NEW YORK, NY (November TBD, 2018)—Some neurons in the brain protect themselves from Alzheimer’s with a cellular cleaning system that sweeps away toxic proteins associated with the disease, according to a new study from Columbia University, The Ohio State University, and the University of Cambridge.
The study, led by neuroscientist Karen Duff, PhD, of Columbia University Vagelos College of Physicians and Surgeons, Hongjun (Harry) Fu, PhD, of The Ohio State University, and Michele Vendruscolo, PhD, of the University of Cambridge, was published online today in Nature Neuroscience.
Cells that resist Alzheimer’s clear themselves of toxic tau proteins
Early in the course of Alzheimer’s disease, neurons in the brain become clogged with toxic tau proteins that impair and eventually kill the neurons.
The new study found that more tau accumulates in certain types of neurons, because cellular systems that clear the proteins from the cells are sluggish in these neurons.
Researchers have long known that neurodegenerative diseases like Alzheimer’s affect some neurons but not others, even leaving neighboring neurons unharmed. But the reasons for this selectivity have been difficult to identify.
New techniques probed inner workings of single cells
The new study was only possible because of new techniques that allow researchers to probe individual cells in the brain.
When Duff and her colleagues examined data from single neurons in the human brain, they detected signs that the components of a cellular cleaning system were less active in the neurons that accumulate tau proteins.
To confirm the connection between the cleaning system and tau buildup, the researchers manipulated one of the components – a protein called BAG3 – in mouse neurons. When the researchers decreased BAG3 levels in mouse neurons, tau piled up. But when BAG3 expression was enhanced, the neurons were able to rid themselves of excess tau.
“If we can develop therapies to support these natural defense mechanisms and stop tau from accumulating, we might be able to prevent, or at least slow, the development of Alzheimer’s and other tau-related neurodegenerative diseases.”
###
The study is titled, “A tau homeostasis signature is linked with the cellular and regional vulnerability of excitatory neurons to tau pathology.”
Karen E. Duff, PhD, is professor of pathology and cell biology at Columbia University Vagelos College of Physicians and Surgeons, and deputy director of the Taub Institute for Research on Alzheimer's Disease and the Aging Brain at Columbia University Irving Medical Center.
The other contributors are: Hongjun Fu (CUIMC and The Ohio State University), Andrea Possenti (University of Cambridge, Cambridge, UK), Rosie Freer (University of Cambridge), Yoshikazu Nakano (CUIMC), Nancy C. Hernandez Villegas (CUIMC), Maoping Tang (University of Rochester, Rochester, NY), Paula V. M Cauhy (CUIMC), Benjamin A. Lassus (CUIMC), Shuo Chen (CUIMC), Stephanie L. Fowler (CUIMC), Helen Y. Figueroa (CUIMC), Edward D. Huey (CUIMC), and Gail V.W. Johnson (University of Rochester).
The study was supported by grants from the National Institutes of Health (AG056673, NS074874, and AG056151), the Alzheimer’s Association, the BrightFocus Foundation, the Tau Consortium, and the Cure Alzheimer’s Fund.
Journal
Nature Neuroscience