After the integrative storage of associated signals, a signal induces the recollection of its associated signal, or the other way around. This associative memory is essential to associative thinking, logical reasoning, imagination and computation. In terms of cellular mechanisms underlying associative memory, new mutual synapse innervations are formed among those coactivated neurons, so that they are recruited to be associative memory cells or associative memory neurons. These associative memory cells receive new synapse innervations alongside innate synapse inputs and encode signals carried by these inputs. We proposed to examine microRNAs as initiative factors for recruiting new synapse innervations and associative memory cells. In a mouse model of associative memory characterized as the reciprocal retrieval of associated whisker and odor signals, barrel and piriform cortical neurons gain their ability to encode whisker and odorant signals based on the newly formed synapse innervations between these coactivated cortices besides innate synapse inputs. miRNA-324 and miRNA-133a are required for recruiting these new synapse innervations and associative memory cells as well as sufficient for facilitating their recruitments, but not for innate synapse inputs. Therefore, the coactivation of sensory cortices through microRNA as initiative factor to recruit new mutual synapse innervations and associative memory cells for associative memory.
Keywords: Associative learning; Barrel cortex; Memory cell; Neural circuit; Piriform cortex.
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