Navigation is often constrained to pathways, and a recurring problem concerns whether to turn left or right when approaching an intersection. We examined this problem during T-maze performance in which the maze location in the recording environment varied over five-trial blocks and analyzed the associated positional firing patterns of hippocampal CA1 and posterior parietal cortex neurons. An arbitrary partitioning of the environmental space determined the left versus right turning rule for T-maze behavior. Under these conditions, rats learned the logical fragmentation of allocentric space into left turn and right turn sub-regions. Paradoxically, under these conditions, the spatial tuning of both posterior parietal cortex and hippocampal CA1 neurons followed the frame of reference given by the T-maze, as opposed to the location in the environment. Moreover, first trials within each block were associated with distinct firing rate changes for both posterior parietal cortex and hippocampal CA1 neurons. These data support a model where spatial tuning by hippocampus and cortex can interact to guide choice behavior in complex, path-based environments where a correct turn choice varies across environmental locations, and as a function of recent experience.
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