Researchers have discovered how a surface protein on brain cells, called Aplp1, can play a role in spreading material responsible for Parkinson’s disease from cell to cell in the brain.

Promisingly, an FDA-approved cancer drug that targets another protein – Lag3 – which interacts with Aplp1 – was found to block this process in mice. This suggests a potential treatment for Parkinson’s may already exist.

In a paper published last year, an international team of scientists detailed how the two proteins work together to help toxic clumps of alpha-synuclein protein get into brain cells.

A large international study involving nearly 700 participants reveals that women with a precursor condition to Parkinson’s disease show significantly less brain atrophy—decreased cortical thickness in the brain—than men, despite similar clinical severity. This discovery, published in the journal Nature Communications, could lead scientists to explore the role that hormones might play in treating the disease.

Isolated REM sleep behavior disorder is characterized by violent movements during sleep, where people literally “act out” their dreams. Far from being harmless, this disorder is the most reliable early warning sign of neurodegenerative diseases caused by the accumulation of a toxic protein in the brain: more than 70% of affected individuals will eventually develop Parkinson’s disease, Lewy body dementia, or, more rarely, multiple system atrophy (a disease affecting multiple body systems).

“This sleep disorder offers a unique window of opportunity to study the mechanisms of neurodegeneration before major motor or cognitive symptoms appear,” explains Shady Rahayel, professor at UdeM’s Faculty of Medicine and leader of this study.

A new study led by Rice University’s Pernilla Wittung-Stafshede has revealed that protein clumps, or plaques that clog the brain, associated with Parkinson’s disease are not merely waste; they can actively drain energy from brain cells. These clumps, composed of a protein called alpha-synuclein, were found to break down adenosine triphosphate (ATP), the molecule responsible for powering nearly all cellular activities.

Published in Advanced Science, the research demonstrates that when ATP binds to these clumps, the protein reshapes itself to trap the molecule in a small pocket. This process causes ATP to break apart and release energy, functioning similarly to an enzyme.

This unexpected finding could change scientists’ understanding of the damage caused by these clumps, which are hallmarks of diseases such as Parkinson’s and Alzheimer’s.