"Scientists have known for a long time that inflammation is a driver of Alzheimer's disease, but inflammation is complex and involves many factors," said School of Biological Sciences Dean Frank M. LaFerla, Ph.D., whose laboratory conducted the research. "That's why we decided to look at TOM-1."
The protein helps to regulate a key component of the inflammatory response. "We were interested in TOM-1 because its levels are low in the Alzheimer's brain and in the brains of Alzheimer's rodent models," said Alessandra C. Martini, Ph.D., the paper's first author and a postdoctoral researcher who worked with Dean LaFerla. "However, its specific role in the disease has largely been unexplored."
The scientists discovered that reducing the amount of TOM-1 in Alzheimer's rodent models increased pathology, which included increased inflammation, and exacerbated cognitive problems associated with the disease. Restoring TOM-1 levels reversed those effects.
"You can think of TOM-1 as being like the brakes of a car and the brakes aren't working for people with Alzheimer's," Dean LaFerla said. "This research shows that fixing the brakes at the molecular level could provide an entirely new therapeutic avenue. With millions of people affected by Alzheimers and the numbers growing, we must research a diverse portfolio of approaches so we can one day vanquish this terrible disease."
Alessandra Cadete Martini, Angela Gomez-Arboledas, Stefania Forner, Carlos J Rodriguez-Ortiz, Amanda McQuade, Emma Danhash, Jimmy Phan, Dominic Javonillo, Jordan-Vu Ha, Melanie Tram, Laura Trujillo-Estrada, Celia da Cunha, Rahasson R Ager, Jose C Davila, Masashi Kitazawa, Mathew Blurton-Jones, Antonia Gutierrez, David Baglietto-Vargas, Rodrigo Medeiros, and Frank M LaFerla.
Amyloid-beta impairs TOM1-mediated IL-1R1 signaling.
PNAS first published September 30, 2019. doi: 10.1073/pnas.1914088116.