LAUSR

The hippocampus (HPC) and the lateral prefrontal cortex (LPFC) are two cortical areas of the primate brain deemed essential to cognition. Here we hypothesize that the codes mediating neuronal communication in HPC and LPFC microcircuits have distinctively evolved to serve plasticity and memory function at different spatiotemporal scales. We used a virtual reality task in which animals navigated through a maze using a joystick and selected one of two targets in the arms of the maze according to a learned context-color rule. We found that neurons and neuronal populations in both regions encode similar information about the task. Moreover, we demonstrate that many HPC neurons concentrate spikes into bursts, whereas most layer II/III LPFC neurons sparsely distribute spikes over time. As the animals learned the task HPC neurons, but not LPFC neurons, increased their burst rate as a function of performance. When integrating spike rates over short intervals, HPC neuronal ensembles reached maximum decoded information with fewer neurons than LPFC ensembles. Our results show that during associative learning HPC principal cells concentrate spikes in bursts enabling temporal summation and fast synaptic plasticity in small populations of neurons and ultimately facilitating rapid encoding of associative memories. On the other hand, layers II/III LPFC pyramidal cells fire spikes more sparsely distributed in time and over a larger number of neurons. The latter would facilitate broadcasting of signals loaded in short term memory across neuronal populations without necessarily triggering fast synaptic plasticity.