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Landmark study opens door to new Cancer,
Aging Treatments
Newswise — Researchers at The Wistar
Institute have deciphered the structure of
the active region of telomerase, an enzyme
that plays a major role in the development
of nearly all human cancers.
The landmark achievement opens the door to
the creation of new, broadly effective
cancer drugs, as well as anti-aging
therapies.
Researchers have attempted for more than a
decade to find drugs that shut down
telomerase—widely considered the No. 1
target for the development of new cancer
treatments—but have been hampered in large
part by a lack of knowledge of the enzyme’s
structure.
The findings, published online August 31 in
Nature, should help researchers in
their efforts to design effective telomerase
inhibitors, says Emmanuel Skordalakes,
Ph.D., assistant professor in Wistar’s Gene
Expression and Regulation Program, who led
the study.
“Telomerase is an ideal target for
chemotherapy because it is active in almost
all human tumors, but inactive in most
normal cells,” Skordalakes says.
“That means a drug that deactivates
telomerase would likely work against all
cancers, with few side effects.”
The study elucidates the active region of
telomerase and provides the first
full-length view of the telomerase
molecule’s critical protein component.
It reveals surprising details, at the atomic
level, of the enzyme’s configuration and how
it works to replicate the ends of
chromosomes—a process critical to both tumor
development and the aging process.
Achieving immortality
In humans, telomerase adds multiple repeats
of a short DNA sequence to the ends of
chromosomes, known as telomeres, thus
preventing damage and the loss of genetic
information during cell division.
When telomerase is dormant, telomeres
shorten each time a cell divides, leading
eventually to genetic instability and cell
death. By preserving chromosomes’ integrity,
telomerase allows cells to continue living
and dividing.
The enzyme is active in cells that multiply
frequently, such as embryonic stem cells,
but is switched off almost entirely in
normal adult cells to prevent the dangers of
runaway cell proliferation.
Cancer cells, however, often regain the
ability to activate telomerase, which has
been implicated in 90 percent of human
tumors. The enzyme permits cells to
replicate indefinitely and achieve the
cellular “immortality” that is the hallmark
of cancer. Deactivating telomerase would
stop tumor growth.
In addition to its role in cancer,
telomerase holds significant implications
for the development of therapies to combat
aging and other age-related diseases.
Finding ways to activate telomerase under
controlled conditions and allow some cells
to begin dividing again could result in
healthier, younger-looking tissue that lives
longer.
An elusive enzyme
Telomerase is a complex structure made up of
multiple protein domains and a stretch of
RNA, which contains the template the enzyme
uses to synthesize telomeres.
Last year, Skordalakes and his team solved
the structure of a key segment of the
molecule—the so-called TRBD domain, where
RNA binding occurs.
However, the complexity of telomerase has
proved a roadblock to determining the
enzyme’s overall architecture—a goal pursued
by researchers worldwide for more than 15
years.
To perform the necessary studies, scientists
first must gather large quantities of the
enzyme in a specific conformation. Because
the complex structure of telomerase most
likely allows it to change configuration,
that process has been challenging,
Skordalakes says.
To find sufficient quantities of the enzyme
for the study, Skordalakes and his team
looked beyond commonly relied-on sources
such as humans and yeast.
By screening a wide variety of organisms,
including protozoa and insects, they
discovered that a gene from the red flour
beetle could produce telomerase in copious
amounts, and a stable form.
“That was really the breakthrough,”
Skordalakes says. “Once we found that the
gene from this organism expressed the
protein in the quantities we needed, we were
able to move quickly.”
The researchers used X-ray crystallography,
a technique that analyzes the diffraction
patterns of X-rays beamed at crystals of a
molecule, to determine the three-dimensional
structure of the enzyme’s active region—the
catalytic component called telomerase
reverse transcriptase protein, or TERT.
The study revealed surprising features,
including the fact that the molecule’s three
domains are organized into a doughnut shape,
an unexpected configuration. Knowledge of
the structure allowed the researchers to
create a model of the enzyme’s function.
“It’s extremely exciting,” Skordalakes says.
“For the first time, we can see how
telomerase assembles at the end of
chromosomes to initiate telomere
replication.”
Looking ahead
Skordalakes plans to further study TERT and
search for new telomerase inhibitors that
could become cancer therapies. He also will
look at modifying existing drugs.
Previous attempts to target telomerase have
fallen flat, but knowledge of the enzyme’s
structure will help researchers to determine
the limitations of existing agents and make
them more effective.
Skordalakes began his studies of telomerase
when he joined The Wistar Institute in 2006
and established his first laboratory.
“I’ve always been interested in
understanding, on a molecular level, the
function of protein nucleic acid assemblies
and using that information in the treatment
of human disease,” he says.
“Telomerase, because of its important role
in cancer and aging, was an obvious target
for me.”
He says though the process was frustrating
at times, his team was determined to solve
the structure.
“It required a lot of perseverance and
effort, but we really wanted to do this,” he
says.
Wistar’s Andrew J. Gillis and Anthony P.
Schuller assisted with the study.
The research was supported in part by the
Commonwealth Universal Research Enhancement
Program of the Pennsylvania Department of
Health and the Ellison Medical Foundation.
The Wistar Institute is an international
leader in biomedical research with special
expertise in cancer research and vaccine
development.
Founded in 1892 as the first independent nonprofit
biomedical research institute in the
country, Wistar has long held the
prestigious Cancer Center designation from
the National Cancer Institute. The Institute
works actively to ensure that research
advances move from the laboratory to the
clinic as quickly as possible. The Wistar
Institute: Today’s Discoveries – Tomorrow’s
Cures. On the Web at
http://www.wistar.org.
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