In cancer cells,
normal mechanisms governing the cellular life cycle have gone haywire. Cancer
cells continue to divide indefinitely, without ever dying off, thus creating
rapidly growing tumors.
Swiss scientists have discovered a protein complex
involved this deregulated process, and hope to be able to exploit it to stop
tumor formation in its tracks.
All our cells come equipped with an automatic
self-destruct mechanism; they are programmed to die after a certain number of
divisions. This internal
clock is of great interest to cancer researchers, because most forms of
cancer exhibit a defect in this innate timing mechanism. Cancer cells continue
to divide indefinitely, long past the moment at which a normal cell would
self-destruct. A team of researchers from professor Joachim Lingner’s
laboratory at EPFL has learned how this defect is regulated in a tumor. Post-doctoral researcher
Liuh-Yow Chen led the team in publishing an article appearing in the
journal Nature on the 4th of July 2012. Their hope is that the
discovery will provide new targets for drug therapies to combat the deadly
disease.
Cellular immortality, which is responsible for cancer
formation, hearkens back to a critical function of the cells of the developing
embryo. At the ends of every chromosome there is a special sequence of DNA
known as a telomere, whose length is governed by the telomerase enzyme. This
sequence represents the lifespan of the cell. Every time the cell divides, it
is shortened, and when the telomere finally runs out, the cell dies. This
reserve allows most cells to divide about 60 times – sufficient for the cell to
play its given role in the organism, without succumbing to inevitable genetic
mutation.
Cellular immortality, cancer’s common denominator
Normally, once the embryonic stage is completed, our
cells stop producing telomerase – with the notable exception of somatic stem
cells. But occasionally, a cell will mutate and reactivate production of the
enzyme, so that when the cell divides, the telomere gets longer instead of
shorter. This is what gives cancer cells their immortality.
“This mutation, on its own, is not enough to cause
cancer,” explains Joachim Lingner, co-author and head of the lab. “But cellular
immortality is a critical element in tumor formation in
90% of known cancers.” Researchers the world over hope to be able to stop the
runaway growth of cancer cells by targeting this mechanism with drug therapy.
But interestingly enough, even in a cancer cell the
telomere doesn’t grow indefinitely long. With each cell division it loses some
60 nucleotides, like most cells, but then the activated telomerase causes it to
gain just as many back. The internal clock is reset to zero, and the cell
becomes immortal. But there’s one interesting question here: What is stopping
the telomere from getting indefinitely long?
Stopping the clock with three proteins
The EPFL team was able to provide an answer to this
question; they identified three proteins that join together and then attach
themselves to the telomere. A bit like a lid on a pot, this protein complex
prevents telomerase from acting on the telomere. But in the cancer cell, their
timing is off – their involvement takes place too late.
“If we could cause these proteins to act earlier, or if
we could recreate a similar mechanism, the cancer cell
would no longer be immortal,” explains Ligner. The cancer cells would
die a normal death. Clinical applications are still a long way off, however, he
insists. “Our discovery may allow us to identify potential targets - for
example, a secondary protein to
which these three proteins also attach. But right now our work is still in the
basic research stages.”
Provided by Ecole
Polytechnique Federale de Lausanne
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