Young, resting neural stem cells in the brains of mice store large clumps of proteins in specialized cellular trash compartments known as lysosomes, researchers have found.
As the cells age, they become less proficient at disposing of these protein aggregates, and their ability to respond readily to "make new neurons" signals wanes. Restoring the ability of the lysosomes to function normally rejuvenates the cells' ability to activate, the researchers found.
The discovery of the aggregates in young stem cells was unexpected, in part because similar aggregates are associated with the development of neurodegenerative diseases, such as Alzheimer's. It also highlights the importance of maintaining precise control over the protein production and disposal process throughout the life and activation status of neural stem cells.
"We were surprised by this finding because resting, or quiescent, neural stem cells have been thought to be a really pristine cell type just waiting for activation," said the senior author, published the work in Science . "But now we've learned they have more protein aggregates than activated stem cells, and that these aggregates continue to accumulate as the cells age. If we remove these aggregates, we can improve the cells' ability to activate and make new neurons. So if one were able to restore this protein-processing function, it could be very important to bringing older, more dormant neural stem cells 'back to life.'"
The researchers began their studies by looking to see what difference there might be, if any, between the gene expression profiles of resting neural stem cells and those that had been activated in response to an outside signal to launch the process to make new neurons. They also compared how the cells changed as they aged.
They isolated several populations of cells for study from the brains of both young and old mice, including resting neural stem cells, activated neural stem cells and the neural cell progenitors that arise from activated stem cells. Authors found that resting stem cells expressed many lysosome-associated genes, while activated stem cells expressed genes associated with a protein complex involved in protein destruction called a proteasome. Strict control of production and disposal allows cells to maintain the necessary protein inventory to carry out needed cellular functions.
When researchers stained young resting and activated neural stem cells with a dye that binds to protein aggregates, they were surprised to find the resting stem cells stained more brightly, despite the fact that resting cells have a lower rate of protein production. They also found that the young resting neural stem cells accumulated these protein aggregates in their large lysosomes relatively slowly compared with their activated counterparts.
"We were really struck by the differences between resting and activated stem cells in the expression of genes involved in protein quality control," said the senior author. "The fact that these young, pristine resting stem cells accumulate protein aggregates makes us wonder whether they actually serve an important function, perhaps by serving as a source of nutrients or energy upon degradation."
Old resting stem cells, authors found, express fewer lysosome-associated genes and begin to accumulate even higher levels of protein aggregates.
"It's almost as if these older cells lose the ability to store, or park, these aggregates," said the senior author. "We found that artificially clearing them by either activating lysosomes in older cells or subjecting them to starvation conditions to limit their protein production actually restored the ability of these older resting stem cells to activate."
The researchers plan to continue their studies to learn what types of proteins might be contributing to the aggregates, to better understand why activated neural stem cells appear to favor proteasomes over lysosomes and to determine how the regulation of protein aggregation becomes disrupted during aging.
"We'd like to know whether the aggregated proteins are the same in the young and old cells," said the senior author. "What do they do? Are they good or bad? Are they storing factors important for activation? If so, can we help elderly resting stem cells activate more quickly by harnessing these factors? Their existence in young cells suggests they may be serving an important function."
Lysosomes keep neuronal stem cells young
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