To the brain, it makes a great difference whether we remember experiences from long ago, or if we recollect recent events. RUB neuroscientists have shown that distinct brain networks are involved.

When we remember events that occurred recently, the hippocampus is activated. This area in the temporal lobe of the brain is a hub for learning and . But what happens if we try to remember things that took place years or decades ago? Neuroscientists at the Ruhr-University Bochum and the Osaka University offer some answers to this question. They reveal that the neural networks involved in retrieving very old memories are quite distinct from those used to remember recent events. The results of the study have now been published in the open source science journal eLIFE.

Hippocampus is a hub for memory

Neuroscientists agree that the hippocampus, which contains the cornu ammonis regions 1 and 3 (CA1 and CA3), plays a major role in retrieving recent memories. However, a major controversy in memory research resides on whether the hippocampus is also engaged when experiences date back half a lifetime or whether this is the role of the parahippocampal region of the brain: the cortical areas directly adjacent to the hippocampus. Prof. Dr. Magdalena Sauvage and her team of neuroscientists have monitored brain activity in mice during the retrieval of memories that are one day to one year old – e.g., up to the mouse equivalent of 40 human years. For their study, they applied a high-resolution molecular imaging technique that detects the expression of a particular gene tied to plasticity processes, thus shedding light on cognitive processes.

Old and recent memories are retrieved differently

"For the very first time we were able to show that the retrieval of old and recent memories are supported by distinct brain networks", Prof. Dr. Magdalena Sauvage reports. The CA3 region, believed to be a site of memory storage in the hippocampus, no longer plays a role when we remember very old memories. Rather, the involvement of the CA1 region persists and the adjacent to the become involved. The reason for the differential involvement of the hippocampal subregions could lie in the mechanisms supported by CA3, explains Prof. Sauvage: "In CA3, memories can be retrieved on the basis of single features of an original memory, which are used as cues. Since the memory for single features degrades over time, we speculate that they might ultimately be of no more use as cues, hence retrieving memory would then essentially rely on CA1 and other processes taking place in the parahippocampal region of the ."

More information: Vanessa Lux et al. Imaging a memory trace over half a life-time in the medial temporal lobe reveals a time-limited role of CA3 neurons in retrieval, eLife (2016). DOI: 10.7554/eLife.11862

Journal information: eLife