Amazing molecule can reverse the effects of concussions

[Nov 1, 2022: Nicole Mlynaryk, University of California San Francisco]


A small molecule called ISRIB that was identified at UC San Francisco can reverse the neuronal and cognitive effects of concussion. (Credit: J. Tsai et al.)


A small molecule called ISRIB that was identified at UC San Francisco can reverse the neuronal and cognitive effects of concussion in mice weeks after an injury occurred, new research has found.


ISRIB blocks the integrated stress response (ISR), a quality control process for protein production that can disrupt the normal function of cells when it is chronically activated.


The study, published in Proceedings of the National Academy of Sciences, found that ISRIB reverses the effects of traumatic brain injury (TBI) on areas of neurons called dendritic spines that are critical to cognition. Mice treated with the drug also showed sustained improvements in working memory.


 
 

“Our goal was to see if ISRIB could ameliorate the neural effects of concussion,” said Michael Stryker, PhD, a co-senior author of the study and professor of physiology at UCSF. “We were pleased to find the drug was tremendously successful in normalizing neuronal and cognitive function with lasting effects.”


TBI is a leading cause of long-term neurological disability, with impairments in concentration and memory affecting patients’ quality of life. It’s also the strongest environmental risk factor for dementia – even a mild concussion significantly increases an individual’s risk.


 

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Reversing the Effects of Concussion


ISRIB was developed in the lab of co-senior author Peter Walter, PhD, who was a professor of biochemistry at UCSF at the time of the study, now emeritus and at Altos Labs. Previous studies demonstrated that the molecule could effectively block the integrated stress response and showed evidence of improving cognition and behavior across different mouse models of TBI.


However, the cellular mechanisms by which ISR inhibition restored cognition remained unknown.


 
 

To investigate this, UCSF graduate student Elma Frias, PhD, began to explore how the ISR and its inhibition affected neurons in the parietal cortex, a brain region involved in working memory.


An image of dendrites showing the dendritic spines (small bumps) essential to communication between neurons. Researchers found that, after a concussion, neurons form an excessive number of these spines, leading to “noisy” signals in the brain that can affect cognition. (Credit: Elma Frias/Stryker Lab)


Using advanced imaging techniques, Frias observed the effects of TBI on dendritic spines, the primary site of excitatory communication between neurons, over the course of multiple days.


 
 

In healthy conditions, neurons show a fairly consistent rate of spine formation, maturation and elimination – dynamics that support learning and memory. But after a single mild concussion, mouse cortical neurons showed a massive burst of newly formed spines and continued to make excessive spines for as long as they were measured.


Cortical spine dynamics are altered by concussive injury and restored by ISR inhibition. (CREDIT: PNAS)


“Some may find this counterintuitive at first, assuming more dendritic spines would be a good thing for making new memories,” said co-senior author Susanna Rosi, PhD, a professor of physical therapy and neurological surgery at UCSF at the time of the study, now also at Altos Labs. “But in actuality, having all too many new spines is like being in a noisy room – when too many people are talking, you can’t hear the information you need.”


 
 

These new spines didn’t stick around for very long, however, and most were removed within days, meaning they hadn’t formed lasting functional synaptic connections.


ISR inhibition normalizes the CHI-induced short-lived newborn spines. (A) A schematic illustrating long- vs. short-lived newborn spines. (B) Number of newly formed spines per dendritic segment. (CREDIT: PNAS)


These aberrant dynamics were rapidly reversed once mice were treated with ISRIB. By blocking the ISR, the drug was able to repair the neuronal structural changes resulting from the brain injury and restore normal rates of spine dynamics. These neuronal structural alterations were also associated with an improvement in performance to normal levels in a behavioral assay of working memory, which persisted for over a month after the final treatment.


 
 

“A month in a mouse is several years in a human, so to be able to reverse the effects of concussion in such a lasting way is really exciting,” said Frias.



Restoring the Brain’s Potential to Heal


The authors suggest that TBI triggers a persistent activation of the ISR, which in turn leads to the ongoing proliferation of transient spines that fail to support memory formation. Future experiments will explore whether ISRIB has similar effects on other cell types, brain areas and cognitive tasks.


ISR activation has been implicated in many neurological disorders, including Alzheimer’s disease, Parkinson’s disease, multiple sclerosis (MS) and amyotrophic lateral sclerosis (ALS). Thus, the researchers believe ISRIB may have therapeutic potential in multiple patient populations.


While there was no evidence of the drug’s toxicity in mice, clinical trials are currently evaluating the safety and effectiveness of ISRIB in humans.


 
 

“This study reminds us that the brain is very plastic; it can be rewired and healed,” said Rosi. “By briefly inhibiting this stress pathway, we may be able to restore healthy synaptic and cognitive function in many neurological conditions.”





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Note: Materials provided above by University of California San Francisco. Content may be edited for style and length.

 
 

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