<p>Training rodents in a particularly difficult olfactory-discrimination task results with acquisition of high-skill to perform the task superbly, termed ‘rule-learning’. We show that rule-learning occurs abruptly, in a “light-bulb moment”. Using whole-cell patch-clamp recordings from the piriform cortex (PC) of Fos2A-iCreER/TRAP2 mice, we target activated-neurons, expressing immediate early genes (IEG). We notice, from the onset of training, IEG-positive neurons from trained animals display enhanced intrinsic excitability. Subsequently, synaptic excitation and inhibition are enhanced in these neurons, in a coordinated, cell-wide process. Additionally,&#xa0;in parallel, we detect&#xa0;the density of IEG-expressing neurons sharply declines. Double labeling with TRAP and c-Fos reveal that nearly two-thirds of the rule-memory cell ensemble neurons are activated from the beginning of training. Silencing TRAP-expressing neurons using inhibitory DREADD leads to a complete loss of rule memory. Hence, we propose that rule learning occurs at a discrete moment and is developed through a gradual process that stabilizes the memory of the rule.</p>

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Biophysical mechanisms underlying the generation and maintenance of rule-learning engram

  • Sankhanava Kundu,
  • Daniel Keren,
  • Iris Reuveni,
  • Samaa Zidan,
  • Amit Kumar,
  • Jackie Schiller,
  • Edi Barkai

摘要

Training rodents in a particularly difficult olfactory-discrimination task results with acquisition of high-skill to perform the task superbly, termed ‘rule-learning’. We show that rule-learning occurs abruptly, in a “light-bulb moment”. Using whole-cell patch-clamp recordings from the piriform cortex (PC) of Fos2A-iCreER/TRAP2 mice, we target activated-neurons, expressing immediate early genes (IEG). We notice, from the onset of training, IEG-positive neurons from trained animals display enhanced intrinsic excitability. Subsequently, synaptic excitation and inhibition are enhanced in these neurons, in a coordinated, cell-wide process. Additionally, in parallel, we detect the density of IEG-expressing neurons sharply declines. Double labeling with TRAP and c-Fos reveal that nearly two-thirds of the rule-memory cell ensemble neurons are activated from the beginning of training. Silencing TRAP-expressing neurons using inhibitory DREADD leads to a complete loss of rule memory. Hence, we propose that rule learning occurs at a discrete moment and is developed through a gradual process that stabilizes the memory of the rule.