University of California, Irvine neurobiologists believe the discovery of this mechanism adds another piece to the puzzle in the ongoing effort to uncover the mysteries of memory and, potentially, certain intellectual disabilities.
In the study led by Marcelo Wood of UC Irvine's Center for the Neurobiology of Learning & Memory, the team investigated the role of this mechanism - a gene designated Baf53b - in long-term memory formation. Baf53b is one of several proteins making up a molecular complex called nBAF.
One of the key questions the researchers addressed is how mutations in components of the nBAF complex lead to cognitive impairments.
Wood and his colleagues used mice bred with mutations in Baf53b. While this genetic modification did not affect the mice's ability to learn, it did notably inhibit long-term memories from forming and severely impaired synaptic function.
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"These findings present a whole new way to look at how long-term memories form," said Wood.
"They also provide a mechanism by which mutations in the proteins of the nBAF complex may underlie the development of intellectual disability disorders characterised by significant cognitive impairments," Wood added.
The mutated forms of Baf53b did not allow for this necessary gene expression.
"The results from this study reveal a powerful new mechanism that increases our understanding of how genes are regulated for memory formation," Wood said.
"Our next step is to identify the key genes the nBAF complex regulates. With that information, we can begin to understand what can go wrong in intellectual disability disorders, which paves a path toward possible therapeutics," Wood said.