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FROM
http://web.mit.edu/newsoffice/2006/huntington.html
massachusetts institute of technology
news office
Research holds promise for Huntington's treatment
Anne Trafton, News Office
March 6, 2006
Researchers at MIT and
Harvard Medical School have identified a compound that
interferes with the pathogenic effects of Huntington's
disease, a discovery that could lead to development of a
new treatment for the disease.
There is no cure for
Huntington's, a neurodegenerative disorder that now
afflicts 30,000 Americans, with another 150,000 at risk.
The fatal disease, which is genetically inherited,
usually strikes in midlife and causes uncontrolled
movements, loss of cognitive function and emotional
disturbance.
"There are now some
drugs that can help with the symptoms, but we can't stop
the course of the disease or its onset," said Ruth
Bodner, lead author on a paper that appears this week in
the online edition of the Proceedings of the National
Academy of Sciences and which will appear in the print
edition March 14. Bodner is a postdoctoral fellow in
MIT's Center for Cancer Research.
The compound developed
by Bodner and others in the laboratories of MIT
Professor of Biology David Housman, Harvard Medical
School Assistant Professor Aleksey Kazantsev and Harvard
Medical School Professor Bradley Hyman might lead to a
drug that could help stop the deadly sequence of
cellular events that Huntington's unleashes.
"Depending on its
target, any one compound will probably block only a
subset of the pathogenic effects," Bodner said.
Huntington's disease is
caused by misfolded proteins, called huntingtin
proteins, that aggregate and eventually form large
clump-like "inclusions." The disease is characterized by
degeneration in the striatum, an area associated with
motor and learning functions, and the cortex. The
proteins may disrupt the function of cellular structures
known as proteasomes, which perform a "trash can"
function for the cell -- disposing of cellular proteins
that are misfolded or no longer needed, said Bodner.
Without a functional
proteasome, those cellular proteins accumulate,
poisoning brain cells and impairing patients' motor and
cognitive function.
Until now, most
researchers looking for Huntington's treatments have
focused on compounds that prevent or reverse the
aggregation of huntingtin proteins. However, recent
evidence suggests that the largest inclusions may not
necessarily be harmful and could in fact be protective,
said Bodner. So, the MIT and Harvard scientists decided
to look for compounds that actually promote the
formation of large inclusions.
The highest
concentration of protein inclusions was found when the
researchers applied a compound they called B2 to cells
cultivated in the laboratory. The compound also had a
strong protective effect against proteasome disruption,
thus blocking one of the toxic effects of the huntingtin
protein.
The B2 compound also
promoted large inclusions and showed a protective effect
in a cellular model of Parkinson's disease, another
neurodegenerative disorder caused by misfolded proteins.
In Parkinson's disease,
the mutant proteins destroy dopamine-producing cells in
the substantia nigra. Normally, the dopamine transmits
signals to the corpus striatum, allowing muscles to make
smooth, controlled movements. When those
dopamine-producing cells die, Parkinson's patients
exhibit the tremors that are characteristic of the
disease.
The researchers are now
working on finding a more potent version of the compound
that could be tested in mice.
This
work was funded by the Hereditary Disease Foundation,
Massachusetts Biotechnology Research Council, National
Institutes of Health, American Parkinson's Disease
Association and the MassGeneral Institute for
Neurodegenerative Disease. |
