7. Background and Basic Circuitry Flashcards
1
Q
NMR conditioning and the cerebellum
A
- CS (tone) arrives at cerebellum as mossy fibre input
- US (shock of air puff) arrives at same region of cerebellum as climbing fibre input
- where do these inputs meet? - synapses for these cells could be sites for plasticity
2
Q
cerebellar cortex and deep nuclei
A
cerebellum has its own cortex with cell bodies on top of underlying white matter
two parts of the cerebellum:
1. extensive cerebellar cortex
2. compact deep nuclei
3
Q
cerebellar cortical circuitry (candidate 1)
A
- mossy fibres excite granule cells
- granule cell axons (parallel and ascending fibres) excite Purkinje cells
- Purkinje cells inhibit cells in deep nuclei
4
Q
Purkinje cells
A
- sole output of the cerebellar cortex
- cell bodies in the middle of cortex (Purkinje cell layer)
- each Purkinje cell recieves around 150’000 parrallel fibre synapses
- largest cells in the cerebellar cortex with a large dendritic tree (like a fan)
5
Q
Mossy Fibre
A
- input for CS
- NMR conditioning - convey information about the CS (tone) to area HVI
- probably: the frequency of firing increases with CS intensity
6
Q
Granule Cells
A
- Mossy fibres synapse with granule cells
- axons of granule cells form parallel fibres that synapse with the dendrites of Purkinje cells
- 80% of all cells in the brain are granule
- 100 granule cells per mossy fibre = expansion recoding
7
Q
expansion recoding
A
something to recode temporally bearing inputs into more spatially diverse outputs
8
Q
layers of cerebellar cortex
A
- more simple to cortex (which has 6)
- molecular layer
- Purkinje cell layer
- Granule cell layer
- white matter underneath
9
Q
Golgi cell
A
- input from parallel fibres
- project back to synapses between mossy fibres and granule cells (granule cell layer)
- are inhibitory - more parallel fibre input the more it is inhibited
- thought to regulate information flow (expansion recoding)
10
Q
stellate and basket cells
A
- both inhibitory and get input from parallel fibres
- Heiney et al., (2014) - supported this by silencing Purkinje cells through their activation
- found in molecular layer
- synapse with Purkinje cell body (basket)
- synapse with Purkinje cell dendrites (stellate)
- thought to balance average excitatory drive from parralel fibres
11
Q
simple spikes
A
Purkinje cells fire spontaneously (e.g. simple spikes)
- usually about 50 spikes/s
- parallel fibre input can increase this to > 200 spikes/s
12
Q
climbing fibres
A
- input for the US
- second input to Purkinje cells comes from climbing fibres
- have cell bodies in the inferior olive
- carry information about the US (air puff)
- typically fire spontaneously at low frequencies = 1 spike/s
13
Q
climbing fibres and purkinje cells
A
all wrapped around Purkinje cell dendrites
- acts as an enormous synapse
- give rise to parallel fibres
- 150’000 synapses for Purkinje cell
14
Q
effects on Purkinje cell firing
A
- very unusual shape of spikes produced by climbing fibre input
- whenever the climbing fibre fires the Purkinje cell does too (complex spikes)
- low frequency of firing compared to simple spikes
15
Q
long term depression
A
- what is the function of climbing fibre input?
- possibility that climbing fibre input acts to alter the efficacy of parallel fibre synapses on Purkinje cells
- activate the parallel fibre (on top of cerebellum) and you see a response in Purkinje cell
- you can pair this stimulation (say 100 times) with the stimulation of climbing fibres
- when you stimulate the climbing fibres on their own, their activation is depressed (LTD)
- fits in with the idea that climbing fibres convey an error signal
- not driving output but are telling the system its done something wrong by weakening the synapses