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Brain 'antifreeze' may stop, reverse injury damage

Journal of Business - 9/28/2018

Molecules halt protein action that causes a cognitive decline

NEWSWISE-The key to better treatments for brain injuries and disease may lie in the molecules charged with preventing the clumping of specific proteins associated with cognitive decline and other neurological problems, researchers from the Perelman School of Medicine at the University of Pennsylvania report in a recent study published in Neurobiology of Disease.

Concentrations of those brain molecules-called N-acetylaspartate, or NAA-are known to decrease when people suffer from brain injuries and diseases. While NAA historically has been used as a marker of disease, its primary role in the brain has remained a mysteiy. Now, Penn neuroscience researchers have shown how NAA wedges in between the folds of amyloid-beta fibrils to inhibit them from locking, folding, and clumping together to create harmful amyloid plaques.

"For decades, NAA has been viewed as simply a marker of injuiy when in fact it could be a part of the rescue process," says senior author Dr. Douglas H. Smith, director of the Center for Brain Injury and Repair and professor of neurosurgery in Penn's Perelman School of Medicine.

"We found that it's a type of brain 'antifreeze' that works to pause and even reverse the aggregation or misfolding of amyloid-beta proteins, which occurs after a brain injury." Smith says, "In this way, it may protect the brain."

NAA is one of the most abundant amino acids in the brain and has the highest concentration in neurons. After a traumatic brain injuiy, scans from proton magnetic resonance spectroscopy consistently show an approximately 20 percent reduction in NAA in patients' white matter, the authors note. This is followed by the rapid clumping of amyloid-beta proteins to form amyloid plaques, which are found in a large number of patients who die shortly after suffering a traumatic brain injury-similar to the hallmark pathology of Alzheimer's disease.

A number of strategies to reduce amyloid-beta aggregation, such as immunotherapy and beta secretase inhibitors, have been attempted over the years, but none of them have proved to be clinically successful, the researchers assert. This new study suggests that restoring NAA to normal levels after head trauma or in neurological diseases, like Alzheimer's, could block the progression of amyloid pathologies.

Using human amyloid-beta samples in the lab, the team demonstrated that concentrations of NAA substantially impaired amyloid-beta clumping. It's possible NAA is creating "peptide backbones," the authors say. The NAA inserts itself between layers of amyloid-beta clumps and protofibrils, preventing the formation of mature amyloid fibrils. The researchers used several different techniques to determine NAA's role, including a dye fluorescence, which is used regularly to quantify the formation and inhibition of amyloids.

Electron microscopy also confirmed the absence of mature fibrils following the NAA treatment. The NAA may be stabilizing the smaller fibrils and preventing further organization into elongated, more mature ones, the authors speculated.

The researchers also showed that the addition of NAA can even reverse the clumping. After 25 minutes, NAA added to the amyloid-beta aggregation started to break down the preformed amyloid fibrils. This work may have important implications for the treatment of traumatic brain injuries and neurodegenerative disorders.

"We show a new and potentially significant biological function of NAA in the brain, as a surprisingly effective agent for inhibiting and even reversing aggregation of amyloid-beta," says lead author Jean-Pierre Dollé, of the Penn Center for Brain Injury and Repair. This tells us a lot about brain injuiy and neurodegeneration, and points us to possible therapies to stop it. These findings support the start of a new line of research to reveal potential mechanisms of NAA interactions with amyloid-beta in patients."

Penn Medicine is an academic medical center dedicated to the related missions of medical education, biomedical research, and excellence in patient care.

 
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