Cadherin–catenin complex in learning and memory
Long-term potentiation (LTP), thought to be the cellular basis for learning and memory, involves a specific signal transmission process that underlies synaptic plasticity.[1] Among the many mechanisms responsible for the maintenance of synaptic plasticity is the cadherin–catenin complex.[2] By forming complexes with intracellular
N-cadherins are believed to be involved in mediating LTP and the synaptic changes underlying learning and memory. During embryonic development,
Structural function and adhesion
Structure of the cadherin–catenin complex
N-cadherins are transmembrane proteins expressed in the majority of CNS synapses.[5] N-cadherins are most commonly expressed on both the presynaptic active zone and postsynaptic density (PSD) regions, and contain both extracellular Ca2+ binding domains as well as intracellular domains for binding their protein partners. A common binding partner for Cadherins are intracellular catenin proteins, specifically the three different subtypes, α-catenins, β-catenins, and p120ctn family catenins. β-catenins and p120ctns bind cadherin’s intracellular domain at the distal and proximal regions respectively.[6] α-catenins, when in monomeric form, will associate with the cadherin-catenin complex via β-catenins. In homodimeric form, α-catenins do not bind β- catenins, but preferentially bind F-actin and other proteins promoting F-actin polymerization.[7] Each catenin subtype and its interaction with cadherins plays a distinct role in the mediation of synaptic plasticity and spine structure.
Regulation of adhesion
Evidence suggest that N-Cadherins stabilize the connection between the presynaptic terminal and postsynaptic spine [8] and that this stabilization increases the likelihood that released glutamate will bind receptors on the postsynaptic neuron.[9] At basal levels of synaptic activity, N-cadherins are largely monomers and are thus weakly adhesive to cadherins located in the cell on the opposite side of the synapse. The influx of Ca2+ through NMDARs, promotes the dimerization of N-cadherins. Dimerized cadherins readily bind to their presynaptic cadherin partners. Inhibition of N-cadherin binding via blocking antibodies prevents the induction of late phase L-long term potentiation,[10] suggesting that the adhesive property of dimeric N-cadherin is necessary for late phase L-LTP. Additionally, KCl depolarization of the presynaptic axon both confers protease resistance to N-cadherins and disperses them throughout the PSD from their original clustering in synaptic puncta,[11] thus increasing their efficacy for cell adhesion.
N-cadherin adhesion further stabilizes the synapse by enabling AMPAR-activation-induced spine head expansion.[12] This morphological change helps to prevent further synaptic modifications that could jeopardize the information held by the already existing synaptic connections. Spine head expansion accomplishes this by reducing the NMDAR to AMPAR ratio, creating a proportionally smaller calcium influx, as well as by allowing for faster calcium diffusion out of the spine. The rapid removal of calcium prevents it from initiating the post-translational modifications that would further alter synaptic strength.[13] Overexpression of an N-cadherin mutant incapable of adhesion prevents spine head expansion, demonstrating N-cadherin’s essential role in this process.[12]
Regulation of cadherin surface levels, turnover, and stability
Regulation mechanisms differ in their synthesis requirements and their temporal initiation.[8][14] One mode of cadherin regulation is surface stabilization, a fairly rapid process (occurring approximately 100 minutes after activity) that is independent of protein synthesis.
NMDAR activity reduces phosphorylation of β-catenin at tyr-654, thereby inhibiting N-cadherin endocytosis and facilitating surface retention and expression.[8][15]
Surface expression is also regulated via protocadherin-mediated adhesion. Protocadherin-alpha and protocadherin-gamma interact to form a protein complex that enhances the surface expression of each cadherin subtype.[16]
Cadherin expression is also regulated by activity-induced internalization, which occurs much later than surface stabilization (an average of 4 hours after the stimulus). Internalization is dependent on protein synthesis, and p120 catenin proteins (p120ctn) are implicated in the turnover, degradation and ‘clustering’ of cadherins into the adhesive junctions at the synapse.[17] P120 ctn proteins are thought to either inhibit endocytosis of neural cadherins, or act at the cell surface to control cadherin turnover.[17][18][19] Down-regulation of p120 ctn leads to greater cadherin endocytosis and prevents adhesion between the pre and post-synaptic neuron.[18] Such evidence strongly suggests that p120 is necessary for cadherin stability.
Binding and signaling
Intracellular binding partners
β-catenin localizes reserve pool vesicles (RPVs) at presynaptic sites.[20] The deletion of β-catenin in vivo results in a decrease in the number of RPVs localized in the synaptic site and an increase in RPVs dispersed along the axon. Moreover, RPVs were unresponsive to continuous trains of stimulation of the presynaptic neuron in B-catenin knockouts. This effect of B-catenin is independent of cadherin-mediated adhesion, and is instead modulated by PDZ binding proteins such as Veli to cadherin. Additionally,
Signal transduction pathways
p120ctn signals through
Cellular function
Role in receptor trafficking/stability
When the glutamate receptor binding protein ABP and p120ctn are co-expressed, anti-p120ctn serum pulls out a complex containing both proteins from cell lysates. The same occurs for a protein similar to ABP, called GRIP. cDNA screening and yeast mating
Regulation of gene expression
Cadherins and catenins have been shown to be involved in regulating gene expression, an important process in synaptic plasticity. (See figures on the right).
Expression of
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