CMU researchers awarded $3 million NIH grant to tackle Alzheimer’s disease and beyond

A major boost in the fight against Alzheimer’s disease and other neurodegenerative disorders is underway, thanks to a $3,027,155 NIH grant awarded to a team of researchers at Central Michigan University and the University of Florida. The project focuses on uncovering the complex relationship between two key proteins, TDP-43 and Tau, and how their dynamic interactions contribute to disease.

Dr. Michelle Steinhilb from Central Michigan University and Dr. May Khanna from the University of Florida are leading the effort as co-investigators. Dr. Steinhilb’s team will determine the physiological and pathological consequences of TDP-43 and Tau interaction using a fruit fly model system while Dr. Khanna’s lab will focus on the biophysical and molecular intricacies of these protein interactions, with the ultimate goal of developing better treatment options.

Why TDP-43 and Tau Matter

You’ve probably heard of Tau when it comes to Alzheimer’s research, it’s one of the main proteins that’s been linked to the disease. But TDP-43? That name might not be as familiar, even though it plays a role in conditions like Alzheimer’s, ALS, and other neurodegenerative disorders. What’s fascinating, and troubling, is that these two proteins often show up together in diseased brains, but no one really understands why. This project aims to change that.

What the Research Will Do

The study is digging deep into how TDP-43 and Tau interact. Using techniques like nuclear magnetic resonance (NMR) and surface plasmon resonance (a way to study how molecules bind), the team will map out their relationship and look for ways to disrupt harmful interactions.

Even more exciting, they’ll test small molecules and peptides to see if these could break up the “bad” interactions between TDP-43 and Tau, basically, finding new tools to fight the proteins’ harmful effects.

And they’re not stopping there. By using a humanized knock-in disease model, the researchers will study how these proteins behave over a natural lifespan, looking at what happens during normal aging and after injuries. This approach could offer clues that other methods miss, especially since it doesn’t rely on artificially ramping up protein production or adding outside chemicals.

Aiming for Better Treatments

The endgame? Therapies that work better than anything we’ve got now. “Right now, treatment options for neurodegenerative diseases like Alzheimer’s are inadequate,” said Dr. Steinhilb. “Our goal is to identify molecular features in these protein interactions that can be targeted to create truly effective therapeutics.”

If successful, the research could pave the way for groundbreaking treatments that tackle not just the symptoms but the underlying causes of these diseases.

A Collaborative Effort

“This project is a team effort through and through,” said Dr. Steinhilb. “Working with Dr. Khanna and combining our expertise is what makes this possible. We’re optimistic that we can make a real difference.”

With the stakes so high, the research has the potential to transform how we understand and treat neurodegenerative diseases, offering new hope for patients and families affected by Alzheimer’s disease and similar conditions.