Abstract
Human memory is a polygenic cognitive trait that is fundamental to individual competence. Genome-wide association studies (GWAS) have identified KIBRA as a novel gene associated with human memory performance. KIBRA interacts with AMPA receptors (AMPARs) and proteins essential for synaptic plasticity. The deletion of Kibra in mice impairs synaptic plasticity and learning and memory. However, the molecular basis through which KIBRA regulates dynamic AMPAR trafficking underlying synaptic plasticity is still unknown. Here we report that KIBRA interacts with the neuronal specific kinase PKCγ to modulate AMPAR trafficking upon learning, and KIBRA-PKCƔ signaling pathway also associates with human memory performance. We find PKCƔ is an essential kinase that phosphorylates AMPARs upon learning, and the loss of KIBRA in mouse brain impedes PKCƔ-AMPAR interaction. Activation of PKCƔ enables KIBRA to recruit phosphorylated AMPARs to the synapse to promote LTP and learning. We further performed transcriptomic and genetic analyses in human postmortem brain samples, and behavioral and fMRI evaluations in living human subjects, to demonstrate the genetic interactions between KIBRA and PRKCG on memory performance and memory associated physiological engagement of the hippocampal memory system. Overall, our results support that the KIBRA-PKCƔ signaling pathway is crucial for modulating memory performance in mice and humans.
Publisher
Cold Spring Harbor Laboratory
Cited by
1 articles.
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