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Ed. Note: The following
is a press release from the University of Chicago Medical Center
August 14, 2005
-- The same family of chemical signals that attracts developing sensory
nerves up the spinal cord toward the brain serves to repel motor nerves,
sending them in the opposite direction, down the cord and away from the
brain, report researchers at the University of Chicago in the September 2005
issue of Nature Neuroscience (available online August 14). The
finding may help physicians restore function to people with paralyzing
spinal cord injuries.
Growing nerve
cells send out axons, long narrow processes that search out and connect with
other nerve cells. Axons are tipped with growth cones, bearing specific
receptors, which detect chemical signals and then grow toward or away from
the source.
In 2003,
University of Chicago researchers reported that a gradient of biochemical
signals known as the Wnt proteins acted as a guide for sensory nerves. These
nerves have a receptor on the tips of their growth cones, known as
Frizzled3, which responds to Wnts.
In this paper,
the researchers show that the nerves growing in the opposite direction are
driven down the cord, away from the brain, under the guidance of a receptor,
known as Ryk, with very different tastes. Ryk sees Wnts as repulsive
signals.
"This is
remarkable example of the efficiency of nature," said Yimin Zou, Ph.D.,
assistant professor of neurobiology, pharmacology and physiology at the
University of Chicago. "The nervous system is using a similar set of
chemical signals to regulate axon traffic in both directions along the
length of the spinal cord."
It may also prove
a boon to clinicians, offering clues about how to grow new connections among
neurons to repair or replace damaged nerves. Unlike many other body
components, damaged axons in the adult spinal cord cannot adequately repair
themselves. An estimated 250,000 people in the United States suffer from
permanent spinal cord injuries, with about 11,000 new cases each year.
This study
focused on corticospinal neurons, which control voluntary movements and
fine-motor skills. These are some of the longest cells in the body. The
corticospinal neurons connect to groups of neurons along the length of
spinal cord, some of which reach out of the spinal cord. They pass out of
the cord between each pair of vertebrae and extend to different parts of the
body, for example the hand or foot.
Zou and
colleagues studied the guidance system used to assemble this complex network
in newborn mice, where corticospinal axon growth is still underway. Before
birth, axons grow out from the cell body of a nerve cell in the motor
cortex. The axons follow a path back through the brain to the spinal cord.
By the time of
birth, the axons are just growing into the cord. During the first week after
birth they grow down the cervical and thoracic spinal cord until they reach
their proper position, usually after seven to ten days.
From previous
studies, Zou and colleagues knew that a gradient of various Wnt proteins,
including Wnt4, formed along the spinal cord around the time of birth. Here
they show that two other proteins, Wnt1 and Wnt5a are produced at high
concentrations at the top of the cord and at consecutively lower levels
farther down.
They also found
that motor nerves are guided by Wnts through a different receptor, called
Ryk, that mediates repulsion by Wnts. Antibodies that blocked the Wnt-Ryk
interaction blocked the downward growth of corticospinal axons when injected
into the space between the dura and spinal cord in newborn mice.
This knowledge,
coupled with emerging stem cell technologies, may provide the most promising
current approach to nervous system regeneration. If Wnt proteins could be
used to guide transplanted nerve cells -- or someday, embryonic stem cells
-- to restore the connections between the body and the brain, "it could
revolutionize treatment of patients with paralyzing injuries to these
nerves," Zou suggests.
"Although half
the battle is acquiring the right cells to repair the nervous system," he
said, "the other half is guiding them to their targets where they can make
the right connections."
"Understanding
how the brain and the spinal cord are connected during embryonic development
could give us clues about how to repair damaged connections in adults with
traumatic injury or degenerative disorders," Zou added.
The National
Institute of Neurological Disorders and Stroke, the Schweppe Foundation, the
Robert Packard ALS Center at Johns Hopkins, the University of Chicago Brain
Research Foundation and the Jack Miller Peripheral Neuropathy Center
supported this study.
Additional
authors include Yaobu Liu, Jun Shi. Chin-Chun Lu, and Anna Lyuksyutova of
the University of Chicago, and Zheng-Bei Wang and Xuejun Song of the Parker
College Research Institute in Dallas Texas
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