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UCLA BERKELEY: Adult Stem Cells Triggered To Multiply More Quickly
SOURCE: Knight Ridder News / The Billings Gazette, MT
WWWeb: http://tinyurl.com/6b3qo

Last modified November 21, 2004 - 11:43 pm

BERKELEY, Calif. - Adult stem cells carry neither the controversy nor
the cachet of embryonic stem cells, but research on the older cells
is often clouded by the conflict over their younger cousins.

Now, a UC Berkeley bioengineer has devised a way to enhance the
utility of adult stem cells that could steal some of the spotlight
away from embryonic stem cells and eventually lead to treatments or
cures for diseases such as Alzheimer's and Parkinson's.

David Schaffer and a team of scientists from the University of
California at Berkeley and the Salk Institute in San Diego discovered
that a certain protein can trigger adult stem cells in the brain to
multiply at three times the normal rate.

"We've learned how to make them divide faster,'' said Schaffer. "And
then the brain knows what to do with them, and about half are turned
into neurons.''

Schaffer used a protein called Sonic hedgehog that is involved with
development of the central nervous system in embryos. The protein got
its name from the popular video game character because mutating the
protein causes fruit fly embryos to grow a small pointy ridge like a
hedgehog.

When Sonic hedgehog meets stem cells from rat brains in a petri dish,
the stem cells speed up their division. Schaffer's team also found
that injecting the gene that creates Sonic hedgehog directly into the
brains of live rats pumps up stem cell proliferation.

"If you could do the same thing in a human being, it might enhance
the function of the hippocampus which is an area of the brain
involved in learning and memory,'' said Theo Palmer, a neuroscientist
at Stanford University.

Though adult stem cells are less versatile than embryonic stem cells,
the more mature cells could actually be better suited for certain
uses, Schaffer said.

Embryonic stem cells have captured scientists' imaginations because
they have the extraordinary ability to grow into many different types
of cells. When a stem cell divides, each new cell can either stay a
stem cell or develop into a specialized cell, such as a red blood
cell or a muscle cell.

Scientists hope to learn how to control which specialized cells the
embryonic stem cells become. This would be the first step toward
replacing cells damaged by disease or injury.

"The embryonic stem cells are the ultimate blank slate,'' Schaffer
said.

Adult stem cells have already started down the path toward a
particular set of specialized cells, such as brain cells. So if it's
brain cells that are needed, as in the case of stroke victims or
patients with a brain disease, adult stem cells may be easier to work
with.

Another advantage of working with adult stem cells is avoiding the
ethical firestorm surrounding embryonic stem cells, which can most
easily be gotten from human embryos that are a few days old.

Because of these concerns, in 2001 the Bush administration decided to
limit federal funding for embryonic stem cell research to cell lines
that are already in existence.

Though Californian's voted to take up some of the slack by passing
Proposition 71, a $3 billion stem cell research initiative that will
include embryonic stem cells, research on adult stem cells is also
still eligible for federal grants.

Another challenge facing both types of stem cell research down the
road will be successful transplantation of the cells into a patient
so that they won't be rejected by the immune system.

Schaffer's research could help overcome this hurdle by using a
patient's own stem cells, possibly while they are still in the brain.


``It would be easier to have somebody pop a pill that gives the stem
cells the signal to make them do what we want them to do,'' said
Schaffer.

Schaffer's team took DNA from a rat and isolated the gene that
produces the Sonic hedgehog protein. They then cloned that gene,
inserted it into a harmless virus which they then injected into the
rat's brain. The virus delivered the Sonic hedgehog genes to the
brain stem cells, stimulating them to divide three times faster than
normal, which in turn tripled the production of new neurons.

The area of the brain they treated is called the hippocampus, which
is involved in learning and memory and is severely affected by
Alzheimer's disease. Though it would probably be a decade or more
away, Schaffer's research could eventually lead to a treatment or
cure for Alzheimer's Disease, and other brain diseases and injuries.

``I think it's very promising,'' said Ravi Kane, a chemical engineer
at Rensselaer Polytechnic Institute in Troy, N.Y. ``But at the same
time, we're not talking about a cure for Alzheimer's disease in the
next two years. It's an exciting avenue, but it's still down the
road.''

The next step for Schaffer's team is to try to learn how to control
the development of stem cells into neurons. They'd also like to be
able to generate other types of neurons that would help people with
Parkinson's disease and Lou Gehrig's disease.

Schaffer's discoveries also have the potential to help people with
depression and people with cancer who are treated with radiation
therapy, says Palmer. Recent studies in Palmer's lab and elsewhere
suggest that in both of these cases, brain stem cell growth is
stunted.

SOURCE: The Billings Gazette, MT
WWWeb: http://tinyurl.com/6b3qo

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