In vitro synaptic reconsolidation in amygdala slices prepared from rat brains

The retrieval of consolidated fear memory causes it to be labile or deconsolidated, and the deconsolidated fear memory is reconsolidated over time in a protein synthesis-dependent manner. We have recently developed an ex vivo model where during fear memory deconsolidation and reconsolidation the synaptic state can be monitored at thalamic input synapses onto the lateral amygdala (T-LA synapses), a storage site for auditory fear memory. In this ex vivo model, the deconsolidation and reconsolidation processes of auditory fear memory in the intact brain were prevented following brain slicing; therefore, we could monitor the synaptic state for memory deconsolidation and reconsolidation at the time of brain slicing. However, why the synaptic reconsolidation process stopped after brain slicing in the ex vivo model is not known. One possibility is that brain slicing severs neuromodulatory innervations, which are required for memory reconsolidation, from other brain regions (e.g., noradrenergic innervation). In the present study, we supplemented amygdala slices with exogenous norepinephrine as a substitute for the severed noradrenergic innervations. DHPG (a group I metabotropic glutamate receptor agonist)-induced depotentiation (mGluRI-depotentiation), a marker for consolidated synapses, was observed following norepinephrine application to slices prepared immediately after tone presentation (fear memory retrieval) to rats that had been pre-conditioned to a tone paired with a shock. These results suggest that noradrenergic activation initiates synaptic reconsolidation. In contrast, mGluRI-depotentiation was absent following norepinephrine application to slices that were prepared immediately after the tone presentation (no fear memory retrieval) to rats when a tone and a shock were unpaired, ruling out the possibility that noradrenergic activation somehow facilitates a subsequent synaptic depression induced by DHPG irrespective of synaptic reconsolidation. Furthermore, the restored mGluRI-depotentiation following application of exogenous norepinephrine was dependent on de novo protein synthesis, as is memory reconsolidation. Thus, our findings suggest that T-LA synapses from acute slice preparations can undergo a reconsolidation process, thereby providing an optimal preparation to study a fear memory reconsolidation process in vitro.

► Brain slicing prevents synaptic reconsolidation processes.
► Pre-exposure to norepinephrine restores the synaptic reconsolidation in slices.
► This synaptic reconsolidation in slices depends on de novo protein synthesis.