Literature DB >> 26176924

Speed cells in the medial entorhinal cortex.

Emilio Kropff1, James E Carmichael2, May-Britt Moser2, Edvard I Moser2.   

Abstract

Grid cells in the medial entorhinal cortex have spatial firing fields that repeat periodically in a hexagonal pattern. When animals move, activity is translated between grid cells in accordance with the animal's displacement in the environment. For this translation to occur, grid cells must have continuous access to information about instantaneous running speed. However, a powerful entorhinal speed signal has not been identified. Here we show that running speed is represented in the firing rate of a ubiquitous but functionally dedicated population of entorhinal neurons distinct from other cell populations of the local circuit, such as grid, head-direction and border cells. These 'speed cells' are characterized by a context-invariant positive, linear response to running speed, and share with grid cells a prospective bias of ∼50-80 ms. Our observations point to speed cells as a key component of the dynamic representation of self-location in the medial entorhinal cortex.

Mesh:

Year:  2015        PMID: 26176924     DOI: 10.1038/nature14622

Source DB:  PubMed          Journal:  Nature        ISSN: 0028-0836            Impact factor:   49.962


  40 in total

1.  A spin glass model of path integration in rat medial entorhinal cortex.

Authors:  Mark C Fuhs; David S Touretzky
Journal:  J Neurosci       Date:  2006-04-19       Impact factor: 6.167

2.  Hippocampal remapping and grid realignment in entorhinal cortex.

Authors:  Marianne Fyhn; Torkel Hafting; Alessandro Treves; May-Britt Moser; Edvard I Moser
Journal:  Nature       Date:  2007-02-25       Impact factor: 49.962

3.  Hippocampus-independent phase precession in entorhinal grid cells.

Authors:  Torkel Hafting; Marianne Fyhn; Tora Bonnevie; May-Britt Moser; Edvard I Moser
Journal:  Nature       Date:  2008-05-14       Impact factor: 49.962

4.  Grid cell firing may arise from interference of theta frequency membrane potential oscillations in single neurons.

Authors:  Michael E Hasselmo; Lisa M Giocomo; Eric A Zilli
Journal:  Hippocampus       Date:  2007       Impact factor: 3.899

5.  Cortical afferents of the perirhinal, postrhinal, and entorhinal cortices of the rat.

Authors:  R D Burwell; D G Amaral
Journal:  J Comp Neurol       Date:  1998-08-24       Impact factor: 3.215

6.  The entorhinal grid map is discretized.

Authors:  Hanne Stensola; Tor Stensola; Trygve Solstad; Kristian Frøland; May-Britt Moser; Edvard I Moser
Journal:  Nature       Date:  2012-12-06       Impact factor: 49.962

7.  Instant neural control of a movement signal.

Authors:  Mijail D Serruya; Nicholas G Hatsopoulos; Liam Paninski; Matthew R Fellows; John P Donoghue
Journal:  Nature       Date:  2002-03-14       Impact factor: 49.962

8.  The contributions of position, direction, and velocity to single unit activity in the hippocampus of freely-moving rats.

Authors:  B L McNaughton; C A Barnes; J O'Keefe
Journal:  Exp Brain Res       Date:  1983       Impact factor: 1.972

Review 9.  Grid cells and cortical representation.

Authors:  Edvard I Moser; Yasser Roudi; Menno P Witter; Clifford Kentros; Tobias Bonhoeffer; May-Britt Moser
Journal:  Nat Rev Neurosci       Date:  2014-06-11       Impact factor: 34.870

10.  A model combining oscillations and attractor dynamics for generation of grid cell firing.

Authors:  Michael E Hasselmo; Mark P Brandon
Journal:  Front Neural Circuits       Date:  2012-05-28       Impact factor: 3.492
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  187 in total

1.  A new direction for grid cells.

Authors:  Ken Cheng
Journal:  Learn Behav       Date:  2016-03       Impact factor: 1.986

Review 2.  Environmental boundaries as a mechanism for correcting and anchoring spatial maps.

Authors:  Lisa M Giocomo
Journal:  J Physiol       Date:  2016-01-05       Impact factor: 5.182

3.  Neural coding: Speed awareness.

Authors:  Katherine Whalley
Journal:  Nat Rev Neurosci       Date:  2015-08-05       Impact factor: 34.870

Review 4.  How environment and self-motion combine in neural representations of space.

Authors:  Talfan Evans; Andrej Bicanski; Daniel Bush; Neil Burgess
Journal:  J Physiol       Date:  2016-01-06       Impact factor: 5.182

5.  Hippocampus at 25.

Authors:  Howard Eichenbaum; David G Amaral; Elizabeth A Buffalo; György Buzsáki; Neal Cohen; Lila Davachi; Loren Frank; Stephan Heckers; Richard G M Morris; Edvard I Moser; Lynn Nadel; John O'Keefe; Alison Preston; Charan Ranganath; Alcino Silva; Menno Witter
Journal:  Hippocampus       Date:  2016-07-29       Impact factor: 3.899

Review 6.  Mesoscopic Neural Representations in Spatial Navigation.

Authors:  Lukas Kunz; Shachar Maidenbaum; Dong Chen; Liang Wang; Joshua Jacobs; Nikolai Axmacher
Journal:  Trends Cogn Sci       Date:  2019-05-23       Impact factor: 20.229

7.  Principles governing the integration of landmark and self-motion cues in entorhinal cortical codes for navigation.

Authors:  Malcolm G Campbell; Samuel A Ocko; Caitlin S Mallory; Isabel I C Low; Surya Ganguli; Lisa M Giocomo
Journal:  Nat Neurosci       Date:  2018-07-23       Impact factor: 24.884

8.  Parallel encoding of recent visual experience and self-motion during navigation in Drosophila.

Authors:  Hiroshi M Shiozaki; Hokto Kazama
Journal:  Nat Neurosci       Date:  2017-09-04       Impact factor: 24.884

9.  Passive Transport Disrupts Grid Signals in the Parahippocampal Cortex.

Authors:  Shawn S Winter; Max L Mehlman; Benjamin J Clark; Jeffrey S Taube
Journal:  Curr Biol       Date:  2015-09-17       Impact factor: 10.834

10.  Medial Entorhinal Cortex Selectively Supports Temporal Coding by Hippocampal Neurons.

Authors:  Nick T M Robinson; James B Priestley; Jon W Rueckemann; Aaron D Garcia; Vittoria A Smeglin; Francesca A Marino; Howard Eichenbaum
Journal:  Neuron       Date:  2017-04-20       Impact factor: 17.173
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