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Ed Note: The following is a press release from the University of
Rochester
July 28, 2004
ATP, the vital energy source that keeps our body's cells alive, runs amok at
the site of a spinal cord injury, pouring into the area around the wound and
killing the cells that normally allow us to move, scientists report in the
cover story of the August issue of Nature Medicine.
The finding that ATP is a culprit in causing the devastating damage of
spinal cord injury is unexpected. Doctors have known that initial trauma to
the spinal cord is exacerbated by a cascade of molecular events over the
first few hours that permanently worsen the paralysis for patients. But the
finding that high levels of ATP kill healthy cells in nearby regions of the
spinal cord that were otherwise uninjured is surprising and marks one of the
first times that high levels of ATP have been identified as a cause of
injury in the body.
The team found that excess ATP damages motor neurons, the cells that allow
us to move and whose deaths in the spinal cord result in paralysis. Even
more noteworthy was what happened when the research team from the University
of Rochester Medical Center blocked ATP's effects on neurons: Rats with
damaged spinal cords recovered most of their function, walking and running
and climbing nearly as well as healthy rats.
While the work opens up a promising new avenue of study, the work is years
away from possible application in patients, cautions Maiken Nedergaard,
M.D., Ph.D., the researcher who led the study. In addition, the research
offers promise mainly to people who have just suffered a spinal cord injury,
not for patients whose injury is more than a day old. Just as clot-busting
agents can help patients who have had a stroke or heart attack who get to an
emergency room within a few hours, so a compound that could stem the damage
from ATP might help patients who have had a spinal cord injury and are
treated immediately.
"There is no good acute treatment now for patients who have a spinal cord
injury," says Nedergaard. "We're hoping that this work will lead to therapy
that could decrease the extent of the secondary damage.
"This is an unusual way of looking at spinal cord injury. Much of the focus
of research has been on trying to re-grow portions of the spinal cord. We're
trying to stop the damage up front," says Nedergaard, a professor in the
Department of Neurosurgery and a researcher in the Center for Aging and
Developmental Biology.
The findings come courtesy of the same technology that underlies the
firefly's mating habits. The firefly uses the enzyme luciferase to convert
ATP to the glow it uses to light up and attract mates. Nedergaard's team
used the same enzyme to study the levels of ATP around the site of spinal
cord injury, recording a very a bright signal for several hours around the
site of injury.
While low levels of ATP normally provide a quick and primitive way for cells
to communicate, Nedergaard says, levels found in the spinal cord were
hundreds of times higher than normal. The glut of ATP over-stimulates
neurons and causes them to die from metabolic stress.
Neurons in the spinal cord are so susceptible to ATP because of a molecule
known as "the death receptor." Scientists know that the receptor, also
called P2X7, also plays a role in regulating the deaths of immune cells such
as macrophages, but its appearance in the spinal cord was a surprise. ATP
uses the receptor to latch onto neurons and send them the flood of signals
that cause their deaths. Nedergaard's team discovered that P2X7 is carried
in abundance by neurons in the spinal cord.
The source of the ATP that kills the neurons provided another revelation for
researchers. Star-shaped cells known as astrocytes, long considered simply
as passive support cells for neurons in the nervous system, produce the high
levels of ATP.
Normally researchers studying spinal cord injury and conditions like
Alzheimer's disease or stroke give most of their attention to neurons, which
send electrical signals and make up the nerves that are vital to everything
we do. But gradually scientists have warmed to the idea that astrocytes play
a vital role in our health. Astrocytes fulfill a vital "housekeeping" role,
nourishing neurons, supplying them with chemicals they need to do their job,
and allowing them to keep their signals crisp by vacuuming up excess
chemicals.
Ten years ago, Nedergaard discovered that astrocytes send signals to the
neurons and the neurons respond. The latest research, funded by the National
Institute of Neurological Disorders and Stroke and the New York State Spinal
Cord Injury Research Program, extends the work and shows that astrocytes
play a central role in our health.
"For a long time, astrocytes were thought of simply as the housekeepers of
the brain, feeding the neurons and regulating their environment," says
Nedergaard. "But astrocytes are much more active than we have thought. It
appears that sometimes astrocytes even give out the instructions telling
neurons what to do. It's very likely they play an important role in many
human diseases."
The paper will appear in the August issue of Nature Medicine and was
published on-line last week. Other authors from the University of Rochester
include graduate student Xiaohai Wang, post-doctoral associate Takahiro
Takano, researchers Qiwu Xu and Wei Guo Peng, technician Pingjia Li, and
collaborator Steven Goldman. The paper also includes authors from New York
Medical College, where Nedergaard worked before joining the university last
year.
Contact: Tom Rickey
trickey@admin.rochester.edu
University of Rochester Medical Center
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