TELOMERE EXTENSION TURNS BACK AGING CLOCK IN CULTURED HUMAN CELLS
A new procedure can quickly
and efficiently increase the length of human telomeres, the protective caps on
the ends of chromosomes that are linked to aging and disease, according to
scientists at the Stanford University School of Medicine.
Treated cells behave
as if they are much younger than untreated cells, multiplying with abandon in
the laboratory dish rather than stagnating or dying.
The procedure, which
involves the use of a modified type of RNA, will improve the ability of
researchers to generate large numbers of cells for study or drug development,
the scientists say. Skin cells with telomeres lengthened by the procedure were
able to divide up to 40 more times than untreated cells. The research may point
to new ways to treat diseases caused by shortened telomeres.
Telomeres are the
protective caps on the ends of the strands of DNA called chromosomes, which
house our genomes. In young humans, telomeres are about 8,000-10,000
nucleotides long. They shorten with each cell division, however, and when they
reach a critical length the cell stops dividing or dies. This internal
"clock" makes it difficult to keep most cells growing in a laboratory
for more than a few cell doublings.
'Turning back the
internal clock'
"Now we have
found a way to lengthen human telomeres by as much as 1,000 nucleotides,
turning back the internal clock in these cells by the equivalent of many years
of human life," said Helen Blau, PhD, professor of microbiology and
immunology at Stanford and director of the university's Baxter Laboratory for
Stem Cell Biology. "This greatly increases the number of cells available
for studies such as drug testing or disease modeling."
A paper describing the
research was published today in the FASEB Journal. Blau, who also
holds the Donald E. and Delia B. Baxter Professorship, is the senior author.
Postdoctoral scholar John Ramunas, PhD, of Stanford shares lead authorship with
Eduard Yakubov, PhD, of the Houston Methodist Research Institute.
The researchers used
modified messenger RNA to extend the telomeres. RNA carries instructions from
genes in the DNA to the cell's protein-making factories. The RNA used in this
experiment contained the coding sequence for TERT, the active component of a
naturally occurring enzyme called telomerase. Telomerase is expressed by stem
cells, including those that give rise to sperm and egg cells, to ensure that
the telomeres of these cells stay in tip-top shape for the next generation.
Most other types of cells, however, express very low levels of telomerase.
Transient effect an
advantage
The newly developed
technique has an important advantage over other potential methods: It's
temporary. The modified RNA is designed to reduce the cell's immune response to
the treatment and allow the TERT-encoding message to stick around a bit longer
than an unmodified message would. But it dissipates and is gone within about 48
hours. After that time, the newly lengthened telomeres begin to progressively
shorten again with each cell division.
The transient effect
is somewhat like tapping the gas pedal in one of a fleet of cars coasting
slowly to a stop. The car with the extra surge of energy will go farther than
its peers, but it will still come to an eventual halt when its forward momentum
is spent. On a biological level, this means the treated cells don't go on to
divide indefinitely, which would make them too dangerous to use as a potential
therapy in humans because of the risk of cancer.
The researchers found
that as few as three applications of the modified RNA over a period of a few
days could significantly increase the length of the telomeres in cultured human
muscle and skin cells. A 1,000-nucleotide addition represents a more than 10
percent increase in the length of the telomeres. These cells divided many more
times in the culture dish than did untreated cells: about 28 more times for the
skin cells, and about three more times for the muscle cells.
"We were
surprised and pleased that modified TERT mRNA worked, because TERT is highly
regulated and must bind to another component of telomerase," said Ramunas.
"Previous attempts to deliver mRNA-encoding TERT caused an immune response
against telomerase, which could be deleterious. In contrast, our technique is
nonimmunogenic. Existing transient methods of extending telomeres act slowly,
whereas our method acts over just a few days to reverse telomere shortening
that occurs over more than a decade of normal aging. This suggests that a
treatment using our method could be brief and infrequent."
Potential uses for
therapy
"This new
approach paves the way toward preventing or treating diseases of aging,"
said Blau. "There are also highly debilitating genetic diseases associated
with telomere shortening that could benefit from such a potential treatment."
Blau and her
colleagues became interested in telomeres when previous work in her lab showed
that the muscle stem cells of boys with Duchenne muscular dystrophy had
telomeres that were much shorter than those of boys without the disease. This
finding not only has implications for understanding how the cells function --
or don't function -- in making new muscle, but it also helps explain the
limited ability to grow affected cells in the laboratory for study.
The researchers are
now testing their new technique in other types of cells.
"This study is a
first step toward the development of telomere extension to improve cell
therapies and to possibly treat disorders of accelerated aging in humans,"
said John Cooke, MD, PhD. Cooke, a co-author of the study, formerly was a
professor of cardiovascular medicine at Stanford. He is now chair of
cardiovascular sciences at the Houston Methodist Research Institute.
"We're working to
understand more about the differences among cell types, and how we can overcome
those differences to allow this approach to be more universally useful,"
said Blau, who also is a member of the Stanford Institute for Stem Cell Biology
and Regenerative Medicine.
"One day it may
be possible to target muscle stem cells in a patient with Duchenne muscular
dystrophy, for example, to extend their telomeres. There are also implications
for treating conditions of aging, such as diabetes and heart disease. This has
really opened the doors to consider all types of potential uses of this
therapy."
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