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Source:UT Southwestern Medical Center
Date:September 14, 2006
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Parkinson's-like Cell Death Blocked By Stopping Inflammatory Factor
Blocking one of the body's natural inflammatory factors gives substantial
protection against cell death in the brain associated with Parkinson's
disease, researchers at UT Southwestern Medical Center have found in a study
on rats.

Blocking one of the body's natural inflammatory factors gives substantial
protection against cell death in the brain associated with Parkinson's
disease, researchers led by Dr. Malu Tansey, assistant professor of
physiology, have discovered. By using a drug against tumor necrosis factor,
or TNF, the researchers saw a 50 percent drop in dopamine neuron death in
the brains of rats injected with compounds that cause Parkinson's-like cell
death. (Credit: UT Southwestern Medical Center)
By using a drug against an inflammatory molecule called tumor necrosis
factor or TNF, the researchers saw a 50 percent drop in dopamine neuron
death in the brains of rats injected with compounds that cause
Parkinson's-like cell death.
"Our findings suggest that TNF-dependent inflammation may be part of the
progressive features of Parkinson's disease, and this gives us an
opportunity with anti-TNF therapy to slow down or prevent the progression of
the disease," said Dr. Malú Tansey, assistant professor of physiology at UT
Southwestern and senior author of the study. "Our prediction is that
independent of the environmental toxin or trigger that induces its
production in the midbrain, TNF is likely to be a common mediator of
dopamine neuron death."
The research will appear online and in the Sept. 13 issue of the Journal of
Neuroscience.
Tumor necrosis factor is necessary for a functioning immune system. Its
effects include the local inflammation and redness around wounds, and the
painful swelling around joints in rheumatoid arthritis. TNF also activates
other cells -including cells in the brain called microglia - that eat
bacteria and other pathogens.
While the results point in a direction for treating neurodegenerative
diseases with anti-inflammatories, a few problems will need to be addressed
before anti-TNF therapies could come into widespread use to fight
neurodegeneration, Dr. Tansey said. For instance, commercially available
anti-TNF drugs as well as the new drug used in this study are too large to
independently cross from the bloodstream into brain tissue.
Parkinson's disease affects 5 percent of people over 65, and is the second
most common neurodegenerative disease after Alzheimer's. Parkinson's disease
comes about because of the death of a certain class of nerve cells in an
area of the brain called the substantia nigra. By the time serious symptoms
appear, more than 80 percent of the dopamine-producing nerve cells are
already dead, and the damage is irreversible.
In addition to its beneficial role, TNF has been a suspected player in
Parkinson's because elevated levels of it are found in post-mortem brains
and cerebrospinal fluid of people with the disease. A previous study by
other researchers found that non-steroidal anti-inflammatory drugs that
block production of TNF and related molecules can reduce the risk of
developing Parkinson's by 46 percent.
In the current study, UT Southwestern researchers injected two different
substances into the rats' brains to cause cell death in the substantia
nigra -low-dose infusion of LPS, a toxin from bacteria often used to mimic
chronic inflammation of the central nervous system, and 6-hydroxydopamine,
which kills cells by creating an overwhelming amount of reactive oxygen and
nitrogen molecules. Cell death was measured by counting neurons in stained
brain slices.
When an experimental TNF inhibitor called XENP345, designed specifically to
block soluble TNF, was also introduced into the brain, dopamine neuron death
was reduced by about half.
The same effect was found on cultured dopamine neurons exposed to either
toxin.
The researchers are now looking into why TNF inhibition did not fully
protect against cell death. For example, the drug may not have been able to
fully diffuse throughout the tissue, it might take longer to work than the
weeks allowed in the experiment, or dopamine neuron loss might also involve
processes independent of TNF.
"If an intervention could still reduce the extent or rate of cell death by
50 percent, it could make a huge difference in the life of a Parkinson's
disease patient," Dr. Tansey said.
Other UT Southwestern researchers involved in the study were graduate
students Melissa McCoy and Terina Martinez; Kelly Ruhn, research assistant
in physiology; Christine Smith, research assistant at the Mobility
Foundation Center; Dr. Barry Botterman, associate professor of cell biology;
and Dr. Keith Tansey, assistant professor of neurology. A researcher at
Xencor, Inc., which manufactures the experimental TNF inhibitory compound
XENP345, also contributed.
The work was supported by the Michael J. Fox Foundation for Parkinson's
Research.

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