory F cell body  LTF F terminal  STF CELL BIOLOGY OF LEARNING & MEMORY

26 F mechanistic analysis of long-term memory F long-term synaptic facilitation in sensory neurons F distributed sensitization training F serotonin substitutes for tail shock @ sensory F cell body  LTF F terminal  STF CELL BIOLOGY OF LEARNING & MEMORY

27 F mechanistic analysis of long-term memory F long-term synaptic facilitation in sensory neurons F serotonin induces F LTF F intracellular signal F protein synthesis (?) F neural plasticity (?) F STF F locally @ synapse CELL BIOLOGY OF LEARNING & MEMORY

28 F mechanistic analysis of long-term memory F long-term synaptic facilitation in sensory neurons F protein synthesis (?) F transcription F translation F transport  synapses CELL BIOLOGY OF LEARNING & MEMORY

29 F mechanistic analysis of long-term memory F long-term synaptic facilitation in sensory neurons F protein synthesis inhibited by blockers F also block LTF F during serotonin application only F not before or after... F narrow temporal window CELL BIOLOGY OF LEARNING & MEMORY

30 F mechanistic analysis of long-term memory F long-term synaptic facilitation in sensory neurons F protein synthesis inhibited by blockers F also block LTF F during serotonin application only F not before or after... F narrow temporal window F no block of STF CELL BIOLOGY OF LEARNING & MEMORY

31 F mechanistic analysis of long-term memory F long-term synaptic facilitation in sensory neurons F protein synthesis inhibited by blockers F also block LTF F during serotonin application only F not before or after... F narrow temporal window F no block of STF F... and does block LTM (behavior) F  protein synthesis necessary for LTM CELL BIOLOGY OF LEARNING & MEMORY

32 F mechanistic analysis of long-term memory F long-term sensitization / serotonin treatments  molecular changes in sensory neurons: F persistent phosphorylation of existing proteins F synthesis of new proteins F growth of sensory neurons... neural plasticity CELL BIOLOGY OF LEARNING & MEMORY

33 F mechanistic analysis of long-term memory F long-term sensitization / serotonin treatments  molecular changes in sensory neurons: F growth of sensory neurons... neural plasticity F visual examination F  axonal processes, branching, varicosities CELL BIOLOGY OF LEARNING & MEMORY

34 F mechanistic analysis of long-term memory F long-term sensitization / serotonin treatments  molecular changes in sensory neurons: F growth of sensory neurons... neural plasticity F visual examination F  axonal processes, branching, varicosities CELL BIOLOGY OF LEARNING & MEMORY

35 F mechanistic analysis of long-term memory F long-term sensitization / serotonin treatments  molecular changes in sensory neurons: F growth of sensory neurons... neural plasticity F model for synaptic restructuring / plasticity F  varicosities F  terminal active zones F opposite for habituation CELL BIOLOGY OF LEARNING & MEMORY

36 F mechanistic analysis of long-term memory F long-term sensitization / serotonin treatments  molecular changes in sensory neurons: F growth of sensory neurons... neural plasticity F model for synaptic restructuring / plasticity F  varicosities F  terminal active zones F  long-term increase in synaptic transmission F what are the molecular mechanisms? CELL BIOLOGY OF LEARNING & MEMORY

37 F mechanistic analysis of long-term memory F molecular induction of LTF in sensory neurons F cAMP pathway implicated: F cAMP injection... S-current  F PKA inhibitors... block serotonin-induced LTF F serotonin application... PKA catalytic subunit cytoplasmic  nuclear F activity of genes: F immediate early (IEG), transcription factors F late-responsive, leave nucleus CELL BIOLOGY OF LEARNING & MEMORY

38 F mechanistic analysis of long-term memory F molecular induction of LTF in sensory neurons F cAMP pathway implicated: F cAMP response elements (CREs) on DNA F CRE binding protein (CREB) F phosphorylated by PKA... CREBs  IEGs F IEGs  late-responsive genes CELL BIOLOGY OF LEARNING & MEMORY

39 F mechanistic analysis of long-term memory F molecular induction of LTF in sensory neurons F single training event  some PKA, STF F distributed training  more PKA... nucleus, LTF CELL BIOLOGY OF LEARNING & MEMORY

40 F mechanistic analysis of long-term memory F molecular induction of LTF in sensory neurons F competition studies using injected CRE sequences  block CREB binding & LTF  CELL BIOLOGY OF LEARNING & MEMORY

41 F mechanistic analysis of long-term memory F molecular induction of LTF in sensory neurons F competition studies using injected CRE sequences  block CREB binding & LTF  CELL BIOLOGY OF LEARNING & MEMORY

42 F mechanistic analysis of long-term memory F molecular induction of LTF in sensory neurons F competition studies using injected CRE sequences  block CREB binding & LTF  F enhanced CREB + 1 serotonin application  F LTF F structural enhancement F CREB essential for LTF & LTM F similar findings in Drosophila (next chapter) CELL BIOLOGY OF LEARNING & MEMORY

43 F mechanistic analysis of long-term memory F LTF molecular model F what proteins? F how do they work? F other 2 nd messenger cascades? F homology (flies, mice) CELL BIOLOGY OF LEARNING & MEMORY

44 F middle-term memory... read the section on your own CELL BIOLOGY OF LEARNING & MEMORY

45 F defensive withdrawal reflex after stimulation (CS) of F siphon, mantle, gill F shows non-associative learning properties F habituation, dishabituation, sensitization F sensitization: reflex with preceding tail shock F associative learning F reflex (CS) + paired shock (US) F differential conditioning = CS1 + + US, CS2 – F distributed training  long-term memory SUMMARY

46 F tail shock sensitization F interneuron serotonin release  sensory neuron F  K current flow (out of cell) F spike broadening F synaptic facilitation F cAMP cascade mediated F sensory neuron transmitter release SUMMARY

47 F classical conditioning F interneuron serotonin release  sensory neuron F tail shock US responses augmented by concurrent CS signal... F activity-dependent presynaptic facilitation F postsynaptic process, NMDA receptor in motor neuron SUMMARY

48 F long-term memory F dispersed training F protein synthesis-dependent F cAMP & CREB  IEGs F IEGs  late-response genes F proteins  neuron terminals F neuronal plasticity SUMMARY

Download ppt "F model system: sea hare ( Aplysia californica ) F behavior: the gill & siphon withdrawal reflex F even more cell biology: learning & memory F summary."

Similar presentations

Synaptic Cleft: Information Transfer

Synaptic Cleft: Information Transfer
Chapter 11 Cell Communication

Chapter 11 Cell Communication
Molecular Mechanisms of Learning and Memory

Molecular Mechanisms of Learning and Memory
NEUROBIOKIMIA: ASPEK BIOMOLEKULER DARI MEMORI Oleh Mohammad hanafi.

NEUROBIOKIMIA: ASPEK BIOMOLEKULER DARI MEMORI Oleh Mohammad hanafi.
Cellular Mechanisms of Learning

Cellular Mechanisms of Learning
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.
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.
PART 4: BEHAVIORAL PLASTICITY #20: LEARNING & MEMORY of a SIMPLE REFLEX in APLYSIA I F model system: sea hare ( Aplysia californica ) F behavior: the gill.

PART 4: BEHAVIORAL PLASTICITY #20: LEARNING & MEMORY of a SIMPLE REFLEX in APLYSIA I F model system: sea hare ( Aplysia californica ) F behavior: the gill.
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,
Neurobiology 2007 Micha Spira 21 March Learning and Memory The Aplysia Model STF.

Neurobiology 2007 Micha Spira 21 March Learning and Memory The Aplysia Model STF.
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.
Neural communication How do neurons send messages to each other?

Neural communication How do neurons send messages to each other?
Anatomy of a Nerve Cell POST-SYNAPTIC NEURON dendrites impulse synapse axon PRE-SYNAPTIC NEURON neurotransmitters.

Anatomy of a Nerve Cell POST-SYNAPTIC NEURON dendrites impulse synapse axon PRE-SYNAPTIC NEURON neurotransmitters.
Copyright © 2007 Wolters Kluwer Health | Lippincott Williams & Wilkins Neuroscience: Exploring the Brain, 3e Chapter 25: Molecular Mechanisms of Learning.

Copyright © 2007 Wolters Kluwer Health | Lippincott Williams & Wilkins Neuroscience: Exploring the Brain, 3e Chapter 25: Molecular Mechanisms of Learning.
Chapter 8c Neurons: Cellular and Network Properties.

Chapter 8c Neurons: Cellular and Network Properties.
University of Jordan1 Physiology of Synapses in the CNS- L2-L4 Faisal I. Mohammed, MD, PhD.

University of Jordan1 Physiology of Synapses in the CNS- L2-L4 Faisal I. Mohammed, MD, PhD.
 spatial learning  cells that code for space  synaptic plasticity in the hippocampus  experiments that are knockouts  summary PART 4: BEHAVIORAL PLASTICITY.

 spatial learning  cells that code for space  synaptic plasticity in the hippocampus  experiments that are knockouts  summary PART 4: BEHAVIORAL PLASTICITY.
Chapter 47 Learning and Memory: Basic Mechanisms Copyright © 2014 Elsevier Inc. All rights reserved.

Chapter 47 Learning and Memory: Basic Mechanisms Copyright © 2014 Elsevier Inc. All rights reserved.

Similar presentations

Ads by Google