Place cell maps slowly develop via competitive learning and conjunctive coding in the dentate gyrus

Authors
Kim, SoyounJung, DajungRoyer, Sebastien
Issue Date
2020-09
Publisher
Nature Publishing Group
Citation
Nature Communications, v.11, no.1
Abstract
Place cells exhibit spatially selective firing fields that collectively map the continuum of positions in environments; how such activity pattern develops with experience is largely unknown. Here, we record putative granule cells (GCs) and mossy cells (MCs) from the dentate gyrus (DG) over 27 days as mice repetitively run through a sequence of objects fixed onto a treadmill belt. We observe a progressive transformation of GC spatial representations, from a sparse encoding of object locations and spatial patterns to increasingly more single, evenly dispersed place fields, while MCs show little transformation and preferentially encode object locations. A competitive learning model of the DG reproduces GC transformations via the progressive integration of landmark-vector cells and spatial inputs and requires MC-mediated feedforward inhibition to evenly distribute GC representations, suggesting that GCs slowly encode conjunctions of objects and spatial information via competitive learning, while MCs help homogenize GC spatial representations.
Keywords
HIPPOCAMPAL GRANULE CELLS; HILAR MOSSY CELLS; PATTERN SEPARATION; ELECTROPHYSIOLOGICAL EVIDENCE; SYNAPTIC PLASTICITY; ADULT NEUROGENESIS; SPATIAL MAP; POTENTIATION; MEMORY; STIMULATION; place cells; spatial mapping; learning; treadmill
ISSN
2041-1723
URI
https://pubs.kist.re.kr/handle/201004/118216
DOI
10.1038/s41467-020-18351-6
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KIST Article > 2020
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