How Neural Stem Cells Activate in the Adult Human Brain?

A University of Ottawa neuroscientist led a Canadian team uncovering key insights into neural stem cell activation, which is crucial for building and renewing the central nervous system (1^✔ ✔Trusted Source
Neural stem cell quiescence and activation dynamics are regulated by feedback input from their progeny under homeostatic and regenerative conditions

Go to source). The collaborative team led by the University of Ottawa’s Dr. Armen Saghatelyan aimed to shed light on how neural stem cells integrate a multitude of signals from different cell types in the brain – and how they decode these signals.

These are big questions because how NSCs react to signals in their cellular environment controls whether they remain in their dormant, non-dividing state known as “quiescence” or if they get activated to grow and divide, generating new neurons and glia in the process.

Neural Stem Cell Activation: A Key to Brain Repair and Regeneration

The reported findings, published today in Cell Stem Cell, will certainly be of deep interest to scientists studying a range of adult neurological diseases and aging. In the neural landscape, rousing NSCs from dormancy, where they conserve resources and energy, is key for neural regeneration and brain injury repair.

“These data make it possible to understand better how NSCs can be activated to generate more neurons and glia in order to counteract different neurological disorders and aging. We are currently studying NSCs’ responses for some of these conditions,” says Dr. Saghatelyan, Canada Research Chair in Postnatal Neurogenesis and the new publication’s senior author. (Neurogenesis is the process by which new neurons are formed in the brain.)

One avenue of new insight focuses on how stem cells wrap around progeny called “daughter” cells – genetically identical cells created after a parent cell divides.

The team discovered that neural stem cells are in fact receiving constant feedback from their chatty daughter cells. Dr. Saghatelyan likens this to a “parent-child relationship” in which the parent is closely attuned to their child’s feedback.

“Many parents will relate to this since parents like to receive news, or feedback, from their children. Based on this feedback, the parents will either stay reassured that everything is going well or take an action,” he says, comparing this dynamic to the cellular state of quiescence or activation.

Revealing this hidden mechanism is a major finding because it provides an entirely new framework for how to understand this cellular relationship in the human brain.

“Until now it was thought that NSCs only generate progeny and that there is no interaction between them,” Dr. Saghatelyan says. “But our work challenged this notion and showed that there is tight structuro-functional interaction between NSCs and their progeny – and that the number of progeny or the efficiency of progeny-NSC interaction determines whether neural stem cells stay quiescent or get activated to generate neurons and glia.”

Further, the new study advances our understanding of how NSCs integrate and decode a multitude of signals in space and time. Dr. Saghatelyan says the research unveils for the first time that “calcium signaling in NSCs allows for integration and decoding of all these signals.”

These new windows of understanding into how NSCs decode signals and how their activation is triggered offers strong potential for informing any future treatments for human neurodevelopmental disorders. Indeed, advancing this potential is the next step for the research collaborators as they explore questions suggested by this work.

“We are now exploring how interactions of NSCs with different cell types in their micro-environment is affected in different physiological and pathological conditions as well as in healthy aging,” says Dr. Saghatelyan, whose Faculty of Medicine research lab focuses on generating new knowledge to help boost neuronal regeneration.

The study – which started at Université Laval where Dr. Saghatelyan’s lab was located until 2022 – was conducted at the uOttawa Faculty of Medicine, where a cutting-edge two-photon imaging system made it possible to assess the functional activity of neural stem cells. Single cell sequencing and spatial transcriptomics were performed by collaborators at University of Toronto and the University of British Columbia. Machine learning collaboration was performed at Université Laval.

The work was supported by the Canadian Institutes of Health Research (CIHR), the Canada Foundation for Innovation (CFI), and investments from the Canada Research Chair program.

Reference:

1. Neural stem cell quiescence and activation dynamics are regulated by feedback input from their progeny under homeostatic and regenerative conditions - (https://linkinghub.elsevier.com/retrieve/pii/S1934590925000013)

Source-Eurekalert