Scientists find promising avenue to restore cognitive function impaired by Alzheimer's disease

Scientists find promising avenue to restore cognitive function impaired by Alzheimer's disease
The compound ISRIB shrank plaques in the brain in a mouse model of Alzheimer’s disease (right, rectangle). Credit: M.M. Oliveira et al., Science Signaling (2021)

A team of neuroscientists has identified a potential means to address the loss of cognitive function due to Alzheimer's disease by targeting protein synthesis in mice. Their findings, reported in the journal Science Signaling, reveal that synthetic pharmaceuticals could rescue the activity of brain cells needed for memory formation.

"This work is the first to show that reversing impaired in brains afflicted by Alzheimer's disease through a pharmacological approach is not only feasible, but also effective," explains Mauricio Martins-Oliveira, a postdoctoral researcher at New York University's Center for Neural Science and the paper's lead author.

Currently, treatments for Alzheimer's disease center on the reduction of phenomena linked to the affliction, such as amyloid plaque load, , and neuroinflammation; the Science Signaling study suggests that the addition of a pharmaceutical normalizing synthesis could aid in reviving normal activity.

"The synthesis of new proteins in the brain is essential for proper neuronal function and, notably, for . We and others have previously shown that impairments in brain protein synthesis contribute memory deficits in Alzheimer's disease model mice, and that the brains of Alzheimer's patients exhibit clear signs of impaired protein synthesis. We thus asked ourselves whether rescuing brain protein synthesis might be an approach to improve memory function in Alzheimer's disease," said co-senior author Sergio Ferreira, a professor at the Institute of Biophysics at Brazil's Federal University of Rio de Janeiro (UFRJ).

"Given the complex nature of Alzheimer's disease, identifying and targeting abnormal molecular pathways that effectively improve cognition has been challenging," adds co-senior author Eric Klann, a professor in NYU's Center for Neural Science. "Our findings show that jump-starting protein synthesis in the brain can revive lost cognitive functions. We hope that this work can serve as a step forward in treating this devastating disease."

The study centered on ISRIB, a synthetic molecule capable of boosting protein synthesis. Developed by Peter Walter at the University of California, San Francisco, ISRIB specifically targets the process of translation initiation—the translation of genetic codes—ultimately stimulating cellular protein synthesis, or the production of proteins.

The NYU and UFRJ researchers sought to determine if ISRIB could restore synaptic plasticity—the ability of the brain to change in order to learn—and memory. Previously, they had shown that translation initiation is impaired in Alzheimer's brains, leading the team to hypothesize that ISRIB could work to re-establish some cognitive functions.

After establishing that key components of the protein synthesis machinery are depleted in the hippocampus—a brain structure known to play a significant role in memory—of Alzheimer's disease patients, the scientists concluded that protein synthesis may also be impaired.

They then tested whether ISRIB could rescue the memory of mice with Alzheimer's-like conditions by administering a series of memory tests (e.g., navigating a maze). Here, they found that ISRIB could indeed restore the memory functions in these mice as well as protein synthesis in the hippocampus.

They also examined whether ISRIB could restore the hippocampal functions and cognition in mice with fully developed Alzheimer's-like afflictions, mimicking the disease at its more advanced stages. Similarly, their results showed that ISRIB could restore in the hippocampus, as well as memory functions.

Taken together, the researchers' findings indicated that restoring protein , aided by synthetic molecules—in this case, ISRIB—could work to restore cognitive processes impaired by Alzheimer's disease.


Explore further

Abnormal proteins in the gut could contribute to the development of Alzheimer's disease

More information: "Correction of eIF2-dependent defects in brain protein synthesis, synaptic plasticity, and memory in mouse models of Alzheimer's disease," stke.sciencemag.org/lookup/doi … 26/scisignal.abc5429
Journal information: Science Signaling

Citation: Scientists find promising avenue to restore cognitive function impaired by Alzheimer's disease (2021, February 2) retrieved 4 March 2021 from https://medicalxpress.com/news/2021-02-scientists-avenue-cognitive-function-impaired.html
This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no part may be reproduced without the written permission. The content is provided for information purposes only.
402 shares

Feedback to editors

User comments