ORDB: Neuron - Cerebellum interneuron granule GLU cell

Neuron

Data

Name

Cerebellum interneuron granule GLU cell

Picture

Canonical Form Type

Canonical form 2 Show Other

Picture from

Modified from Llinas, RR and Walton, KD in Synaptic Organization of the Brain, 4th ed. (Shepherd, GM., ed.). New York: Oxford University Press 1998.

Organism

Vertebrates Show Other

Neuron category

interneuron Show Other

Neuron type

cell rotation

Coordinates(2D)

Description

Electrophysiological properties

NeuroLex

Layer

Hodology

Molecular Marker

Neuronal Receptors (7)

SN	Property present	CF-Compartment	Receptor	Connect Note	Publication facts
1	Yes	Distal equivalent dendrite	AMPA		AMPA receptors during development: granule cells express a heterogeneous population of AMPA receptors, a subset of which are segregated to postsynaptic sites after synaptogenesis
2	Yes	Distal equivalent dendrite	NMDA	from extrinsic and intrinsic mossy fibers	Silent synapses during development
3	Yes	Axon terminal	GabaB	GABA spillover	Whereas, activation of the adenosine A1 receptor reduces synaptic strength by modulating presynaptic calcium channels, baclofen modulates presynaptic calcium channels as well, but also affects release processes downstream from calcium entry
4	Yes	Soma	Nicotinic	mossy fiber-granule cell synapse	In slices that preserve mossy-fiber to granule cell synapses, Ach induced diverse responses in granule cells, one response being somatic current (nAChR also mediated postsynaptic currents, PSCs, which, however, were glutamatergic in nature, indicating a presynaptic mechanism. )
5	Yes	Soma	GabaA		Granule cells compensate for the lack GABAA receptors (in somatic location? ) by expressing the two-pore-domain K+ channel TASK-1, a voltage-independent K + conductance so as to maintain normal neuronal behaviour; this finding highlight the importance of GABAA receptor-mediated background inhibition
6	Yes	Axon terminal	NMDA		NMDA reversibly depresses postsynaptic currents, through a trans-synaptic mechanism that involves release from parallel fibers nitric oxide that decreases the glutamate sensitivity of the Purkinje cell
7	Yes	Axon terminal	Glutamate		Activation of mGluR1 in Purkinje cells causes a Ca-dependent release of a retrograde messenger, probably Glutamate, which acts on presynaptic ionotropic glutamatergic receptor (AMPA/kinate) on the parallel fibers (PFs), depolarizes PFs and modulates neurotransmission from parellel fibers to Purkinje cells

Neuronal Currents (4)

SN	Property present	CF-Compartment	Current	Publication facts
1	Yes	Axon terminal	I Calcium	Calcium is involved in delayed release of neurotransmitter at synapses between granule cell their postsynaptic targets (stellate cells and Purkinje cells)
2	Yes	Soma	I Potassium	Single-channel and whole-cell recording identified three types of current: a transient inward sodium current and a transient and a sustained outward potassium current
3	Yes	Soma	I A	Presence of Subthreshold-operating transient (A-type) K(+) currents (I(SA)s), as indicated by an accesspry subunit that accelerates the kinetics of this current
4	Yes	Soma	I Na,t	Single-channel and whole-cell recording identified three types of current: a transient inward sodium current and a transient and a sustained outward potassium current

Neuronal Transmitters (2)

SN	Property present	CF-Compartment	transmitter	Connect Note	Publication facts
1	Yes	Axon terminal	NO		At parallel fiber (PF) -Purkinje cell synapses, NMDA reversibly depresses postsynaptic currents, through a trans-synaptic mechanism that involves release from PFs nitric oxide that decreases the glutamate sensitivity of the Purkinje cell
2	Yes	Axon terminal	Glutamate	parallel fibers to Purkinje cells

Other categories referring to Cerebellum interneuron granule GLU cell

Interneurons Connectivity.Interneuron (1)

Pathological mechanism.Neuron (1)

2 Objects Relationship (edge).Object Two (target) (1)

Neuronal Structure.Neurons (1)

Revisions:	9
Last Time:	12/18/2015 2:51:52 PM
Reviewer:	Luis Marenco
Owner:	Buqing Mao