Neuroscientists Discover Brain Mechanism Tied to Age-Related Memory Loss

Human Brain Memories Neurons

Johns Hopkins neuroscientists have pinpointed a mechanism in the brain responsible for a common type of age-related memory loss.

As the brain ages, a region in the hippocampus becomes imbalanced, causing forgetfulness. Researchers say understanding this region of the brain and its function may be the key to preventing cognitive decline.

Working with rats, neuroscientists at Johns Hopkins University have identified a mechanism in the brain responsible for a common type of age-related memory loss. The work, published on May 202, 2022, in the journal Current Biology, provides new insight on the workings of aging brains and may deepen our understanding of Alzheimer’s disease and similar disorders in humans.

“We’re trying to understand normal memory and why a part of the brain called the hippocampus is so critical for normal memory,” said senior author James Knierim, a professor at the university’s Zanvyl Krieger Mind/Brain Institute. “But also with many memory disorders, something is going wrong with this area.”

Neuroscientists know that neurons in the hippocampus, located deep in the brain’s temporal lobe, are responsible for a complementary pair of memory functions called pattern separation and pattern completion. These functions occur in a gradient across a tiny region of the hippocampus called CA3.

“We’re trying to understand normal memory and why a part of the brain called the hippocampus is so critical for normal memory. But also with many memory disorders, something is going wrong with this area.” — James Knierim, Mind/Brain Institute

When those functions swing out of balance, memory becomes impaired, causing symptoms like forgetfulness or repeating oneself. The Johns Hopkins researchers discovered that as the brain ages, this imbalance may be caused by the CA3 gradient disappearing; the pattern separation function fades away, and the pattern completion function takes over.

Neurons responsible for pattern separation are typically more prevalent in the proximal region of the CA3 area, while those responsible for pattern completion are prevalent in the distal region, said lead author Heekyung Lee, an assistant research scientist at the Mind/Brain Institute, With aging, neural activity in the proximal region becomes overactive, and the interplay between the two regions becomes abnormal, creating a dominance in pattern completion.

In normal brains, pattern separation and pattern completion work hand-in-hand to sort and make sense of perceptions and experiences, from the most basic to the highly complex. If you visit a restaurant with your family and a month later you visit the same restaurant with friends, you should be able to recognize that it was the same restaurant, even though some details have changed—this is pattern completion. But you also need to remember which conversation happened when, so you do not confuse the two experiences—this is pattern separation.

When pattern separation disappears, pattern completion overpowers the process. With your brain focusing on the common experience of the restaurant to the exclusion of the details of the separate visits, you might remember a conversation about a trip to Italy during one visit, but mistake who was talking. “We all make these mistakes, but they just tend to get worse with aging,” Knierim said.

In experiments, the scientists compared young rats with unimpaired memories to older rats with unimpaired memories and older rats with impaired memories. While the older rats with unimpaired memories performed water maze tasks as well as young rats, the neurons in the CA3 regions of their hippocampi were already beginning to favor pattern completion at the expense of pattern separation. Since that physiological finding had not shown up in their behavior, the researchers concluded that something was allowing the rats to compensate for the deficit.

That finding is echoed in humans who remain surprisingly sharp into their older years, the researchers say. So pinpointing the memory loss mechanism could lay the groundwork for learning what prevents memory impairment in some humans, and therefore how to prevent or delay cognitive decline in the elderly.

“If we can understand better what these compensatory mechanisms are, then maybe we can help prevent cognitive decline with aging,” Knierim said. “Or, if we can’t stop it, maybe we can enhance other parts of the brain to compensate for the losses that are occurring.”

Other senior authors of the paper were Michela Gallagher, Krieger-Eisenhower Professor of Psychology and Neuroscience at Johns Hopkins, and Scott Zeger, professor of biostatistics at Johns Hopkins’ Bloomberg School of Public Health. Gallagher’s lab previously demonstrated that the anti-epilepsy drug Levetiracetam improves memory performance by reducing hyperactivity in the hippocampus. So Lee also speculates that this new, more specific information about how memory impairment occurs might allow scientists to better aim such drugs toward the deficits in the future.

“It would give us better control of where we could possibly target the deficits that we see,” she said.

Reference: “Loss of functional heterogeneity along the CA3 transverse axis in aging” by Heekyung Lee, Zitong Wang, Arjuna Tillekeratne, Nick Lukish, Vyash Puliyadi, Scott Zeger, Michela Gallagher and James J. Knierim, 20 May 2022, Current Biology.
DOI: 10.1016/j.cub.2022.04.077

The paper’s other co-authors were Zitong Wang, Arjuna Tillekeratne, Nick Lukish, and Vyash Puliyadi, all of Johns Hopkins.

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