Early intrinsic excitability plasticity of neocortical engram neurons defines memory formation and precision.
Senka Hadzibegovic, Liangying Zhu, Melanie Ginger, Maria Gueidão Costa, Paula Alvarez Menendez, Rafaël De Sa, Katy Le Corf, Yves Le Feuvre, Olivier Nicole, Bruno Bontempi, Andreas Frick
Abstract
Open AccessNeocortical memory engrams are thought to mature via strengthened interconnectivity, yet synaptic plasticity alone cannot explain the dynamic vividness of enduring memories. Neuronal intrinsic excitability (IE) plasticity has been touted as an early priming mechanism that renders engram neurons susceptible to ongoing plastic processes and later encoding events. Here, we reveal that learning-induced IE plasticity of nascent anterior cingulate cortex (ACC) engram neurons is a permissive mechanism for the formation and specificity of remote memories. Using c-fos-dependent genetic/viral targeting in mice, we found that contextual fear learning triggered a time-limited increase in ACC engram IE during the early phase of memory formation. Remarkably, chemogenetically hyperpolarizing these neurons within-but not outside-the IE plasticity window strengthened consolidated memories, enhanced their context-precision, and prevented interference-induced engram reallocation. Thus, IE plasticity in nascent ACC engram neurons acts as an essential tagging mechanism that determines the fate and dynamic content of remote memories.