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EMBARGOED FOR RELEASE: 1 JULY 2001 AT 00:15  ET US
Contact: Natalie Frazin
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301-496-5751
NIH/National Institute of Neurological Disorders and Stroke

Manipulating a single gene dramatically improves regeneration
in adult neurons:  Finding may lead to new approaches for treating
brain and spinal cord

Increasing the expression of a single gene that is important during
development dramatically improves the ability of adult neurons to
regenerate, a new study shows.  The finding suggests that intrinsic
properties of neurons play an important role in controlling neuronal
regeneration and may lead to new approaches for treating damage
from stroke, spinal cord injury, and other neurological conditions.

The study examined how genetically engineering adult neurons to
produce larger amounts of a type of protein called integrin affects
nerve fiber growth.  This approach is one of the first to examine
“the critical missing half of the regeneration equation:   the
properties of adult neurons, rather than the environment of the
adult brain,” says study investigator Maureen L. Condic, Ph.D.,
of the University of Utah School of Medicine in Salt Lake City.
The work was supported by the National Institute of Neurological
Disorders and Stroke (NINDS) and will appear in the July 1, 2001,
issue of the Journal of Neuroscience.(1)

Most neural regeneration studies in the past have manipulated
factors in the environment of the adult nervous system to try to
influence neuron growth.  Studies have shown that nerve fibers
can regenerate in the brain and spinal cord of newborn animals,
but regeneration does not normally occur in the brain or spinal
cord of older animals.  Recent studies have linked neuronal
regeneration to integrin proteins, which function as receptors
that enable neurons to interact with specialized molecules in the
surrounding environment during development. Neurons taken
from developing animals typically have very high levels of integrin,
but neurons from adult animals have very little of this protein.

In this study, Dr. Condic used a modified adenovirus to insert
extra copies of a gene for one kind of integrin protein into
sensory neurons taken from adult rats.  A second group of
neurons received extra copies of a different integrin gene.
The additional genes produced levels of integrin in the adult
neurons that were comparable to those in newborn animals.
The neurons were cultured in conditions similar to those of the
adult central nervous system.  Dr. Condic then measured the
amount of nerve fiber growth displayed by the adult neurons
with extra integrin genes and compared it to the growth of
neurons from newborn rats and of adult neurons that had
received a non-integrin gene.  She found that increasing the
amount of either of the integrin proteins dramatically increased
the amount of nerve fiber growth in the adult neurons.  The
increase in growth was more than ten times greater than that
in any other published study of regeneration by adult neurons.
The adult neurons with the extra integrin genes were able to
extend nerve fibers profusely even when growth-inhibiting
proteins were present in the culture.  The amount of growth
was indistinguishable from that of neurons from newborn animals.

The magnitude of the integrin proteins’ effects on the adult
neurons was very surprising, Dr. Condic says.   In the past,
many scientists believed that the inherent limitations on growth
of nerve fibers from adult neurons were too complex to be
significantly affected by altering a few genes.   In this study,
however, the effect of increasing just one gene was striking.
“It’s as though you have a ’57 Chevy on blocks in the front
yard, and it has all the necessary components except for its
wheels,” says Dr. Condic.  “If you give the wheels back, which
are the car’s usual way of interacting with the environment, it’s
ready to go.”  Integrin proteins are like the tires of the car – they
connect with the surrounding surface to enable neurons to extend
nerve fibers, she explains.

The finding complements studies of factors in the nervous system
environment that improve regeneration.  Effective therapies will
probably employ a multi-pronged approach that alters
environmental factors as well as the inherent properties of the
neurons, Dr. Condic says. However, it should be much easier to
regulate gene expression in specific neurons than to change the
environment of the brain.  “The nervous system is a very big place,
and right now we don’t have the technology to modulate the total
environment of the brain,” Dr. Condic explains.  Because the
nervous system is so complex, there is also a risk that changes
to the environment of the brain could inadvertently harm neurons
outside of the damaged area and result in problems such as epilepsy
or increased sensitivity to pain.

It may eventually be possible to modify integrin genes with a type
of “switch” that is controlled by drugs or other chemicals and inject
those genes into a damaged area of the brain, says Dr. Condic.
Doctors could then add and subtract the chemical to turn the genes
on and off, allowing them to precisely control the amount of nerve
fiber growth in that region of the brain.  However, an approach of
this type is still theoretical, and more research is needed before
scientists can predict whether such a technique might work in
humans.

Dr. Condic and colleagues are now planning to study integrin gene
expression in an animal model with a type of spinal cord injury that
is common in humans.  “This is the next critical step,” she says.
“At this point, all systems look ‘go’ with blazing green lights – but
in animals, it’s much more complicated.”

###

The NINDS, part of the National Institutes of Health in Bethesda,
Maryland, is the nation's leading supporter of research on the brain
and nervous system. The NINDS is now celebrating its 50th anniversary.

(1)Condic, M. L.  "Adult Neuronal Regeneration Induced by Transgenic
Integrin Expression." Journal of Neuroscience, Vol. 21, No. 13, July 1,
2001, pp. 4782-4788.

This release will be posted on the NINDS website at
http://www.ninds.nih.gov/news_and_events/index.htm

http://www.eurekalert.com/releases/aha-msg062501.html

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