Basket cell

Basket cell

Transverse section of a cerebellar folium (Basket cell labeled at bottom left)
Details
Location Cerebellum
Morphology multipolar
Function Inhibitory interneuron
Neurotransmitter GABA
Presynaptic connections Parallel fibers
Postsynaptic connections Purkinje cells
Identifiers
NeuroLex ID Basket Cell
Anatomical terminology

Basket cells are inhibitory GABAergic interneurons of the brain, found in the molecular layer of the cerebellum, the hippocampus, and the cerebral cortex.[1]

Anatomy and Physiology

Basket cells are multipolar interneurons that function to make inhibitory synapses and control the overall potentials of target cells. Their cell bodies can be found in molecular layers. The dendrites of basket cells are free branching, contain smooth spines, and extended from 12 to 30 mm. Basket cells have shown to form axo-somatic synapses. [2] The branched axonal arborizations give rise to the name as they appear as baskets surrounding the soma of the target cell. [3] By controlling the synapses of neurons, basket cells can directly control the action potential discharge rate of target cells. [4]

Cerebellum

Micrograph of cerebellar cortex showing Purkinje cells within the baskets formed by the processes of basket cells. Bielschowsky stain.

In the cerebellum, the multipolar basket cells have branching dendrites, which are dilated and knotty. Basket cells synapse on the cell bodies of Purkinje cells and make inhibitory synapses with Purkinje cells. Cerebellar basket cell axons fire inhibitory neurotransmitters such as GABA to Purkinje cell axons, and inhibits the Purkinje cell.[5]Purkinje cells send inhibitory messages to the deep cerebellar nuclei and are responsible for the sole output of motor coordination from the cerebellar cortex. With the work of the basket cell, Purkinje cells do not send the inhibitory response for motor coordination and motor movement occurs.[6]

Hippocampus

Hippocampal basket cells target somata and proximal dendrites of pyramidal neurons. Like their counterparts in the cortex,[7]hippocampal basket cells are also parvalbumin-expressing and fast-spiking. In the CA3 region of the hippocampus, basket cells can often form recurrent inhibition loops with pyramidal cells. [8] Projections from a pyramidal cell will innervate the basket cell, which in turn has a projection back onto the original pyramidal cells. Since basket cells are inhibitory, this generates a closed loop that can help dampen excitatory responses.

Cortex

In the cortex, basket cells have sparsely branched axons giving off small pericellular, basket-shaped elaborations at several intervals along their length. Basket cells make up 15-25 % of total neurons in the cortex.[9]There are three types of basket cells in the cortex, the small, large and nest type:[10] The axon of a small basket cell arborizes in the vicinity of that same cell's dendritic range, this axon is short. In contrast, large basket cells innervate somata in different cortical columns due to a long axon.[11]The nest basket cells are an intermediate form of the small and large cells, their axons are confined mainly to the same cortical layer as their somata. Nest basket cells have "radiating axonal collaterals" between that of large and small basket cells. They are included as basket cells because they are interneurons that perform axo-somatic synapses. [12]

Additional images

External links

References

  1. Jones, Edward (1984). Cerebral Cortex: Volume 1: Cellular Components of the Cerebral Cortex. Springer. ISBN 9780306415449.
  2. Jones EG, Hendry SHC (1984) Basket cells. In: Cerebral cortex: cellular components of the cerebral cortex (Peters A, Jones EG, eds), pp. 309–334. New York: Plenum Press.
  3. Stahl's Essential Pharmacology, http://neuronbank.org/wiki/index.php/Basket_cell
  4. Cobb SR, Buhl EH, Halasy K, Paulsen O, Somogyi P (1995) Synchronization of neuronal activity in hippocampus by individual GABAergic interneurons. Nature 378:75-78.
  5. Southan, A., Robertson, B. "Patch-Clamp Recordings from Cerebellar Basket Cell Bodies and Their Presynaptic Terminals Reveal an Asymmetric Distribution of Voltage-Gated Potassium Channels", The Journal of Neuroscience, London, 1 February 1998. Retrieved on 2014-3-12.
  6. Tan, Y., Llano, I. "Modulation by K+ channels by action potential-evoked intracellular Ca2+ concentration rises in rat cerebellar basket cell axons", Journal of Physiology , Germany, 14 June 1999. Retrieved on 2014-3-11.
  7. Contreras, D. (2004). "Electrophysiological classes of neocortical neurons". Neural Networks 17 (5–6): 633–646. doi:10.1016/j.neunet.2004.04.003. PMID 15288889.
  8. Bryne, John. "Feedback/recurrent inhibition: Feedback inhibition in microcircuits". Neuroscience Online. University of Texas Health Center.
  9. Wang, Y., Gupta, A., Toledo-Rodriquez, M., Wu, C., and Markram, H. "Anatomical, Physiological, Molecular and Circuit Properties of Nest Basket Cells in the Developing Somatosensory Cortex", Oxford Journals, April 2002. Retrieved on 2014-3-11.
  10. Fox, K. "Barrel Cortex", Cambridge University Press, pp. 55-56
  11. Wang, Y., Gupta, A., Toledo-Rodriquez, M., Wu, C., and Markram, H. "Anatomical, Physiological, Molecular and Circuit Properties of Nest Basket Cells in the Developing Somatosensory Cortex", Oxford Journals, April 2002. Retrieved on 2014-3-11.
  12. Wang, Y., Gupta, A., Toledo-Rodriquez, M., Wu, C., and Markram, H. "Anatomical, Physiological, Molecular and Circuit Properties of Nest Basket Cells in the Developing Somatosensory Cortex", Oxford Journals, April 2002. Retrieved on 2014-3-11.