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Effects of visual inputs on neural dynamics for coding of location and running speed in medial entorhinal cortex

Holger Dannenberg, Hallie Lazaro, Pranav Nambiar, Alec Hoyland, Michael E. Hasselmo

2020eLife41 citationsDOIOpen Access PDF

Abstract

Neuronal representations of spatial location and movement speed in the medial entorhinal cortex during the 'active' theta state of the brain are important for memory-guided navigation and rely on visual inputs. However, little is known about how visual inputs change neural dynamics as a function of running speed and time. By manipulating visual inputs in mice, we demonstrate that changes in spatial stability of grid cell firing correlate with changes in a proposed speed signal by local field potential theta frequency. In contrast, visual inputs do not alter the running speed-dependent gain in neuronal firing rates. Moreover, we provide evidence that sensory inputs other than visual inputs can support grid cell firing, though less accurately, in complete darkness. Finally, changes in spatial accuracy of grid cell firing on a 10 s time scale suggest that grid cell firing is a function of velocity signals integrated over past time.

Topics & Concepts

Entorhinal cortexCoding (social sciences)Visual cortexNeurosciencePredictive codingComputer scienceDynamics (music)BiologyArtificial intelligenceHippocampusPhysicsMathematicsAcousticsStatisticsMemory and Neural MechanismsSleep and Wakefulness ResearchOlfactory and Sensory Function Studies
Effects of visual inputs on neural dynamics for coding of location and running speed in medial entorhinal cortex | Litcius