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Place cell
A hippocampal pyramidal cell
Location Hippocampus
Function Spatial memory: fires when animal is in a particular location
Neurotransmitter Glutamate
Morphology Pyramidal projection neuron
Presynaptic connections superficial Entorhinal Cortex, Schaffer collaterals
Postsynaptic connections deep Entorhinal Cortex, Subiculum


Place cells are principal neurons in the hippocampus that fire strongly whenever an animal is in a specific location in an environment - the cell's "place field". These neurons are distinct from other neurons with spatial firing properties, such as grid cells, head direction cells, and spatial view cells. In the CA1 and CA3 hippocampal subfields, place cells are believed to be pyramidal cells, while those in the dentate gyrus are believed to be granule cells.

Place cells were first described in rats by O'Keefe and Dostrovsky.[1] Based on this discovery, O'Keefe and Nadel hypothesized that the primary function of the rat hippocampus is to form a cognitive map of the rat's environment.[2] Ekstrom and colleagues, using extracellular recordings from epileptic children, have found cells with similar properties in the human hippocampus[3]

Place fields Edit

Place cells show increased frequency of firing when an animal is in a specific area referred to as the cell's place field. The firing rate increase can be quite dramatic, from virtually zero outside the field to as much as 100 Hz (for brief periods) in the middle of the place field. When a rat forages randomly in an environment, place fields are only weakly modulated by the direction the rat faces, or not at all. However, when an animal engages in stereotyped behaviour (e.g. shuttling between goal locations), place cells tend to be active in the place field on passes in one direction only.

On initial exposure to a new environment, place fields become established within minutes. The place fields of cells tend to be stable over repeated exposures to the same environment. In a different environment, however, a cell may have a completely different place field or no place field at all. This phenomenon is referred to as "remapping". In any particular environment, roughly 40-50% of the hippocampal place cells will be active.[4][5]

In an environment with few or no directional cues (for instance, a circular environment surrounded by black curtains), place fields will tend to have a fixed radial position, but the entire set of place fields may rotate around the maze as predicted by a theory that rats are slowly losing their orientation.[6] If a polarizing cue is introduced (commonly a large white rectangle of paper), place fields will tend to have fixed positions relative to the cue. If the cue is moved while the animal can see it, place fields will tend to remain unaffected; however, if the animal is briefly removed from the environment then the cue is moved and the animal returned, the place fields will rotate so as to maintain their position relative to the cue card. Although visual cues seem to be the primary determinant of place cell firing, it is worth noting that firing persists in the dark, suggesting that proprioception or other senses contribute as well.

In an environment in which a rat is constrained to walk along a linear track, place fields will often have a directional component in addition to a place component. A place cell that fires at a particular location while the rat walks in one direction along the track will not necessarily fire as the rat visits that location from the other direction. If the rat frequently turns around at the same point, however, place fields there will often be independent of direction.

The size of place fields and their signal to noise ratio varies depending on the region of brain in consideration. In the hippocampus, place fields are smallest and sharpest at the dorsal pole, becoming larger toward the ventral pole.[7] This may reflect the topography of projections to the hippocampus. For example, the ventral hippocampus receives much more input from the amygdala, while dorsal hippocampus is more preferentially ennervated by entorhinal cortex.

Spatial modulated cells are also found in the entorhinal cortex, which feed input from neocortex into the hippocampus. Neurons in the lateral entorhinal cortex exhibit little spatial selectivity,[8] while neurons of the medial entorhinal (MEA) cortex exhibit multiple "place fields" that are arranged in an hexagonal pattern, and are therefore called "grid cells". These fields and spacing between fields increase from the dorso-lateral MEA to the ventro-medial MEA[9][10]

Phase Precession Edit

Phase Precession

Example of phase precession from a rat running on a circular track. Top plot: The position of the spikes are plotted along with the phase that the cell fired relative to the hippocampal theta rhythm. Bottom plot: Density plot of spike position versus phase of firing. Note that the y-axis covers two full theta cycles (0-720 degrees) to ensure that a complete cycle of precession is seen. The rat enters the field on right and exits on the left.

The hippocampus is one of many brain structures that can show a characteristic 4-12 Hz oscillation, theta rhythm, in an EEG recording. The oscillation has been observed in all mammalian species tested. In both rats and humans, it is associated with real or virtual movement through space.

When a neuron discharges, it can be said to fire in relation to the current phase of a theta cycle (0-360 degrees). When a rat enters a cell's place field, the cell will initially discharge when perisomatic inhibition is weakest. For theta recorded in the CA1 pyramidal cell layer, this approximately corresponds with the peak of the oscillation. On each following cycle as the rat progresses through the field, the cell will discharge at earlier and earlier phases,[11] typically stopping just before the trough of the cycle (as recorded in CA1 stratum pyramidale). In other words, the place cell produces a rhythmic discharge of a slightly higher frequency than the ongoing theta oscillation.

Because place fields of different cells overlap, at any particular time the rat will be at different distances in different fields, so each place cell will fire at a different phase of theta, allowing the rat's position to be determined with good precision. This potentially provides an alternative temporal code for location. Phase precession also results in the compression of temporal sequences of place cell firing - a phenomenon believed to facilitate synaptic plasticity.[12] There is evidence that phase precession is related to depolarisation of the neuron, such that the firing rate and firing phase of the cell are tightly coupled,[13].[14] However, phase precession can also be robustly independent of firing rate in freely moving animals[15] This caveat of phase precession, which alludes to the potential neural mechanisms underlying it, requires further investigation before arriving at a definitive answer.

See alsoEdit

ReferencesEdit

  1. O'Keefe J, Dostrovsky J (1971) "The hippocampus as a spatial map. Preliminary evidence from unit activity in the freely-moving rat" in Brain Research Volume 34, pages 171-175. Entrez PubMed 5124915
  2. John O'Keefe & Lynn Nadel (1978) The Hippocampus as a Cognitive Map, originally published by Oxford University Press ISBN 0-19-857206-9).
  3. Ekstrom A, Kahana M, Caplan J, Fields T, Isham E, Newman E, Fried I (2003) "Cellular networks underlying human spatial navigation" in Nature Volume 425, pages 184-188. Entrez PubMed 12968182
  4. Wilson MA, McNaughton BL (1993) "Dynamis of the hippocampal ensemble code for space" in Science Volume 261(5124), pages 1055-1058. Entrez PubMed 8351520
  5. Guzowski JF, Knierim JJ, Moser EI (2004) "Ensemble dynamics of hippocampal region CA3 and CA1" in Neuron Volume 44(4), pages 581-584. Entrez PubMed 15541306
  6. Knierim JJ, Kudrimoti HS, McNaughton BL (1995) "Place cells, head direction cells, and the learning of landmark stability" in Journal of Neuroscience Volume 15(3 Pt 1), pages 1648-1659 Entrez PubMed 7891125
  7. Jung MW, Weiner SI, McNaughton BL (1994) "Comparison of spatial firing characteristics of units in dorsal and ventral hippocampus of the rat" in Journal of Neuroscience Volume 14(12), pages 7347-7356 Entrez PubMed 7996180
  8. Hargreaves RL, Rao G, Lee I, Knierim JJ (2005) "Major dissociation between medial and lateral entorhinal input to dorsal hippocampus" in Science Volume 308(5729), pages 1792-1794 Entrez PubMed 15961670
  9. Fyhn M, Molden S, Witter MP, Moser EI, Moser MB (2004) "Spatial representation in the entorhinal cortex" in Science Volume 305(5688), pages 1258-1264 Entrez PubMed 15333832
  10. Hafting T, Fyhn M, Molden S, Moser MB, Moser EI (2005) "Microstructure of a spatial map in the entorhinal cortex" in Nature Volume 436(7052), pages 801-806 Entrez PubMed 15965463
  11. O'Keefe J, Recce ML (1993) "Phase relationship between hippocampal place units and the EEG theta rhythm" in Hippocampus Volume 3(3), pages 317-330 Entrez PubMed 8353611
  12. Skaggs WE, McNaughton BL (1996) "Replay of neuronal firing sequences in rat hippocampus during sleep following spatial experience" in Science Volume 271(5257), pages 1870-1873 Entrez PubMed 8596957
  13. Harris KD, Henze DA, Hirase H, Keinekugel X, Dragoi G, Czurko A, Buzsaki G (2002) "Spike train dynamics predicts theta-related phase precession in hippocampal pyramidal cells" in Nature Volume 417(6890), pages 738-741 Entrez PubMed 12066184
  14. Mehta MR, Lee AK, Wilson MA (2002) "Role of experience and oscillations in transforming a rate code into a temporal code" in Nature Volume 417(6890), pages 741-746 Entrez PubMed 12066185
  15. Huxter J, Burgess N, O'Keefe J (2003) "Independent rate and temporal coding in hippocampal pyramidal cells" in Nature Volume 425(6960), pages 828-832 Entrez PubMed 14574410

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