Molecular mechanisms of memory - PowerPoint PPT Presentation

1 / 33
About This Presentation
Title:

Molecular mechanisms of memory

Description:

How does the brain achieve Hebbian plasticity? ... Recall that glutamate is the main excitatory neurotransmitter in the brain. ... – PowerPoint PPT presentation

Number of Views:69
Avg rating:3.0/5.0
Slides: 34
Provided by: michae1365
Category:

less

Transcript and Presenter's Notes

Title: Molecular mechanisms of memory


1
Molecular mechanisms of memory
2
  • How does the brain achieve Hebbian plasticity?
  • How is the co-activity of presynaptic and
    postsynaptic cells registered and stored?

3
  • Experiments in the 1980s showed that blockade of
    a particular type of glutamate receptor prevented
    the induction of LTP without interfering with
    synaptic transmission.
  • When this receptor was blocked, the synapse still
    worked (release of transmitter from the
    presynaptic neuron produced a normal postsynaptic
    response)
  • However, it could be cause LTP.

4
  • A second experiment showed that LTP could not
    occur if calcium was prevented from rising in the
    postsynaptic cell during action potentials.
  • These two findings converged, because the special
    glutamate receptor controls calcium in the
    postsynaptic cell during action potentials.

5
  • Recall that glutamate is the main excitatory
    neurotransmitter in the brain.
  • When it is released from presynaptic terminals
    and binds to postsynaptic receptors, it increases
    the likelihood that the postsynaptic neuron will
    fire.

6
  • There are several types of glutamate receptors.
  • The AMPA receptor is involved in regular synaptic
    transmission
  • The NMDA receptor is involved in synaptic
    plasticity.
  • There are others, but not involved here.

7
(No Transcript)
8
(No Transcript)
9
  • Presynaptically released glutamate binds to both
    AMPA and NMDA receptors.
  • Binding of glutamate to AMPA receptors is the
    normal way that a postsynaptic cell is induced to
    fire.

10
  • In contrast, when presynaptically released
    glutamate reaches NMDA receptor on the
    postsynaptic cell, it has no initially because
    part of the receptor is blocked.
  • However, one glutamate has caused the
    postsynaptic cell to fire an action potential by
    binding to the AMPA receptors, the block on the
    NMDA receptor is rmoved.
  • Glutamate can then open the NMDA receptor channel
    and allow calcium to enter the cell.
  • LTP is the result.

11
  • For NMDA receptors to pass calcium, both
    presynaptic and postsynaptic cell must be active.
  • This is the requirement for Hebbian plasticity.

12
  • Why is calcium entry through NMDA receptors a
    means of forming associations between a strong
    and a weak input?

13
  • Activity in the weak input pathway results in the
    release of glutamate and the binding of glutamate
    to postsynaptic receptors.
  • Because the connection is weak, however, the
    input is not capable on its own of making the
    postsynaptic cell fire an action potential.
  • However, when synaptic activity in the strong
    pathway activates the postsynaptic cell, the
    block on NMDA receptors will be removed, even at
    the weak synapses.

14
  • If the weak pathway releases glutamate at the
    same time that the strong pathway causes an
    action potential, the NMDA receptors at both the
    strong and the weak synapses will be able to bind
    the glutamate.
  • Calcium will flow in through the NMDA receptors,
    and the weak synapses will be strengthened.

15
  • In summary, the reason that NMDA receptors allow
    LTP to occur is that they are coincidence
    detectors they are able to register that
    presynaptic and postsynaptic neurons are active
    at the same time.
  • NMDA receptors allow the cell to record exactly
    which presynaptic inputs were active when the
    postsynaptic cell was firing.
  • This input specificity is key to association,
    which is exactly what Hebb described.

16
Long term memory
  • The binding of glutamate to its receptors is a
    brief event.
  • Memories can be long term.
  • Biological and chemical changes must occur that
    outlast the synaptic activation by NMDA.

17
  • Changes in synapses have been studied use two
    procedures
  • Early LTP is a form of Hebbian LTP that lasts
    only an hour or so
  • Late LTP is more persistent
  • Early and late LTP are commonly considered
    analogs of short-term and long-term memory.

18
  • Short- and long-term memory are distinguished by
    their chemical requirements, in addition to their
    longevity.
  • Known for several decades that if animals are
    given drugs that prevent the brain from making
    new proteins, they are able to learn normally
    (short term) but are unable to form long-lasting
    memories.

19
  • If the animals are tested within an our of
    learning some task, they perform well, but when
    they are tested the next day, they show no sign
    of having learned the task.

20
  • This requirement for protein synthesis is true
    for most if not all kinds of memory, and for most
    if not all species.
  • Blockade of protein synthesis has no effect on
    early LTP but prevents late LTP.
  • These parallels between early LTP and short term
    memory on the one hand, and late LTP and
    long-term memory on the other, are consistent
    with the idea that LTP may mediate memory.

21
Second messengers in memory
  • Neurotransmitters like glutamate are considered
    first messengers
  • They are responsible for signaling between
    neurons.
  • Second messengers initiate chemical reactions
    within neurons after the neuron is stimulated by
    the first messengers.

22
Calcium is a major 2nd messenger
  • We saw that, when glutamate binds to its NMDA
    receptors, calcium flows into a cell (after the
    block has been removed)
  • Once this occurs, calcium directs chemical
    reactions that strengthen synaptic connections.

23
  • The inflow of calcium activate protein kinases,
    which are enzymes that activate other proteins.
  • Protein kinases phosphorylate their target
    proteins, which transforms them from inactive to
    an active state.

24
  • The creation of long-lasting or late LTP, like
    long term memory, requires synthesis of new
    proteins.
  • This requires activation of kinases, specifically
    protein kinase A (PKA), MAP kinase (MAPK) and
    calcium/calmodulin protein kinase (CaMK)

25
  • These activated kinases move to the cell nucleus
    where they activate another protein, CREB.
  • CREB is a transcription factor that causes the
    expression of specific genes to produce new
    proteins.
  • These proteins strengthen the synapses.

26
(No Transcript)
27
Biochemistry of LTP
  • LTP in the hippocampus involves
  • NMDA receptor activation
  • consequent post-synaptic increase in calcium
  • activation of protein kinases and other enzymes
  • a partially-characterized sequence of events
    leading to increased synaptic strength

28
Mutants in genes in this pathway cause changes in
learning ability
29
Gene TargetingMethods exist to
  • add, delete, or modify genes in the mouse genome.
  • restrict expression of mouse genes to specific
    regions of the brain,
  • restrict expression to specific experimental
    conditions
  • high/low temperature
  • presence/absence of antibiotic
  • These methods can be used to create mouse models
    of human disease, e.g., Alzheimer' disease.

30
  • The first gene-targeting study of LTP and
    learning used mice with a null mutation for the
    alpha CaMKII gene.
  • This gene responds to changes in calcium (Ca) ion
    changes related to memory formation.
  • Alpha CaMKII mutants showed impaired LTP and LTD
    in the hippocampus and neocortex.

31
  • Although the alpha CaMKII mutant mice were
    severely impaired in the hippocampal-dependent
    version of the water maze, they were able to
    learn the "visible-platform" version of this
    task, which is known not to depend on hippocampal
    function.

32
  • alpha CaMKII mutants
  • can learn that the platform is the only escape in
    the pool
  • have the motivation to escape the water
  • have the motor coordination and sensory
    perception required to efficiently swim to the
    escape platform,
  • but they are unable to learn the spatial
    relationships required to guide them to the
    hidden platform.

33
  • CaMKII appears to be involved in the early stages
    of memory formation (during initial learning),
    but not in long-term memory formation.
Write a Comment
User Comments (0)
About PowerShow.com