New Method for Producing Precursor
of Neurons, Bone and Other Important Tissues from Stem Cells
Tuesday, 15 November 2011
In principle, stem cells offer
scientists the opportunity to create specific cell types — such as nerve or
heart cells — to replace tissues damaged by age or disease. In reality, coaxing
stem cells to become the desired cell type can be challenging, to say the
least.
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University of Georgia Researcher
Stephen
Dalton has developed a method that – in a
single step – directs undifferentiated, or
pluripotent, stem cells to become neural
crest cells, which are
the precursors of
bone cells, smooth muscle cells and
neurons. Credit:
University of Georgia.
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"Now
that we have methods for efficiently making neural crest stem cells, we can
start to use them to better understand human diseases," said lead author Stephen Dalton, Georgia Research Alliance Eminent
Scholar of Molecular Biology and professor of cellular biology in the UGA
Franklin College of Arts and Sciences.
"The
cells can be also used in drug discovery and potentially in cell therapy, which
involves the transplantation of cells."
The process by which a pluripotent stem
cell, which has the ability to become any type of cell in the body, becomes a
specific cell type is orchestrated by signaling molecules that activate
specific "decision" pathways
within cells. As a stem cell divides, various combinations of these molecules
at different points during its development narrow its possible outcomes so that
it ultimately becomes one type of cell, a skin cell, for example, instead of,
say, a muscle cell.
Until now, creating neural crest cells
relied on a mix of science and serendipity. Scientists would take
undifferentiated stem cells and direct them to become a related but different
cell type known as neural progenitor cells. The neural crest cells they really
wanted would often show up as contaminants, which scientists would then isolate
and use for their studies. Not surprisingly, the process was laborious, time
consuming, expensive and sub-optimal for clinical applications.
The method developed by Dalton and a
post-doctoral researcher in his laboratory, Laura Menendez, involves bathing
cells in a solution of small molecules that suppress one pathway, known as
Smad, and amplify another, known as Wnt. The inhibition of Smad is used in the
process that creates the related neural progenitor cells, which suggested that
the pathway could also play a role in the development of neural crest cells.
Observing that the Wnt pathway is highly active in the formation of the neural
crest in developing organisms led Dalton and his team to suspect that
activating the pathway could give them the cells they needed. After testing
various concentrations of the signaling molecules and determining the optimal
time to deliver them, the scientists discovered that they could create neural
crest cells with little or no contamination of other cell types.
The new method cuts the amount of time
required to generate the cells by approximately one-half. Dalton said another
benefit is that instead of using costly large-molecule compounds known as
growth factors and cytokines to direct the differentiation of cells, his method
uses inexpensive small molecules that have a much higher degree of consistency.
With their newly developed ability to
create neural crest cells, Dalton and his team are working to gain a deeper
understanding of normal development — as well as what goes wrong in devastating
diseases that are associated with neural crest defects, such as Hirschsprung's
disease, DiGeorge syndrome and Treacher-Collins syndrome.
The cells that Dalton and his team have
created are self-renewing, which means that multiple additional cells can be
created from an initial batch. Having large numbers of cells that can easily be
stored is essential for drug testing as well as for cell transplantation, the
holy grail of stem cell science.
"Now
that we've worked out ways for making the cells, we've greatly enhanced their
potential in disease modeling and regenerative medicine," Dalton said.
Source: University of Georgia
Contact: Stephen Dalton.........
For more on stem cells and cloning, go to CellNEWS at
http://cellnews-blog.blogspot.com/
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