Conjunctive vector coding and place coding in hippocampus share a common directional signal

Abstract

AbstractVector coding is becoming increasingly understood as a major mechanism by which neural systems represent an animal’s location in both a global reference frame and a local, item-based reference frame. Landmark vector cells (LVCs) in the hippocampus complement classic place cells by encoding the vector relationship (angle and distance) between the individual and specific landmarks in the environment. How these properties of hippocampal principal cells interact is not known. We simultaneously recorded the activities of place cells and LVCs via in vivo calcium imaging of the CA1 region of freely moving rats during classic, cue-card rotation studies. The firing fields of place cells rotated relative to the center of the platform to follow the cue card rotation, whereas the firing fields of simultaneously recorded LVCs rotated by the same amount as the place cells, but the axis of rotation was the nearby local landmarks, not the environmental center. We identified a novel type of place cell that exhibited conjunctive coding of the classic place field properties and LVC properties. These results demonstrate the capacity of CA1 neurons to encode both world-centered spatial information and animals’ location relative to the local landmarks, with a common directional input presumably provided by the head direction cell system.