This gene could play a major role in reducing brain swelling after stroke

Could a medication someday help the brain heal itself after a stroke, or even prevent damage following a blow to the head? A new USC study lends support to the idea.

When a person has a stroke, the brain responds with inflammation, which expands the area of injury and leads to more disability. In the April 9 issue of Cell Reports, USC researchers describe a key gene involved with tamping down inflammation in the brain, as well as what happens when the injured brain gets an added boost of that gene.

The gene -- called TRIM9 -- is abundant in the youthful brain but grows scarce with age, just as people become more at risk from stroke. In a lab model of stroke, researchers found that older brains with low TRIM9 levels -- or engineered brains missing the TRIM9 gene entirely -- were prone to extensive swelling following stroke.

But when the scientists used a harmless virus to carry a dose of the gene directly into TRIM9-deficient brains, the swelling decreased dramatically and recovery improved.

Jae Jung, lead author and chair of the Department of Molecular Microbiology and Immunology at the Keck School of Medicine of USC, says it's unlikely that gene therapy delivered by viruses will become the go-to treatment for strokes, head injuries or encephalitis. It's too slow, he said, and the best shot at treating stroke is within the first 30 minutes to one hour. Jung says the next step will be identifying what, exactly, flips on the switch for TRIM9 gene expression.

"Maybe there will be a way to chemically activate TRIM9 right after a stroke," Jung said. "Or maybe a football player can take a medication that turns on TRIM9 gene expression right after they get a blow to the head."

Not all inflammation in the brain is bad, Jung added. Inflammation plays a role in fighting infection and helps clear away dead tissue. But when it goes on too long, neurons die; inflammation causes the brain's blood vessels to become permeable, allowing white blood cells to enter tissue where they don't belong.

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In addition to Jung, the paper's other authors are Berislav Zlokovic and Zhen Zhao of the Zilkha Neurogenetic Institute at the Keck School; co-first authors Jianxiong Zeng and Yaoming Wang, Zhifei Luo Lin-Chun Chang, Ji Seung Yoo, Huan Yan, Younho Choi and Xiaochun Xie, all of the Keck School; Benjamin Deverman and Viviana Gradinaru of the California Institute of Technology; and Stephanie Gupton of the University of North Carolina at Chapel Hill.

The study was supported by the National Institutes of Health (grants CA200422, CA180779, DE023926, DE027888, DE28521, AI073099, AI116585, AI129496, AI140718, 9R01NS090904-16 and AI140705), the Hastings Foundation, the Fletcher Jones Foundation, the Alzheimer's Association (grant NIRG-15-363387), the Whittier Foundation, the Cure for Alzheimer's Fund (NS090904), Fondation Leducq Transatlantic Network of Excellence for the Study of Perivascular Spaces in Small Vessel Disease (reference 16 CVD 05 and GM108970), the Beckman Institute at Caltech through the Resource Center for CLARITY, Optogenetics and Vector Engineering, and an NIH Director's New Innovator Award (DP20D017782).

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