News Release

Mount Sinai researchers detail mechanism of a key protein implicated in age-related brain dysfunction

Peer-Reviewed Publication

The Mount Sinai Hospital / Mount Sinai School of Medicine

Castellano TIMP2

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Accumulation of extracellular matrix content in brain of TIMP2-deficient "KO" mice (left column) that leads to impaired plasticity processes, including the migration of adult-born neurons (right column). 

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Credit: Mount Sinai Health System

Mount Sinai researchers have shed valuable light on the mechanism of a key protein that regulates the plasticity and function of the hippocampus, a key brain region involved in memory and learning, and that decreases with age in mice.

The team’s findings, published in Molecular Psychiatry, could pave the way for a better understanding of how the protein, known as tissue inhibitor of metalloproteinases 2 (TIMP2), could potentially be targeted in age-related disorders like Alzheimer’s disease to help restore affected molecular processes in the brain.

Aging is known to be the top risk factor for many neurodegenerative disorders, including Alzheimer’s disease. Previous work by Mount Sinai researchers and others found that proteins that are enriched in young blood, including TIMP2, could be harnessed to rejuvenate brain function in aged animals by affecting plasticity—or the flexibility of neural processes related to memory—in the hippocampus. Despite that important discovery, little was known about the biology of how TIMP2 regulates plasticity of the hippocampus at the molecular level.

“In our latest study, we detailed a molecular link involving this protein that ties processes of plasticity, including the generation of new neurons in adulthood, to the structural nature—or what we call the extracellular matrix—of the hippocampal microenvironment,” says Joseph Castellano, PhD, Assistant Professor of Neuroscience, and Neurology, at the Icahn School of Medicine at Mount Sinai and senior author of the paper. “TIMP2 controls these processes by changing the flexibility of the microenvironment through components of the extracellular matrix. Studying pathways that regulate the extracellular matrix could be important for designing novel therapies for diseases in which plasticity is affected.”

For their work, the team used a mutant mouse model mimicking the loss of TIMP2 levels in the blood and hippocampus that is known to occur with age. The team also created a model that allowed researchers to specifically target and delete the pool of TIMP2 expressed by neurons in the hippocampus. These models, in combination with RNA sequencing, confocal imaging, super-resolution microscopy, and behavioral studies, allowed for a detailed molecular examination of TIMP2’s regulation of plasticity.

The researchers, including first author Ana Catarina Ferreira, PhD, a postdoctoral fellow in Dr. Castellano’s group, learned that the loss of TIMP2 results in an accumulation of extracellular matrix components in the hippocampus that occurs alongside a reduction in plasticity processes, including the generation of adult-born neurons, synaptic integrity, and memory. The extracellular matrix is a network of many macromolecular components that make up the structural microenvironment around and between cells.

“We directly targeted this phenotype with an enzyme delivered to the hippocampus that affects the extracellular matrix and found that plasticity processes normally impaired in the setting of reduced TIMP2 were now restored,” notes Dr. Castellano. “This finding has important implications for fundamentally understanding how plasticity is regulated at the structural level in brain regions involved in memory.”

Overall, the findings suggest that targeting processes that regulate the extracellular matrix may be an important direction for designing approaches that improve plasticity in the brain. Dr. Castellano, whose lab is focused on characterizing factors with the potential to reverse features of brain aging, plans to explore molecules beyond TIMP2 that regulate the extracellular matrix, and is optimistic about where this research may take the field in the context of mitigating a variety of disorders associated with aging.

The study was supported by funding from the National Institutes of Health, National Institute on Aging (R01AG061382, RF1AG072300, T32AG049688).

About the Mount Sinai Health System
Mount Sinai Health System is one of the largest academic medical systems in the New York metro area, with more than 43,000 employees working across eight hospitals, more than 400 outpatient practices, more than 300 labs, a school of nursing, and a leading school of medicine and graduate education. Mount Sinai advances health for all people, everywhere, by taking on the most complex health care challenges of our time—discovering and applying new scientific learning and knowledge; developing safer, more effective treatments; educating the next generation of medical leaders and innovators; and supporting local communities by delivering high-quality care to all who need it.

Through the integration of its hospitals, labs, and schools, Mount Sinai offers comprehensive health care solutions from birth through geriatrics, leveraging innovative approaches such as artificial intelligence and informatics while keeping patients’ medical and emotional needs at the center of all treatment. The Health System includes approximately 7,400 primary and specialty care physicians; 13 joint-venture outpatient surgery centers throughout the five boroughs of New York City, Westchester, Long Island, and Florida; and more than 30 affiliated community health centers. Hospitals within the System are consistently ranked by Newsweek’s® “The World’s Best Smart Hospitals” and by U.S. News & World Report's® “Best Hospitals” and “Best Children’s Hospitals.” The Mount Sinai Hospital is on the U.S. News & World Report® “Best Hospitals” Honor Roll for 2023-2024.

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