A simple drug cocktail that converts cells
neighboring damaged neurons into functional new neurons could
potentially be used to treat stroke, Alzheimer's disease, and brain
injuries. A team of researchers at Penn State identified a set of four,
or even three, molecules that could convert glial cells -- which
normally provide support and insulation for neurons -- into new neurons.
A paper describing the approach appears online in the journal Stem Cell Reports on February 7, 2019.
"The biggest problem for brain repair is that neurons don't
regenerate after brain damage, because they don't divide," said Gong
Chen, professor of biology and Verne M. Willaman Chair in Life Sciences
at Penn State and leader of the research team. "In contrast, glial
cells, which gather around damaged brain tissue, can proliferate after
brain injury. I believe turning glial cells that are the neighbors of
dead neurons into new neurons is the best way to restore lost neuronal
functions."
Chen's team previously published research describing a sequence of
nine small molecules that could directly convert human glial cells into
neurons, but the large number of molecules and the specific sequence
required for reprogramming the glial cells complicated the transition to
a clinical treatment. In the current study, the team tested various
numbers and combinations of molecules to identify a streamlined approach
to the reprogramming of astrocytes, a type of glial cells, into
neurons.
"We identified the most efficient chemical formula among the hundreds
of drug combinations that we tested," said Jiu-Chao Yin, a graduate
student in biology at Pen State who identified the ideal combination of
small molecules. "By using four molecules that modulate four critical
signaling pathways in human astrocytes, we can efficiently turn human
astrocytes -- as many as 70 percent -- into functional neurons."
The resulting chemically converted neurons can survive more than
seven months in a culture dish in the lab. They form robust neural
networks and send chemical and electrical signals to each other, as
normal neurons do inside the brain.
Using three of the small molecules instead of four also results in
the conversion of astrocytes into neurons, but the conversion rate drops
by about 20 percent. The team also tried using only one of the
molecules, but this approach did not induce conversion.
Chen and his team had previously developed a gene therapy technology
to convert astrocytes into functional neurons, but due to the excessive
cost of gene therapy -- which can cost a patient half a million dollars
or more -- the team has been pursuing more economical approaches to
convert glial cells into neurons. The delivery system for gene therapies
is also more complex, requiring the injection of viral particles into
the human body, whereas the small molecules in the new method can be
chemically synthesized and packaged into a pill.
"The most significant advantage of the new approach is that a pill
containing small molecules could be distributed widely in the world,
even reaching rural areas without advanced hospital systems," said Chen.
"My ultimate dream is to develop a simple drug delivery system, like a
pill, that can help stroke and Alzheimer's patients around the world to
regenerate new neurons and restore their lost learning and memory
capabilities."
The researchers acknowledge that many technical issues still need to
be resolved before a drug using small molecules could be created,
including the specifics of drug packaging and delivery. They also plan
to investigate potential side effects of this approach in future studies
in order to develop the safest drug pills. Nonetheless, the research
team is confident that this combination of molecules has promising
implications for future drug therapies to treat individuals with
neurological disorders.
"Our years of effort in discovering this simplified drug formula take us one step closer to reaching our dream," said Chen.
In addition to Chen and Yin, other co-authors contributed to this
work include Lei Zhang, Ning-Xin Ma, Yue Wang, Grace Lee, Xiao-Yi Hou,
Zhuo-Fan Lei, Feng-Yu Zhang, Feng-Ping Dong and Gang-Yi Wu from Penn
State. This work was supported by the National Institutes of Health
(AG045656), the Alzheimer's Association (ZEN-15-321972), and the Charles
H. "Skip" Smith Endowment Fund at Penn State.
Courtesy: ScienceDaily
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