Until recently, the production of pluripotent
"multipurpose" stem cells from skin cells was considered to be the
ultimate new development. In the meantime, it has become possible to directly
convert cells of the body into one another -- without the time-consuming detour
via a pluripotent intermediate stage.
However,
this method has so far been rather inefficient. Scientists from the Bonn Institute
of Reconstructive Neurobiology (Director: Prof. Dr. Oliver Brüstle) have now
developed the method to the point that it can be used for biomedical
applications.
The scientists are presenting their results
in the journal Nature Methods.
There
was much excitement surrounding cell reprogramming with the breakthrough of
Shinya Yamanaka. In 2006, the Japanese scientist was able to reprogram skin
cells for the first time with the aid of a few control factors into so-called
induced pluripotent stem cells (iPS cells) -- "multipurpose" cells
from which all body cells can in principle be produced. In 2010,
Marius
Wernig, a former postdoctoral researcher with Prof. Brüstle and meanwhile the
director of the institute at Stanford University in California, developed the
idea further: Using only three so-called transcription factors, his team was
able to perform direct transformation of skin cells into so-called induced
neurons (iN). However, the method has so far been rather inefficient: Only a
small percentage of the skin cells were converted into the desired nerve cells.
Researchers are increasing yields during
transformation of cells
For the
scientists at the LIFE & BRAIN Center at the University of Bonn, that was
not enough. They are interested in the biomedical utilization of artificially
produced human nerve cells for disease research, cell replacement, and the
development of active substances. One concept seemed likely: Why not use
low-molecular active substances -- so-called small molecules -- to optimize the
process? Julia Ladewig, post-doctoral researcher and lead author of the study,
began using such active substances to influence several signaling pathways
important for cell development.
By
blocking the so-called SMAD signaling pathway and inhibiting glycogen synthase
kinase 3 beta (GSK3ß), they increased the transformational efficiency by
several times -- and were thus able to even simplify the means of extraction.
Using only two instead of previously three transcription factors and three active
substances, the Bonn researchers were able to convert a majority of the skin
cells into neurons. In the end, their cell cultures contained up to more than
80% human neurons. And since the cells divide even further during the
conversion process, the actual efficiency is even higher.
Two nerve cells are produced from one skin
cell
"We
can obtain up to more than 200,000 nerve cells converted in this way from
100,000 skin cells," says Julia Ladewig. In order to find the right
combination of active substances, the Bonn scientists are focusing on signaling
pathways which are especially important for cell specialization.
"The
SMAD signaling pathway and also GSK3ß were suspected of inhibiting the
conversion of connective tissue cells and pluripotent stem cells into neural
cells. The obvious step was to block both of them using corresponding active
substances," says Philipp Koch, team leader and senior author responsible
for the study, together with Prof. Brüstle.
The
results were intriguing: "We were able to demonstrate how the genes
typical for skin fibroblast were gradually down-regulated and
nerve-cell-specific genes were activated during the cell transformation. In
addition, the nerve cells thus obtained were functionally active, which also
makes them interesting as a source for cell replacement," says Ladewig.
Scientists are now transferring the method to
other types of cells
The
Bonn scientists have already transferred the method to other types of cells
such as, for example, umbilical cord cells. Brüstle clearly foresees the next
steps: "First of all, we want to use nerve cells obtained in this way for
disease and active substance research. The long-term goal will be to convert
cells directly in the body into nerve cells."
ScienceDaily
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