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Pamela McDonnell
Director, Media Relations
NYU Medical Center Public Affairs
212-404-3555
Email: Pamela.McDonnell@nyumc.org
Mutation Rate in a Gene on the X Chromosome
Holds Promise for Testing Cancer Risk
NEW YORK, Sept. 15 -- A new study to detect an elevated rate of
mutations in a gene on the X chromosome holds promise for developing
a test that could identify individuals at risk for developing cancer.
In the study, led by David J. Araten, M.D., Assistant Professor
in the Department of Hematology at NYU School of Medicine, the rate
of mutations in the gene, called PIG-A, was significantly higher
in individuals born with defects in the cellular machinery to repair
DNA compared to people without these genetic conditions.
The study is published in the September 15 issue of Cancer Research,
a journal of the American Association for Cancer Research.
“The mutation rate is widely believed to be a critical factor
in the development of cancer, but it has been extremely difficult
to study in human cells,” says Dr. Araten. “The ultimate
goal of our project is to develop a test for the mutation rate.
If successful, we may be able identify individuals at high risk
for cancer and find ways to decrease their risk.”
In the new study, supported by a grant from the Doris Duke Charitable
Foundation, Dr. Araten found that the chance of a mutation in the
PIG-A gene each time a cell divides ranges from about 1 in 3 million
to about 1 in 300,000 in cells from individuals without a genetic
predisposition to cancer.
Among some people with Fanconi anemia and ataxia telangiectasia,
conditions involving defects in DNA repair, which predisposes them
to cancer, the probability of mutations was close to 1 in 100,000
to 1 in 20,000 per cell division, according to the study.
In order to find the mutations in the PIG-A gene, Dr. Araten took
advantage of some unique properties of this gene that can be exploited
with an instrument called a flow cytometer, which rapidly sifts
through millions of cells to identify the rare mutants. This tool
uses a laser to light up antibodies attached to surface proteins
on cells; PIG-A mutants lack some of these proteins and do not fluoresce.
In human cells there are two functional copies for most genes and
therefore two mutations would be required to identify a rare mutant.
Because each mutation is so rare, two mutations would be unlikely
to occur in the same cell in a screening test, making detection
nearly impossible. However, the PIG-A gene is on the X-chromosome,
which is present in only one copy in male cells and there is only
one functional copy in female cells. Therefore, cells with only
a single mutation in PIG-A can be identified.
“The higher the mutation rate, the more quickly cells will
acquire the mutations that cause cancer,” says Dr. Araten.
“With a test for the mutation rate, we may be able to enroll
patients at high risk in screening programs to identify cancers
at an early, curable stage. We may also be able to develop medications
that decrease the mutation rate.”
Dr. Araten recently joined NYU School of Medicine. The study was
conducted at Memorial Sloan Kettering Cancer Center in the Departments
Human Genetics and Molecular Pharmacology.
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