Spatial Information Encoding across Multiple Neocortical Regions Depends on an Intact Hippocampus

• Published in: The Journal of neuroscience Vol. 41; no. 2; pp. 307 - 319
• Main Authors: Esteves, Ingrid M, Chang, HaoRan, Neumann, Adam R, Sun, JianJun, Mohajerani, Majid H, McNaughton, Bruce L
• Format: Journal Article
• Language: English
• Published: United States Society for Neuroscience 13.01.2021
• Subjects: Algorithms; Animals; Calcium; Calcium imaging; Cortex; Cues; Hippocampus; Hippocampus - cytology; Hippocampus - physiology; Mice; Mice, Transgenic; Neocortex - cytology; Neocortex - physiology; Nerve Net - physiology; Neuroimaging; Neurons; Neurons - physiology; Psychomotor Performance - physiology; Representations; Space Perception - physiology; Spatial data; Spatial discrimination; Touch; Treadmills; neocortex; two-photon; calcium imaging; spatial navigation; place cells
• ISSN: 0270-6474; 1529-2401
• DOI: 10.1523/jneurosci.1788-20.2020

There has been considerable research showing populations of neurons encoding for different aspects of space in the brain. Recently, several studies using two-photon calcium imaging and virtual navigation have identified "spatially" modulated neurons in the posterior cortex. We enquire here whether the presence of such spatial representations may be a cortex-wide phenomenon and, if so, whether these representations can be organized in the absence of the hippocampus. To this end, we imaged the dorsal cortex of mice running on a treadmill populated with tactile cues. A high percentage (40-80%) of the detected neurons exhibited sparse, spatially localized activity, with activity fields uniformly localized over the track. The development of this location specificity was impaired by hippocampal damage. Thus, there is a substantial population of neurons distributed widely over the cortex that collectively form a continuous representation of the explored environment, and hippocampal outflow is necessary to organize this phenomenon. Increasing evidence points to the role of the neocortex in encoding spatial information. Whether this feature is linked to hippocampal functions is largely unknown. Here, we systematically surveyed multiple regions in the dorsal cortex of the same animal for the presence of signals encoding for spatial position. We described populations of cortical neurons expressing sequential patterns of activity localized in space in primary, secondary, and associational areas. Furthermore, we showed that the formation of these spatial representations was impacted by hippocampal lesion. Our results indicate that hippocampal inputs are necessary to maintain a precise cortical representation of space.