One retrieval trial induces reconsolidation in an appetitive learning paradigm in honeybees (Apis mellifera)

Combining memory retrieval with the application of a protein synthesis-inhibitor leads to an amnestic effect that is referred to as the reconsolidation phenomenon. Several behavioural studies demonstrate that only a few or weak retrieval trials (that do not result in significant extinction) lead to this phenomenon. In contrast, many trials (that result in significant extinction) combined with a protein synthesis inhibitor result in an inhibition of the extinction memory. Based on these findings it was suggested that extinction is the boundary condition for reconsolidation: when extinction is induced the consolidation of the extinction memory is the dominant process. Recently we were not able to confirm this hypothesis in the honeybee (Apis mellifera): We did not find the reconsolidation phenomenon after one retrieval trial, but demonstrated reconsolidation after five retrieval trials that led to extinction. To exclude that this observation resembles a special case in insects we here wanted to know if one retrieval trial induces reconsolidation as it has been demonstrated before in many other species. To do so we used experimental parameters that had been used before to demonstrate consolidation in the honeybee with the exception that this time the protein synthesis-inhibitor was applied 1 h after one memory retrieval instead after acquisition. We thereby demonstrate the reconsolidation phenomenon after one retrieval trial but only when using the doubled dose of protein synthesis-inhibitor that has been used to inhibit consolidation.     

Infusion of protein synthesis inhibitors in the entorhinal cortex blocks consolidation but not reconsolidation of object recognition memory

Memory consolidation and reconsolidation require the induction of protein synthesis in some areas of the brain. Here, we show that infusion of the protein synthesis inhibitors anisomycin, emetine and cycloheximide in the entorhinal cortex immediately but not 180 min or 360 min after training in an object recognition learning task hinders long-term memory retention without affecting short-term memory or behavioral performance. Inhibition of protein synthesis in the entorhinal cortex after memory reactivation involving either a combination of familiar and novel objects or two familiar objects does not affect retention. Our data suggest that protein synthesis in the entorhinal cortex is necessary early after training for consolidation of object recognition memory. However, inhibition of protein synthesis in this cortical region after memory retrieval does not seem to affect the stability of the recognition trace.