New research appearing in the journal Nature Biotechnology answers important questions about the viability of treatments that seek to replace diseased and aged cells in the central nervous system with healthy ones. Its findings have implications for a number of neurological and psychiatric disorders—including Huntington’s disease, amyotrophic lateral sclerosis (ALS), and schizophrenia—that have been linked to glia, a population of cells that support brain health and function.
“A broad variety of disorders we associate with neuronal loss now appear to be caused by dysfunctional glial cells,” said the lead author of the new study. “This makes these diseases attractive targets for stem and progenitor cell-based therapies.”
The new study describes the ability of human glial progenitor cells–precursor cells that can give rise to both astrocytes and oligodendrocytes, the two major types of glia—to compete with one another in the adult brain, and the competitive advantage of young and healthy cells over aged and diseased cells.
A number of recent important advances are behind the new findings. In 2013, the team first reported strategies for producing the brain’s glial support cells from embryonic stem cells. In later research, the lab transplanted these cells into the brains of baby mice, resulting in the creation of human glial-chimeric mice, a technical achievement that enables the researchers to study human glial cells in the living brain. The team showed that after transplantation, the human glial progenitor cells quickly outcompeted native cells, resulting in brains with mouse neurons and human glia.
In later experiments, the lab transplanted human glial cells with the Huntington’s disease (HTT) mutation. They observed that this mutation impaired the function of glial progenitor cells, resulting in poor astrocytes and oligodendrocytes production. The lab also showed that transplanting healthy human glial progenitor cells into mouse models of Huntington’s delayed disease progression, reinforcing the importance role that glial dysfunction plays in this still untreatable neurodegenerative disease.
As these prior studies were limited to the transplant of human cells into the mouse brain, the question remained whether human cells transplanted into another human brain would yield the same type of benefit. The new Nature Biotechnology study strongly suggests that the answer to this question is yes, and highlights the potential value of cell replacement therapies by showing that healthy human glia will outcompete and replace sick human cells.
To demonstrate this, the researchers first implanted human glial progenitor cells with the HTT mutation into the brains of newborn mice. After the animals reached adulthood, the researchers then transplanted healthy human glial cells, which went on to displace and eliminate their Huntington’s disease counterparts.
“In the striatum, our target area, the healthy cells essentially kicked out the disease cells, eventually replacing the glial progenitor population entirely,” said the author. “You can actually see a wave of migration and a border where the cells expressing the HTT mutation are dying off and being replaced by heathy ones.
In an accompanying set of experiments, the researchers found that younger healthy human glial progenitors outcompeted older and otherwise healthy human glia, suggesting that cellular youth is a critical determinant of competitive success.
“These findings have strong therapeutic implications, as they suggest that in the adult human brain, resident glia–whether diseased or simply aged—may be replaced following the introduction of younger and healthier cells,” said the author.
https://www.nature.com/articles/s41587-023-01798-5
http://sciencemission.com/site/index.php?page=news&type=view&id=publications%2Fyoung-glial-progenitor&filter=22
Swapping young glial progenitor cells with old ones to treat Huntington's disease
- 1,613 views
- Added
Latest News
How antisense non-coding RN…
By newseditor
Posted 07 Jul
3D maps of diseased tissues…
By newseditor
Posted 06 Jul
How GLP-1 receptor agonists…
By newseditor
Posted 06 Jul
Pan-cancer proteogenomics e…
By newseditor
Posted 05 Jul
Fertility treatments could…
By newseditor
Posted 05 Jul
Other Top Stories
Vasomotion is critical in clearing amyloid from the brain
Read more
Using health records and not genetic data to calculate genetic link…
Read more
Tau and amyloid team up to damage synapses!
Read more
Neurons regulating early alcohol consumption identified!
Read more
A new FUS mediated toxicity modifier in ALS identified
Read more
Protocols
Pan-cancer proteogenomics c…
By newseditor
Posted 05 Jul
A systems biology-based ide…
By newseditor
Posted 05 Jul
Tongue orthotopic xenograft…
By newseditor
Posted 04 Jul
Monitoring norepinephrine r…
By newseditor
Posted 01 Jul
BicemuS: A new tool for neu…
By newseditor
Posted 26 Jun
Publications
dsRNA formation leads to pr…
By newseditor
Posted 07 Jul
BACH1 inhibits senescence,…
By newseditor
Posted 07 Jul
Bone transport induces the…
By newseditor
Posted 06 Jul
Hypothalamic neuronal activ…
By newseditor
Posted 06 Jul
Prevention of Falls in Olde…
By newseditor
Posted 05 Jul
Presentations
Myelin plasticity in the ve…
By newseditor
Posted 10 Jun
Hydrogels in Drug Delivery
By newseditor
Posted 12 Apr
Lipids
By newseditor
Posted 31 Dec
Cell biology of carbohydrat…
By newseditor
Posted 29 Nov
RNA interference (RNAi)
By newseditor
Posted 23 Oct
Posters
A chemical biology/modular…
By newseditor
Posted 22 Aug
Single-molecule covalent ma…
By newseditor
Posted 04 Jul
ASCO-2020-HEALTH SERVICES R…
By newseditor
Posted 23 Mar
ASCO-2020-HEAD AND NECK CANCER
By newseditor
Posted 23 Mar
ASCO-2020-GENITOURINARY CAN…
By newseditor
Posted 23 Mar