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Pyramidal and stellate cell specificity of grid and border representations in layer 2 of medial entorhinal cortex.


ABSTRACT: In medial entorhinal cortex, layer 2 principal cells divide into pyramidal neurons (mostly calbindin positive) and dentate gyrus-projecting stellate cells (mostly calbindin negative). We juxtacellularly labeled layer 2 neurons in freely moving animals, but small sample size prevented establishing unequivocal structure-function relationships. We show, however, that spike locking to theta oscillations allows assigning unidentified extracellular recordings to pyramidal and stellate cells with ?83% and ?89% specificity, respectively. In pooled anatomically identified and theta-locking-assigned recordings, nonspatial discharges dominated, and weakly hexagonal spatial discharges and head-direction selectivity were observed in both cell types. Clear grid discharges were rare and mostly classified as pyramids (19%, 19/99 putative pyramids versus 3%, 3/94 putative stellates). Most border cells were classified as stellate (11%, 10/94 putative stellates versus 1%, 1/99 putative pyramids). Our data suggest weakly theta-locked stellate border cells provide spatial input to dentate gyrus, whereas strongly theta-locked grid discharges occur mainly in hexagonally arranged pyramidal cell patches and do not feed into dentate gyrus.

SUBMITTER: Tang Q 

PROVIDER: S-EPMC4276741 | biostudies-literature | 2014 Dec

REPOSITORIES: biostudies-literature

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Pyramidal and stellate cell specificity of grid and border representations in layer 2 of medial entorhinal cortex.

Tang Qiusong Q   Burgalossi Andrea A   Ebbesen Christian Laut CL   Ray Saikat S   Naumann Robert R   Schmidt Helene H   Spicher Dominik D   Brecht Michael M  

Neuron 20141204 6


In medial entorhinal cortex, layer 2 principal cells divide into pyramidal neurons (mostly calbindin positive) and dentate gyrus-projecting stellate cells (mostly calbindin negative). We juxtacellularly labeled layer 2 neurons in freely moving animals, but small sample size prevented establishing unequivocal structure-function relationships. We show, however, that spike locking to theta oscillations allows assigning unidentified extracellular recordings to pyramidal and stellate cells with ∼83%  ...[more]

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