| What's
New:
New
therapeutic target identified in inherited brain tumor
disorder
By
Michael Purdy
Oct.
31, 2005 — Researchers studying a mouse model of neurofibromatosis
1 (NF1), a genetic condition that causes childhood brain
tumors, have found their second new drug target in a
year, a protein called methionine aminopeptidase-2 (MetAP2).
An
established drug, fumagillin, is already known to suppress
the activity of MetAP2. Researchers at Washington University
School of Medicine in St. Louis showed that fumagillin
significantly slowed the rapid proliferation of cultured
mouse brain cells that resulted from the loss of Nf1,
the gene that causes neurofibromatosis 1. Evaluation
of the ability of this class of drugs to control brain
tumor growth in small animal models is planned.
"This
agent and others like it have already been in clinical
trials as treatments for other tumors, so if we find
that fumagillin inhibits brain tumor growth in preclinical
studies, it will be a much smaller leap to using these
compounds in patients with NF1," says senior investigator
David H. Gutmann, M.D., Ph.D., the Donald O. Schnuck
Family Professor of Neurology at Washington University
School of Medicine in St. Louis and co-director of the
neuro-oncology program at the Siteman Cancer Center.
Neurofibromatosis
1 affects more than 100,000 people in the United States
and is one of the most common tumor predisposition syndromes.
Gutmann and his colleagues discovered that abnormally
high levels of MetAP2 may be a distinguishing characteristic
of brain tumors in patients with NF1. Analyses of other
similar brain tumors did not reveal the high MetAP2
levels characteristic of tumors caused by NF1.
To
identify MetAP2, Gutmann collaborated with Jason D.
Weber, Ph.D., assistant professor of medicine and of
cellular biology and anatomy at the Washington University
Neurofibromatosis Center. The center facilitates multidisciplinary
neurofibromatosis research and is dedicated to developing
better treatments to improve the lives of patients affected
with neurofibromatosis.
Researchers
in Gutmann's and Weber's laboratories took samples of
cerebrospinal fluid from wild-type mice and a genetically
engineered mouse model of NF1. Using a technique called
proteomic analysis, they looked at the number of times
copies of any given protein were found in the fluid.
The goal was to identify proteins whose levels were
different in the spinal fluid of the mouse model compared
to normal mice.
Gutmann
and Weber previously used the genetically engineered
mice for a proteomic analysis of astrocytes, the brain
cells that often become cancerous in patients with NF1.
That led to the finding that proteins in the mammalian
target of rapamycin pathway (mTOR) are overactivated,
suggesting that mTOR may be a promising target for future
chemotherapy for NF1-associated brain tumors.
The
new study's results suggest that MetAP2 may be directly
regulated by neurofibromin, the protein produced by
the Nf1 gene.
Like
the mTOR pathway proteins, MetAP2 is normally active
in processes that regulate the production of proteins
from RNA. Gutmann and Weber plan additional studies
to determine how increased MetAP2 expression enables
astrocyte growth and brain tumor development.
"The
availability of a mouse model of NF1-associated brain
tumors allows us to conduct experiments that we could
never perform in humans that have already broadened
our understanding of the function of the Nf1 gene,"
Gutmann says. "It's highly likely that these new
insights will lead to new treatments for NF1 patients."
Dasgupta
B, Yi Y, Hegedus B, Weber JD, Gutmann DH. Cerebrospinal
fluid proteomic analysis reveals dysregulation of methionine
aminopeptidase-2 expression in human and mouse neurofibromatosis
1-associated glioma. Cancer Research, November 1, 2005.
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