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Toroidal topology of population activity in grid cells

Author

Listed:
  • Richard J. Gardner

    (Norwegian University of Science and Technology)

  • Erik Hermansen

    (Norwegian University of Science and Technology)

  • Marius Pachitariu

    (HHMI Janelia Research Campus)

  • Yoram Burak

    (The Hebrew University of Jerusalem
    The Hebrew University of Jerusalem)

  • Nils A. Baas

    (Norwegian University of Science and Technology)

  • Benjamin A. Dunn

    (Norwegian University of Science and Technology
    Norwegian University of Science and Technology)

  • May-Britt Moser

    (Norwegian University of Science and Technology)

  • Edvard I. Moser

    (Norwegian University of Science and Technology)

Abstract

The medial entorhinal cortex is part of a neural system for mapping the position of an individual within a physical environment1. Grid cells, a key component of this system, fire in a characteristic hexagonal pattern of locations2, and are organized in modules3 that collectively form a population code for the animal’s allocentric position1. The invariance of the correlation structure of this population code across environments4,5 and behavioural states6,7, independent of specific sensory inputs, has pointed to intrinsic, recurrently connected continuous attractor networks (CANs) as a possible substrate of the grid pattern1,8–11. However, whether grid cell networks show continuous attractor dynamics, and how they interface with inputs from the environment, has remained unclear owing to the small samples of cells obtained so far. Here, using simultaneous recordings from many hundreds of grid cells and subsequent topological data analysis, we show that the joint activity of grid cells from an individual module resides on a toroidal manifold, as expected in a two-dimensional CAN. Positions on the torus correspond to positions of the moving animal in the environment. Individual cells are preferentially active at singular positions on the torus. Their positions are maintained between environments and from wakefulness to sleep, as predicted by CAN models for grid cells but not by alternative feedforward models12. This demonstration of network dynamics on a toroidal manifold provides a population-level visualization of CAN dynamics in grid cells.

Suggested Citation

  • Richard J. Gardner & Erik Hermansen & Marius Pachitariu & Yoram Burak & Nils A. Baas & Benjamin A. Dunn & May-Britt Moser & Edvard I. Moser, 2022. "Toroidal topology of population activity in grid cells," Nature, Nature, vol. 602(7895), pages 123-128, February.
    • Handle: RePEc:nat:nature:v:602:y:2022:i:7895:d:10.1038_s41586-021-04268-7
    DOI: 10.1038/s41586-021-04268-7
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    Cited by:

    1. Duy Duong-Tran & Ralph Kaufmann & Jiong Chen & Xuan Wang & Sumita Garai & Frederick H. Xu & Jingxuan Bao & Enrico Amico & Alan D. Kaplan & Giovanni Petri & Joaquin Goni & Yize Zhao & Li Shen, 2024. "Homological Landscape of Human Brain Functional Sub-Circuits," Mathematics, MDPI, vol. 12(3), pages 1-25, January.
    2. Francis Kei Masuda & Emily A. Aery Jones & Yanjun Sun & Lisa M. Giocomo, 2023. "Ketamine evoked disruption of entorhinal and hippocampal spatial maps," Nature Communications, Nature, vol. 14(1), pages 1-19, December.
    3. Laurenz Muessig & Fabio Ribeiro Rodrigues & Tale L. Bjerknes & Benjamin W. Towse & Caswell Barry & Neil Burgess & Edvard I. Moser & May-Britt Moser & Francesca Cacucci & Thomas J. Wills, 2024. "Environment geometry alters subiculum boundary vector cell receptive fields in adulthood and early development," Nature Communications, Nature, vol. 15(1), pages 1-17, December.
    4. Davide Spalla & Alessandro Treves & Charlotte N. Boccara, 2022. "Angular and linear speed cells in the parahippocampal circuits," Nature Communications, Nature, vol. 13(1), pages 1-13, December.

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