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Motor Systems: Cerebellum and LTD

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Cortico-pontine-cerebellar-thalamo-cortical circuit. Cerebellum and long-term depression ... vermis and paravermal region; coordination of movements and muscle tone ... – PowerPoint PPT presentation

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Title: Motor Systems: Cerebellum and LTD


1
Motor Systems Cerebellum and LTD
  • Richard Harlan, PhD
  • harlanre_at_tulane.edu

2
Overview
  • Gross structure of cerebellum
  • Cytoarchitecture of cerebellum
  • Functional organization of cerebellum
  • Cortico-pontine-cerebellar-thalamo-cortical
    circuit
  • Cerebellum and long-term depression

3
Cortical-Subcortical-Thalamo-Cortical Loops
Subcortical Structures
Cortex
Thalamus
4
Motor Hierarchy and Loops
5
Cortical-Subcortical-Thalamo-Cortical
Loops Involving cerebellum

Cortex
Pons


Cerebellum
Thalamus

6
Overview
  • Gross structure of cerebellum
  • Cytoarchitecture of cerebellum
  • Functional organization of cerebellum
  • Cortico-pontine-cerebellar-thalamo-cortical
    circuit
  • Cerebellum and long-term depression

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Cerebellar organization
  • Divided into a cortex and deep nuclei
  • Cortex divided into 10 lobules
  • Each lobule divided into folia, running
    medial-lateral
  • Cortex also divided into vermis on midline and
    hemispheres

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Deep nuclei
  • Fastigial (medial, relates to vermis)
  • Interposed or intermediate (two nuclei, relate to
    paravermal region of hemispheres
  • Dentate (lateral and largest, relates to
    hemispheres)

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Overview
  • Gross structure of cerebellum
  • Cytoarchitecture of cerebellum
  • Functional organization of cerebellum
  • Cortico-pontine-cerebellar-thalamo-cortical
    circuit
  • Cerebellum and long-term depression

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15
Cell types in cerebellar cortex
  • Purkinje cell body, dendrites, axons, recurrent
    collaterals dendrites are flattened
    perpendicular to folia GABAergic output from
    the cortex project to deep nuclei

16
Purkinje Neurons
17
Cell types in cerebellar cortex
  • basket GABAergic pinceaux around axon hillock of
    Purkinje cell projects to surrounding Purkinje
    cells to produce surround inhibition
  • stellate stellate cells only in mol two types
    of stellate cells superficial and deep GABAergic

18
Cell types in cerebellar cortex
  • granule cells send parallel fibers (PF) to
    molecular layer activate dendrites of Purkinje,
    stellate, basket and Golgi cells glutamatergic
  • Golgi cells inhibitory interneurons that synapse
    on mossy fiber terminals GABAergic and
    enkephalinergic

19
Cerebellar Circuitry
  • Two major inputs
  • Climbing fibers from inferior olivary complex
    form massive excitatory contacts with Purkinje
    neurons
  • Mossy fibers from several brain regions synapse
    on granule cells
  • Inputs send one collateral to deep cerebellar
    nuclei and one to cerebellar cortex
  • Output from cerebellar cortex is Purkinje cell
    projects to deep cerebellar neuron

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Purkinje Neurons
Perpendicular to folia
Parallel to folia
22
Complex and simple spikes of Purkinje cells, as
recorded intracellularly following excitation by
climbing and mossy fibers, respectively.
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26
Overview
  • Gross structure of cerebellum
  • Cytoarchitecture of cerebellum
  • Functional organization of cerebellum
  • Cortico-pontine-cerebellar-thalamo-cortical
    circuit
  • Cerebellum and long-term depression

27
Functional divisions of the cerebellum
  • Vestibulo-cerebellum flocculo-nodular lobe
    reflex control of balance
  • Spinocerebellum vermis and paravermal region
    coordination of movements and muscle tone
  • Cerebro-cerebellum lateral portions of
    hemispheres planning and initiation of
    movements mostly upper limbs

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29
Intermediate or paravermal zone
30
Functional divisions of the cerebellum
  • Vestibulo-cerebellum flocculo-nodular lobe
    reflex control of balance
  • Spinocerebellum vermis and paravermal region
    coordination of movements and muscle tone
  • Cerebro-cerebellum lateral portions of
    hemispheres planning and initiation of
    movements mostly upper limbs

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32
Functional divisions of the cerebellum
  • Vestibulo-cerebellum flocculo-nodular lobe
    reflex control of balance
  • Spinocerebellum vermis and paravermal region
    coordination of movements and muscle tone
  • Cerebro-cerebellum lateral portions of
    hemispheres planning and initiation of
    movements mostly upper limbs

33
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34
Functional divisions of the cerebellum
  • Vestibulo-cerebellum flocculo-nodular lobe
    reflex control of balance
  • Spinocerebellum vermis and paravermal region
    coordination of movements and muscle tone
  • Cerebro-cerebellum lateral portions of
    hemispheres planning and initiation of
    movements mostly upper limbs

35
Cortical-Cerebellar Loop
glutamate
Motor Cortex
Pons
glu
glu
Motor Thalamus VL
glutamate
Cerebellum
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Cerebellar Crossings
  • symptoms are ipsilateral to lesion
  • some outputs are ipsilateral fastigial and
    vestibular nuclei
  • crossed outputs are double crossed outputs from
    interposed and dentate n. are crossed
    (decussation of superior cerebellar peduncle),
    but output from targets are also crossed (e.g.
    rubrospinal, corticospinal, corticobulbar)
  • climbing fibers are always crossed
  • mossy fibers old are ipsilateral, new are
    contralateral

38
Cerebellar Problems
  • Vestibulocerebellum loss of balance, swaying,
    truncal and gait ataxia
  • Spinocerebellum and cerebrocerebellum
    (neocerebellar syndrome)

39
Neocerebellar Syndrome
  • ataxia intermittent or jerky movements lateral
    lesions cause ataxia in limbs, medial lesions
    cause gait ataxia, but not upper limb ataxia
  • dysmetria deficit in judging distances, e.g.
    past-pointing
  • adiadochokinesis clumsiness in rapidly
    alternating movements
  • asynergy decomposition of movements
  • hypotonia weakness, flacidness and fatigue
  • intention tremor tremor at end of a movement
  • nystagmus lateral eye movements with fast and
    slow components

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42
Overview
  • Gross structure of cerebellum
  • Cytoarchitecture of cerebellum
  • Functional organization of cerebellum
  • Cortico-pontine-cerebellar-thalamo-cortical
    circuit
  • Cerebellum and long-term depression

43
Major players in LTD in cerebellar cortex
  • AMPA and mGluRs
  • Ca
  • PKC
  • NO

44
Cell types in cerebellar cortex
  • Purkinje PKC g and some have PKC d no NMDA
    receptors, but mGluR1 and AMPA receptors (GluR2
    and 2/3, perhaps GluR1) at PF synapses no nNOS

45
Cell types in cerebellar cortex
  • basket GABAergic pinceaux around axon hillock of
    Purkinje cell projects to surrounding Purkinje
    cells to produce surround inhibition PKC d in
    pinceau
  • stellate stellate cells only in mol two types
    of stellate cells superficial and deep
    superficial cells have PKC bI GABAergic

46
Cell types in cerebellar cortex
  • granule cells send parallel fibers (PF) to
    molecular layer activate dendrites of Purkinje,
    stellate, basket and Golgi cells glutamatergic
    much nNOS here PKC bII perhaps mGluR1a in
    granule cells and PF
  • Golgi cells inhibitory interneurons that synapse
    on mossy fiber terminals GABAergic and
    enkephalinergic

47
LTD in Purkinje cells
  • A. phenonemon long-term decrease in EPSP (or
    EPSC) amplitude following paired activation of
    "inputs" from CF and PF (or two sets of PF)
    initiation phase independent of protein
    synthesis, while maintenance phase requires
    postsynaptic protein synthesis

48
LTD in Purkinje cells
  • B. major preparations studied
  • 1. in vivo
  • 2. acute slices
  • 3. dissociated cells in culture

49
LTD in Purkinje cells required factors
  • 1. glutamate acting on AMPA and mGluR1 receptors
    no LTD in mGluR1 knockout mice LTD can be
    rescued by intracellular activation of IP3, and
    this can be blocked by PKC antagonist LTD can
    also be rescued by mGluR1a transgene under
    control of Purkinje cell-specific promoter in
    knockout mice
  • 2. increase in intracellular Ca, through VGCC
    and perhaps release of stored Ca or activation
    of Na-Ca exchanger link to mGluR1 receptors
  • 3. activation of PKC link to mGluR1 receptors
    and Ca

50
LTD in Purkinje cells important factors
  • 1. NO production, although this is controversial
    and may be a product of cell culture how does
    this work?
  • 2. activation of soluble guanylyl cyclase in PC,
    leading to increased cGMP, activation of
    G-substrate, and inhibition of phosphatases

51
LTD in Purkinje cells important factors
  • 3. phosphorylation of AMPA receptors, especially
    GluR2 at ser-880 via PKC this produces reduction
    in affinity of GluR2 for GRIP, disruption of
    GluR2 clustering, and internalization of GluR2
    application of peptides that interfere with
    clathrin-mediated endocytosis blocks LTD
    intracellular infusion of peptides that disrupt
    interaction between GluR2 and PDZ domain proteins
    (GRIP/ABP) and PICK1 blocks LTD

52
LTD in Purkinje cells important factors
  • 4. activation of PLA2 to produce arachidonic
    acid link to PKC
  • 5. activation of CRF receptors, which are linked
    to activation of PKC

53
LTD in Purkinje cells important factors
  • 6. induction of c-Fos and c-Jun procedures which
    induce LTD increase IEG production these
    transcription factors may be important for
    maintenance phase
  • 7. late phase of LTD blocked by transfection of
    dominant negative inhibitor of CREB, and by
    pharmacological inhibition of CaMKIV, but not PKA
    or MAPK cascades

54
Functional significance of LTD
  • A. adaptation in vestibulo-ocular reflex, and
    potentially in other examples of motor learning
  • B. why LTD rather than LTP? LTP occurs at mossy
    fiber-granule cell synapse and at granule
    cell-Purkinje cell synapse (mediated by PKA,
    which can activate NO release)
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