Abstract
The neocortex plays a critical role in the gradual formation and storage of remote declarative memories. Because the circuitry mechanisms of systems-level consolidation are not well understood, the precise cortical sites for memory storage and the nature of enduring memory correlates (mnemonic plasticity) are largely unknown. Detailed maps of neuronal activity underlying recent and remote memory recall highlight brain regions that participate in systems consolidation and constitute putative storage sites, and thus may facilitate detection of mnemonic plasticity. To localize cortical regions involved in the recall of a spatial memory task, we trained rats in a water-maze and then mapped mRNA expression patterns of a neuronal activity marker Arc/Arg3.1 (Arc) upon recall of recent (24 h after training) or remote (1 month after training) memories and compared them with swimming and naive controls. Arc gene expression was significantly more robust 24 h after training compared to 1 month after training. Arc expression diminished in the parietal, cingulate and visual areas, but select segments in the prefrontal, retrosplenial, somatosensory and motor cortical showed similar robust increases in the Arc expression. When Arc expression was compared across select segments of sensory, motor and associative regions within recent and remote memory groups, the overall magnitude and cortical laminar patterns of task-specific Arc expression were similar (stereotypical). Arc mRNA fractions expressed in the upper cortical layers (2/3, 4) increased after both recent and remote recall, while layer 6 fractions decreased only after the recent recall. The data suggest that robust recall of remote memory requires an overall smaller increase in neuronal activity within fewer cortical segments. This activity trend highlights the difficulty in detecting the storage sites and plasticity underlying remote memory. Application of the Arc maps may ameliorate this difficulty.
Highlights
The representation of declarative memories in the brain determined by mapping, lesion and inactivation studies changes over the time (Frankland and Bontempi, 2005; Squire and Bayley, 2007)
For a spatial memory task such as the water-maze (WM), the expansion of memory representation into the neocortex occurs within 7–10 days after completion of training (Frankland et al, Abbreviations: WM, water-maze; WMT, water-maze trained; swim control (SW), swimming control; IEG, immediate-early gene; Arc, activity-regulated cytoskeleton-associated; Cg1 and cingulate cortex and 2 (Cg2), cingulate cortex 1 and 2; RS, retrosplenial, Ins, insular cortices; MO, medial orbital; VO, ventral orbital cortex; DLO, dorso-lateral orbital cortex; parietal association (Par), visual primary (V1) and secondary medial and lateral (V2M; V2L) cortices; somatosensory and motor primary and secondary cortices (S1, S2, M1, M2, respectively); FrAs, frontal association; prelimbic (Prl) and lateral orbital (LO) cortices; LEA, lateral entorhinal area; L, layer; ROI, region of interest. 2001; Remondes and Schuman, 2004; Teixeira et al, 2006)
We found that the main trend in global reorganization of neuronal activity induced by memory recall in the cerebral cortex parallels the changes we described previously for the hippocampus (Gusev et al, 2005)
Summary
The representation of declarative memories in the brain determined by mapping, lesion and inactivation studies changes over the time (Frankland and Bontempi, 2005; Squire and Bayley, 2007). While the hippocampus plays a critical role in memory acquisition and its early retention, or may even be persistently involved in memory representation (for reference see Lehmann et al, 2007), the neocortex is critical for the gradual formation and further storage of remote memories. This transition in memory representation reflects systems-level memory consolidation the mechanisms of which are largely unknown. Neurons active during memory recall might highlight storages sites that express mnemonic plasticity. The stereotypical or well-ordered organization of memory-related activity could facilitate detection of enduring storage correlates because it could point to the most common storage sites across the entire cortex
Sign-in/Register to view highlights & summary 
Published Version (
Free)
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call