Schematized drawing of a hippocampal slice and the hippocampal circuitry (the positive feedback reentrant loop)Top: the major cell populations of the hippocampus—the dentate granule cells of the dentate gyrus, the CA3 pyramidal cells, and the CA1 pyramidal cells. Bottom: one of several impulse pathways through the hippocampus. Axons of entorhinal cortical (EC) neurons contact dentate granule cells (DG) via the perforant path. The axons of the granule cells (the mossy fibers) terminate primarily on the apical dendrites of the CA3 pyramidal cells. The CA3 pyramidal cells send Schaffer collaterals to the apical dendrites of the CA1 pyramidal cells. A significant percentage of axons from CA1 terminate in the subiculum. In turn, neurons in the subiculum project to the entorhinal cortex, thus closing the circuit passing from entorhinal cortex to hippocampus back to the entorhinal area. All connections in this feedback loop are excitatory (glutamatergic).

Schematic of the N-methyl-d-aspartate (NMDA) subtype of glutamate receptor, illustrating some of the regulatory domains discussed in the textFor the channel to open (thus allowing the flow of calcium, sodium, and potassium), two events must occur simultaneously: 1) glutamate and glycine must bind to their sites, and 2) the cell must be depolarized (i.e., attain a more positive membrane potential) such that magnesium is released from its site within the channel pore. The "P" in the figure indicates that the receptor may be regulated by phosphorylation of the intracellular domains. Probably four subunits come together to form the receptor channel complex. At least one of those subunits must be the subunit NMDAR1. Members of the NR2 family contribute subunits as well, helping to determine channel functional properties. APV=2-amino-5-phosphonovalerate; CGS 19755=1-(cis-2-carboxypiperidine-4-yl)-propyl-1-phosphonic acid; CPP=3-(2-carboxypiperazin-4-yl)-propyl-1-phosphonic acid; MK 801=dizocilpine; PCP=phencyclidine; TCP=1-(1-(2-thienyl)-cyclohexyl)-piperidine.

A speculative model by which opposing processes occurring during sensitization could lead to NMDA receptors' displaying enhanced activity (as in the dentate granule and CA3 neurons of the hippocampus of kindled animals) or diminished activity (as in the NMDA receptor hypofunction hypothesis of schizophrenia)Here, the relative activities of kinases (phosphorylating enzymes) and phosphatases (dephosphorylating enzymes) determine the overall phosphorylation state of the receptor (and hence its activity). Evidence suggests that phosphorylation of the receptor results in increased NMDA receptor activity, whereas dephosphorylation results in decreased activity. In the model, yotiao is a scaffolding protein that associates with the NMDA receptor. Yotiao also binds type 1 protein phosphatase (PP1) and adenosine 3′,5′-cyclic monophosphate (cAMP)-dependent protein kinase (PKA), bringing these enzymes in close proximity to the receptor. The close apposition of these enzymes to the NMDA receptor suggests a tight correlation of their activity with ion flow (or lack thereof) through the NMDA receptor. However, many kinases and phosphatases (including tyrosine kinases, protein kinase C, and calcium-sensitive kinase and phosphatase) are able to interact with the NMDA receptor, and these may be important in the model depicted. Likewise, the model suggests increased/decreased phosphorylation state of individual receptors (e.g., phosphate groups on two sites rather than one or none), but an equally plausible possibility is the addition or removal of a phosphate group from a single specific site in a subpopulation of NMDA receptors.