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Summary: A new study shows that our brains physically link memories formed close together in time through changes in the dendrites of neurons, rather than in the cell bodies. Using advanced imaging in mice, researchers found that the same dendritic branches are activated when closely timed experiences are encoded, effectively binding the memories.
This discovery explains why events from the same day often feel connected, while those from weeks apart seem more isolated. The findings offer new insight into how memories are organized and may inform therapies for memory-related disorders like Alzheimer’s.
Key Facts:
- Dendritic Memory Linking: Memories formed close in time are stored in the same dendritic branches, creating physical links between them.
- Experimental Validation: Mice exposed to two environments in quick succession linked them behaviorally, freezing in both after a shock in just one.
- Therapeutic Potential: Understanding dendritic memory encoding could lead to new approaches for treating memory-related disorders.
Source: Ohio State University
If you’ve ever noticed how memories from the same day seem connected while events from weeks apart feel separate, a new study reveals the reason: Our brains physically link memories that occur close in time not in the cell bodies of neurons, but rather in their spiny extensions called dendrites.
This discovery stems from studies in mice, in which researchers observed memory formation using advanced imaging techniques, including miniature microscopes that captured single-cell resolution in live animals.
The study shows that memories are stored in dendritic compartments: When one memory forms, the affected dendrites are primed to capture new information arriving within the next few hours, linking memories formed close in time.
“If you think of a neuron as a computer, dendrites are like tiny computers inside it, each performing its own calculations,” said lead author Megha Sehgal, assistant professor of psychology at The Ohio State University.
“This discovery shows that our brains can link information arriving close in time to the same dendritic location, expanding our understanding of how memories are organized.”
The research was published recently in the journal Nature Neuroscience.
Though most learning and memory studies have focused on how a single memory is formed in the brain, Sehgal’s lab aims to determine how we organize multiple memories.
“The idea is that we don’t form memories in isolation. You don’t form a single memory. You use that memory, make a framework of memories, and then pull from that framework when you need to make adaptive decisions,” she said.
Neurons, the principal brain cells, are known to encode and relay information. Dendrites – the branch-like projections extending from neurons – serve a critical role in how information is processed, receiving incoming information and passing it to the neuronal cell body.
But dendrites are not just passive conduits – each dendritic branch can act as an independent computational unit. While dendrites have been thought to play an important role in the brain’s function, how they shape learning and memory has been unclear until now, Sehgal said.
When mice were exposed in experiments to two different environments within a short period of time, the team found that memories of these spaces became linked. If mice received a mild shock in one of these spaces, the animals ended up freezing out of fear in both environments, associating the shock from one room with the other.
The study focused on the retrosplenial cortex (RSC), a brain region crucial for spatial and contextual memory. The researchers observed that linked memories consistently engaged the same groups of RSC neurons and their dendritic branches.
The team tracked these changes at the dendritic level by visualizing dendritic spines, tiny protrusions on dendrites where neurons communicate.
The formation of new memories triggered the addition of clustered dendritic spines, a process critical for strengthening communication between neurons and facilitating learning.
Dendritic spine clusters formed after the first memory were more likely to attract new spines during a second closely timed memory, physically linking those experiences in the brain.
To confirm the role of dendrites in linking memories, the team used optogenetics, a technique that allows researchers to control neurons with light. By reactivating specific dendritic segments that had been active during memory formation, they were able to link otherwise unrelated memories, further demonstrating the importance of dendritic changes in shaping memory networks.
In addition to illuminating a previously unknown role for dendrites in linking memories, the findings open new avenues for understanding memory-related disorders, Sehgal said.
“Our work not only expands our understanding of how memories are formed but also suggests exciting new possibilities for manipulating higher order memory processes,” she said.
“This could have implications for developing therapies for memory-related conditions such as Alzheimer’s disease.”
Sehgal co-led the study with Alcino Silva, director of the Integrative Center for Learning and Memory at UCLA, and Panayiota Poirazi, research director of the Foundation for Research and Technology-Hellas in Greece.
Funding: This work was supported by the National Institute of Mental Health, the National Institute on Aging, the Dr. Miriam and Sheldon G. Adelson Medical Research Foundation, the European Commission, the National Institutes of Health and the Einstein Foundation Berlin.
About this memory and neuroscience research news
Author: Emily Caldwell
Source: Ohio State University
Contact: Emily Caldwell – Ohio State University
Image: The image is credited to Neuroscience News
Original Research: Open access.
“Compartmentalized dendritic plasticity in the mouse retrosplenial cortex links contextual memories formed close in time” by Megha Sehgal et al. Nature Neuroscience
Abstract
Compartmentalized dendritic plasticity in the mouse retrosplenial cortex links contextual memories formed close in time
Events occurring close in time are often linked in memory, and recent studies suggest that such memories are encoded by overlapping neuronal ensembles. However, the role of dendritic plasticity mechanisms in linking memories is unknown.
Here we show that memory linking is dependent not only on neuronal ensemble overlap in the mouse retrosplenial cortex, but also on branch-specific dendritic allocation mechanisms.
The same dendritic segments are preferentially activated by two linked (but not independent) contextual memories, and spine clusters added after each of two linked (but not independent) contextual memories are allocated to the same dendritic segments.
Importantly, we show that the reactivation of dendrites activated during the first context exploration is sufficient to link two contextual memories.
Our results demonstrate a critical role for localized dendritic plasticity in memory integration and reveal rules governing how linked and independent memories are allocated to dendritic compartments.
