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Researchers at McGill University in Montreal  have published a
preliminary report that they have discovered stem cells deep in the skin
of rats and humans  can become fat, muscle and brain cells. When
implanted into rat brains, the cells continued to grow. The next step in
their research will be to implant the cells in rat brains with simulated
Parkinson's disease to test if brain function can be restored.

The research is being funded by two private companies that have "licensed
McGill's patents on the discovery,...  grants from the Christopher Reeve
Paralysis
Foundation... and the Canadian government's newly formed Stem Cell
Network, a
consortium designed to nurture pioneering work."

The reporter states that Dr. Freda Miller, one of the researchers
emphasized
"that even if adult stem cells are all they promise to be, it is crucial
that researchers still have access to embryonic stem cells for
comparison."
   "I don't want people to use our work as a reason to not use embryonic
stem
cells," she said. "So much of our work is based on embryonic stem cell
research,
I would really hate at this early point to see any of that work impeded."

Very interesting full article below:
Linda

 FROM: Los Angeles Times
 August 19, 2001 Sunday  Home Edition
SECTION: Part A; Part 1; Page 5; Foreign Desk

"Stem Cell Research Matures in Montreal Studies;
Science: Team finds that adult material--not just that found in embryos--
can
change into many types of tissue for possible use in treating diseases."

BYLINE: MAGGIE FARLEY, TIMES STAFF WRITER

   Dr. Freda Miller has a vision. It is that someday she could take a bit
of
someone's skin and transform its "blank slate" stem cells into brain
tissue to
alleviate that person's Parkinson's symptoms, or pancreatic cells to cure
a
patient's diabetes. (No cloning necessary.)

   Miller and her research team at McGill University's Montreal
Neurological
Institute unveiled the first step toward that vision last week when they
announced that they have discovered stem cells deep in the skin of rats
and
humans that can become fat, muscle or even brain cells.

   The discovery, detailed in the September issue of the journal Nature
Cell
Biology, is a significant step in research showing that stem cells of
adults--not just those found in embryos--can change into many types of
tissue.
If adult stem cells can be used to treat diseases, they might provide a
way to
sidestep the moral dilemma of whether a tiny cluster of cells from an
embryo
represents human life. President Bush grappled with that question this
month in
deciding to limit federal funding for embryonic stem cell research.

   As potentially valuable as it is politically charged, stem cell
research is
one of the fastest-moving areas in molecular biology. A few years ago,
scientists thought that adult stem cells could change only into the same
class
of tissue as their place of origin. Only stem cells found in the brain,
according to this reasoning, could become neural cells, while only those
found
in bone marrow could help make blood.

   In the past year and a half, however, studies have shown that these
powerful
cells can be coaxed into quite different fates. Stem cells found in the
brain
can be changed into muscle, and those in bone marrow can turn into liver
cells.
Unlike their embryonic counterparts, though, adult stem cells are painful
to
harvest and difficult to divide, and their cell lines--the sets, or
colonies,
derived from them--are generally short-lived.

   But the stem cells found at McGill, which seem to be exceptionally
versatile,
are easy to generate and simple to collect--the practical beauty of the
discovery is that it is only skin deep. Miller's study is the first to
claim
that a single adult stem cell can give rise to two of three of the basic
classes
of cells in the body. The McGill lab is working to confirm that it can
generate
cells for all three, and preliminary results are encouraging, Miller
says.

   "As a scientist, you're trained not to hope too much," she said. "But
on this
project, things keep turning out well."

   Most important, in an experiment yet to be published, researchers
implanted
neural cells derived from skin stem cells into rat brains, where they
seemed to
meld well with the surrounding tissue and act like the cells around them.
Next,
the team will implant the cells in rat brains with simulated Parkinson's
disease
to test whether they can help restore brain function.

   Still, it's a far step from rat brains to treatments that will work in
human
brains. Although the researchers allowed themselves champagne toasts and
a quick
celebration the day their article was published--after two years of
checking and
rechecking their results--they know this is just the beginning.

   They plan to spend the next two years learning how to induce the cells
to
become specific types of tissue and how to control their development once
they
do. (A neuron derived from a skin cell, for example, needs to remain a
neuron.)

   Miller said the researchers also need to duplicate more of their
rodent
results with human cells. But the scientists are driven by the hope of
bringing
science closer to treatments for spinal cord injuries, juvenile diabetes,
heart
disease and brain disorders--treatments made from patients' own cells.

   According to Miller, the biggest limitation to working with adult stem
cells
is that so little is known about them. It was only two years ago that one
researcher in the McGill lab, Jean Toma, asked, Why not look for stem
cells in
skin? The dermis is rich in different types of cells, including neural
cells
that sense temperature and pressure. It repairs itself quickly without
losing
sensation. And it's easy to obtain samples.

   The scientists decided to give one experiment a couple of months.
Within a
few weeks, they had the first hints that neural cells were developing
from stem
cells they had harvested. Then they exposed those cells to different
growth
cultures to coax them into becoming different types of cells--bubble-like
fat
cells, and the lithe cells of smooth muscle. Most significant, they
produced
several kinds of brain cells, including neurons, the thinking units of
the
brain, and glial cells, which produce the nerve fiber sheaths that can be
damaged by multiple sclerosis.

   To prove that all the different types were originating from a single
skin
stem cell, they also isolated lone cells and started over. And over. And
over
again. They allowed the single cells to flourish into small colonies to
see how
long they could keep generating. Most adult stem cell lines peter out
after a
short time, while their embryonic cousins, by comparison, can keep
dividing
indefinitely.

   The lab members, alternately ecstatic and skeptical, brought in a
small cake
on the cell line's 1-year "birthday." In November, the cell line will
turn 2.

   "They're still growing like crazy," Miller said.

   Though the advances made by Miller and her colleagues are coming
almost on
top of one another, their newly discovered stem cell is a long way from
replacing the embryonic stem cell in research or therapy.

   "We're so far behind still in adult stem cells," Miller said. "You can
make
more than 200 cells from an embryonic stem cell--every type of cell in a
human
being--and at this point, only five or six from ours. That's a very big
gap."

   Other scientists are watching their work carefully.

   "Stem cell biology is important for all areas of medicine, and so
we're going
to have to explore the properties of all these cells," said Ronald McKay,
a stem
cell expert at the U.S. National Institutes of Health who regards the
McGill
discovery with cautious optimism. "What we're likely to be going into now
is a
period of many claims and many ups and downs."

   A number of players, public and private, have come together in Canada
to help
stimulate this research. Miller's work is funded in part by two private
companies that have licensed McGill's patents on the discovery: Curis
Inc. of
Cambridge, Mass., and Canada's Aegera Therapeutics Inc. The rest of the
funding
comes from a combination of grants from the Christopher Reeve Paralysis
Foundation and the Canadian government's newly formed Stem Cell Network,
a
consortium designed to nurture pioneering work.

   Spurred by recent debate in the U.S. over the limits of stem cell
research,
and the reported efforts of a Canadian cult known as the Raelians to
start
cloning humans, the Canadian government is pushing new legislation to
restrict
embryonic stem cell research.

   Canada's draft law is more liberal than the United States' new policy.
It
would allow stem cells to be taken from embryos left over from in vitro
fertilization procedures but would not tolerate the creation of embryos
solely
for research. As in Britain, it would permit embryos to be used only
within 14
days of their creation and only with the donor's consent.

   But even scientists like Miller, who doesn't directly use embryos or
cloning
in her work, are wary of interference. Miller emphasized that even if
adult stem
cells are all they promise to be, it is crucial that researchers still
have
access to embryonic stem cells for comparison.

   "I don't want people to use our work as a reason to not use embryonic
stem
cells," she said. "So much of our work is based on embryonic stem cell
research,
I would really hate at this early point to see any of that work impeded."

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