Recent memory for socially transmitted food preferences in rats does not depend on the hippocampus.

The standard model of systems consolidation holds that the hippocampus (HPC) is involved only in the initial storage and retrieval of a memory. With time hippocampal-neocortical interactions slowly strengthen the neocortical memory, ultimately enabling retrieval of the memory without the HPC. Key support for this idea comes from experiments measuring memory recall in the socially-transmitted food preference (STFP) task in rats. HPC damage within a day or two of STFP learning can abolish recall, but similar damage five or more days after learning has no effect. We hypothesize that disruption of cellular consolidation outside the HPC could contribute to the amnesia with recent memories, perhaps playing a more important role than the loss of HPC. This view predicts that intraHPC infusion of Tetrodotoxin (TTX), which can block conduction of action potentials from the lesion sites, will block the retrograde amnesia in the STFP task. Here we confirm the previously reported retrograde amnesia with neurotoxic HPC damage within the first day after learning, but show that co-administration of TTX with the neurotoxin blocks the retrograde amnesia despite very extensive HPC damage. These results indicate that HPC damage disrupts cellular consolidation of the recent memory elsewhere; STFP memory may not ever depend on the HPC.

Temporary inactivation of the rodent hippocampus: an evaluation of the current methodology.

Temporary cellular inactivation is a useful and increasingly popular approach in examining brain function. In general the methods allow for fast-acting manipulations that have the advantage of being reversible. However, there is significant variation in detailed procedures across experiments and most authors show very little evidence about the extent or duration of inactivation. Here we investigate a commonly used method of temporarily inactivating the hippocampus in rats. Using immediate early gene activation after electroconvulsive shock we measure the extent of inactivation using different lengths of infusion needles and one vs. two bilateral infusion sites. Our methods allowed us to uncover some possible confounding factors. We suggest specific variations in the procedures which decrease or eliminate these problems. We also investigate the properties of the sodium channel blocker ropivacaine and recommend this drug based on its functional profile and established low level of toxicity.

Interfering with post-learning hippocampal activity does not affect long-term consolidation of a context fear memory outside the hippocampus.

There are still uncertainties about the role of the hippocampus (HPC) in memory consolidation. One theory, systems consolidation, states that the HPC is required for the initial storage of certain memories that subsequently become established in non-HPC networks through a lengthy process, involving an interaction with the HPC. A similar process may underlie the ability of multiple, distributed learning episodes of contextual fear conditioning to create a HPC-independent context fear memory, in a memory task that does not undergo systems consolidation with the mere passage of time [5]. The current study examined whether post-learning HPC activity is necessary to establish these HPC-independent context memories through distributed learning episodes. Rats received either three or six context conditioning sessions over the course of three days. The HPC-dependence of context memories was assessed using multisite, temporary inactivation of the HPC using ropivacaine during retention testing. We established that six conditioning sessions, but not three, created a memory that could be retrieved while the HPC was inactive. To directly test our hypothesis, HPC was inactivated after half of the six context-shock pairings in an independent group of rats. The rats were then tested for retention of context fear in the absence of HPC activity. Post-learning inactivation of the HPC did not affect the establishment of a HPC-independent context memory. These results favor the idea that at least one memory system outside the HPC can acquire context memories independently.