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Distinct organization of two cortico-cortical feedback pathways.


ABSTRACT: Neocortical feedback is critical for attention, prediction, and learning. To mechanically understand its function requires deciphering its cell-type wiring. Recent studies revealed that feedback between primary motor to primary somatosensory areas in mice is disinhibitory, targeting vasoactive intestinal peptide-expressing interneurons, in addition to pyramidal cells. It is unknown whether this circuit motif represents a general cortico-cortical feedback organizing principle. Here we show that in contrast to this wiring rule, feedback between higher-order lateromedial visual area to primary visual cortex preferentially activates somatostatin-expressing interneurons. Functionally, both feedback circuits temporally sharpen feed-forward excitation eliciting a transient increase-followed by a prolonged decrease-in pyramidal cell activity under sustained feed-forward input. However, under feed-forward transient input, the primary motor to primary somatosensory cortex feedback facilitates bursting while lateromedial area to primary visual cortex feedback increases time precision. Our findings argue for multiple cortico-cortical feedback motifs implementing different dynamic non-linear operations.

SUBMITTER: Shen S 

PROVIDER: S-EPMC9613627 | biostudies-literature | 2022 Oct

REPOSITORIES: biostudies-literature

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Distinct organization of two cortico-cortical feedback pathways.

Shen Shan S   Jiang Xiaolong X   Scala Federico F   Fu Jiakun J   Fahey Paul P   Kobak Dmitry D   Tan Zhenghuan Z   Zhou Na N   Reimer Jacob J   Sinz Fabian F   Tolias Andreas S AS  

Nature communications 20221027 1


Neocortical feedback is critical for attention, prediction, and learning. To mechanically understand its function requires deciphering its cell-type wiring. Recent studies revealed that feedback between primary motor to primary somatosensory areas in mice is disinhibitory, targeting vasoactive intestinal peptide-expressing interneurons, in addition to pyramidal cells. It is unknown whether this circuit motif represents a general cortico-cortical feedback organizing principle. Here we show that i  ...[more]

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