The CaMKII/NMDAR complex as a molecular memory
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Abstract
CaMKII is a major synaptic protein that is activated during the induction of long-term potentiation (LTP) by the Ca2+
influx through NMDARs. This activation is required for LTP induction, but the role of the kinase in the maintenance
of LTP is less clear. Elucidating the mechanisms of maintenance may provide insights into the molecular processes
that underlie the stability of stored memories. In this brief review, we will outline the criteria for evaluating an LTP
maintenance mechanism. The specific hypothesis evaluated is that LTP is maintained by the complex of activated
CaMKII with the NMDAR. The evidence in support of this hypothesis is substantial, but further experiments are
required, notably to determine the time course and persistence of complex after LTP induction. Additional work is
also required to elucidate how the CaMKII/NMDAR complex produces the structural growth of the synapse that
underlies late LTP. It has been proposed by Frey and Morris that late LTP involves the setting of a molecular tag
during LTP induction, which subsequently allows the activated synapse to capture the proteins responsible for late
LTP. However, the molecular processes by which this leads to the structural growth that underlies late LTP are
completely unclear. Based on known binding reactions, we suggest the first molecularly specific version of tag/
capture hypothesis: that the CaMKII/NMDAR complex, once formed, serves as a tag, which then leads to a binding
cascade involving densin, delta-catenin, and N-cadherin (some of which are newly synthesized). Delta-catenin binds
AMPA-binding protein (ABP), leading to the LTP-induced increase in AMPA channel content. The addition of
postsynaptic N-cadherin, and the complementary increase on the presynaptic side, leads to a trans-synaptically
coordinated increase in synapse size (and more release sites). It is suggested that synaptic strength is stored stably
through the combined actions of the CaMKII/NMDAR complex and N-cadherin dimers. These N-cadherin pairs have
redundant storage that could provide informational stability in a manner analogous to the base-pairing in DNA.
General note
Artículo de publicación ISI
Quote Item
Sanhueza and Lisman Molecular Brain 2013, 6:10
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