Abstract
The ability of neurons to maintain spine architecture and modulate it in response to synaptic activity is a crucial component of the cellular machinery that underlies information storage in pyramidal neurons of the hippocampus. Here we show a critical role for δ-catenin, a component of the cadherin-catenin cell adhesion complex, in regulating spine head width and length in pyramidal neurons of the hippocampus. The loss of Ctnnd2, the gene encoding δ-catenin, has been associated with the intellectual disability observed in the cri du chat syndrome, suggesting that the functional roles of δ-catenin are vital for neuronal integrity and higher order functions. We demonstrate that loss of δ-catenin in a mouse model or knockdown of δ-catenin in pyramidal neurons compromises spine head width and length, without altering spine dynamics. This is accompanied by a reduction in the levels of synaptic N-cadherin. The ability of δ-catenin to modulate spine architecture is critically dependent on its ability to interact with cadherin and PDZ domain-containing proteins. We propose that loss of δ-catenin during development perturbs synaptic architecture leading to developmental aberrations in neural circuit formation that contribute to the learning disabilities in a mouse model and humans with cri du chat syndrome.
Highlights
The architecture of spines in pyramidal neurons is critical for function
We demonstrate that loss of ␦-catenin in a mouse model or knockdown of ␦-catenin in pyramidal neurons compromises spine head width and length, without altering spine dynamics
Taken together with our previous studies, these results indicate that (a) ␦-catenin is a critical regulator of spine architecture in pyramidal neurons, (b) this functional role extends to different stages during development, and (c) this functional role of ␦-catenin is cell autonomous
Summary
The architecture of spines in pyramidal neurons is critical for function. Results: We identified ␦-catenin as a critical regulator of spine architecture in hippocampal neurons. The loss of Ctnnd, the gene encoding ␦-catenin, has been associated with the intellectual disability observed in the cri du chat syndrome, suggesting that the functional roles of ␦-catenin are vital for neuronal integrity and higher order functions. We demonstrate that loss of ␦-catenin in a mouse model or knockdown of ␦-catenin in pyramidal neurons compromises spine head width and length, without altering spine dynamics This is accompanied by a reduction in the levels of synaptic N-cadherin. By taking advantage of shRNA-mediated knockdown in rat hippocampal neurons, we demonstrate that knockdown of ␦-catenin during development leads to a similar phenotype The compromise in synaptic architecture with loss of ␦-catenin may underlie the behavioral phenotypes observed in the ␦-catenin mouse model and individuals with cri du chat syndrome
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