, 2004, Arendt, 2009 and Milnerwood and Raymond, 2010). “
“Donald Hebb first proposed that synapses between two neurons would be strengthened if they showed coincident activity. This idea was hugely influential because such “Hebbian” plasticity could theoretically explain how memories formed, particularly associations between temporally linked
events. Subsequently, Bliss and Lomo (1973) discovered long-term potentiation (LTP), a phenomenon in which synaptic strength is enhanced following bursts of synaptic activity. Thus, LTP gained particular notoriety as one of the underlying mechanisms of learning and memory and considerable effort was focused on unraveling mechanisms of coincidence detection and the subsequent synaptic plasticity. From these GDC-0068 manufacturer studies, NMDA-type glutamate receptors (NMDARs) emerged as a class of ionotropic receptors whose pharmacological or genetic perturbations disrupted both LTP and learning and memory (Traynelis et al., 2010). NMDARs are now understood as pivotal molecules required for coincidence detection, Selleckchem PI3K inhibitor synaptic plasticity, and learning and memory
in the central nervous system (CNS). A voltage-dependent Mg2+ block of NMDARs allows them to function as Hebbian coincidence detectors (Mayer et al., 1984; Nowak et al., 1984). Binding by glutamate alone is insufficient for channel activation as Mg2+ remains bound to a site in the channel pore, effectively blocking ion transport. Eviction of this Mg2+ ion additionally requires membrane depolarization. Thus, the coincidence Tolmetin of presynaptic glutamate release
and strong depolarizing potential in the postsynaptic neuron is required for the opening of NMDAR channels. Subsequent Ca2+ influx through the open channel serves as a trigger for synaptic plasticity. Mouse models with mutations specific to the NMDA Mg2+ block site result in developmental defects and/or defects in complex behavior, suggesting that coincidence detection is required for normal NMDAR function in vivo (Single et al., 2000; Rudhard et al., 2003). However, for two reasons, neither these studies nor the observations of abnormal LTP and learning in these mutant mice (Chen et al., 2009) directly address the role of coincidence detection in vivo. First, all known Mg2+ block mutations in murine NMDARs also decrease Ca2+ conductance. Thus, it is unclear whether the resultant phenotypes are due to Mg2+ block-specific effects or reduced calcium permeability. Second, because Mg2+ block mutants show severe developmental defects and early lethality, it is difficult to exclude the possibility that defects in learning observed in NMDAR Mg2+ block mutants arise due to altered nervous system development. Miyashita et al. (2012)’s experiments in Drosophila circumvent these confounding issues and directly assess the role of the Mg2+ block in memory formation. Drosophila NMDARs, composed of two subunits, dNR1 and dNR2, are necessary for normal memory formation ( Xia et al., 2005; Wu et al., 2007).
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