Abstract
Since Milner and Scoville published their observations of Henry Molaison's profound memory deficits following bilateral removal of the hippocampal formation (Scoville & Milner, 1957), generations of neuroscientists have sought to understand how the hippocampus executes its essential role in learning and memory. Central to that understanding is elaboration of the functions performed by the circuitry of the hippocampal CA3 region. A signature feature of CA3 is that its principal cells, the pyramidal cells (PCs), generate a highly recurrent network, by giving off and receiving excitatory collateral inputs to and from myriad other CA3 PCs. Inputs to this recurrent network come primarily from layer 2 neurons in nearby entorhinal cortex (EC) via the perforant pathway (PP), which bifurcates into two distinct excitatory pathways: a monosynaptic pathway onto the distal apical dendrites of the PCs; and a disynaptic pathway, where EC inputs synapse onto granule cells in the dentate gyrus, which, in turn, synapse onto the proximal apical dendrites of CA3 PCs via mossy fibre (MF) axons. Owing to their strength and location, the MF inputs strongly drive activity in the PCs despite there being only several dozen of these inputs per neuron (as opposed to thousands of inputs from the PP and recurrent collaterals).
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