1 / 19

Neural Plasticity: Long-term Depression

Neural Plasticity: Long-term Depression. Lesson 16. Long-term Depression. Hippocampus Low frequency stimulation 1 Hz over 10-15 min NMDA & Ca 2+ -dependent Low Ca 2+   phosphatase activity Cerebellum mGlu1-R Different mechanism ~. Cerebellum. Motor functions

ownah
Download Presentation

Neural Plasticity: Long-term Depression

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Neural Plasticity:Long-term Depression Lesson 16

  2. Long-term Depression • Hippocampus • Low frequency stimulation • 1 Hz over 10-15 min • NMDA & Ca2+ -dependent • Low Ca2+  phosphatase activity • Cerebellum • mGlu1-R • Different mechanism ~

  3. Cerebellum • Motor functions • Coordination of movements • Regulation of posture • Indirect control • Adjust outputs of descending tracts • Also nonmotor functions • memory/language ~

  4. Cerebellum: Anatomy • Folia & lobules • analogous gyri & lobes • Vermis - along midline • output  ventromedial pathway • Hemispheres • output  lateral pathway • Deep cerebellar nuclei • fastigial, interposed, & dentate • Major output structures ~

  5. Spinocerebellum Cerebrocerebellum Vestibulocerebellum I n t e r p o s e d F a s t i g i a l Dentate

  6. Cerebellum • Programs ballistic movements • feed-forward control • no feedback during execution • direction, force, & timing • long term modification of circuits • Motor learning • shift from conscious  unconscious ~

  7. Cerebellum • Acts as comparator for movements • compares intended to actual performance • Correction of ongoing movements • internal & external feedback • deviations from intended movement ~

  8. Cerebellum: 3 layered cortex 1. Molecular layer • parallel fibers • axons of granule cells • runs parallel to long axis of folium ~

  9. Cerebellum: 3 layered cortex 2. Purkinge cell layer • large somas • axons to underlying white matter • perpendicular to main axis of folium ~

  10. Cerebellum: 3 layered cortex 3. Granular layer • innermost layer • small, densely packed granule cells • > # neurons in cerebral cortex ~

  11. Cerebellum: 3 layered cortex Molecular Purkinje Granule

  12. Cerebellum: & Motor Learning • Purkinje cells only output from cerebellar cortex • inhibit deep cerebellar nuclei • Input to Purkinje cells • Mossy fibers via parallel fibers • from spinal cord & brainstem nuclei • climbing fibers • cerebral cortex & spinal cord • via inferior olivary nucleus ~

  13. Cerebellum: & Motor Learning • 1 Purkinje cell synapses.. • 1 each with 200,000 parallel fibers • Many with 1 climbing fiber • strong synaptic connections • Climbing fibers ­effects of mossy fibers • transient ~

  14. Cerebellum: 3 layered cortex Molecular Purkinje Granule Mossy fibers Climbing fibers

  15. Cerebellum: & Motor Learning • Long-term depression (LTD) • requires concurrent activity • climbing & parallel fibers active together • ¯in activity of specific Purkinje cells • Climbing fibers may carry error signals • corrections ¯ parallel fiberinfluence • input specificity • only affects active synapses of a parallel fiber ~

  16. LTD Mechanisms • Similar to LTP • changes are postsynaptic • Glutamate receptors ~

  17. LTD Mechanisms • Requires concurrent activity • Climbing fiber 1. Ca++ influx - voltage-gated • Parallel fibers activate 2. AMPA - Na+ influx 3. mGLUR1 • AMPA desensitized •  Na+ influx ~

  18. LTD Mechanisms • mGluR1 • metabotropic • cGMP-mediated • intracellular Ca++ stores • activation of phosphatases • Knockout mice • lack mGluR1 • loss of motor coordination ~

More Related