New research from the USC Viterbi School of
Engineering could be key to our understanding of how the aging process
works. The findings potentially pave the way for better cancer
treatments and revolutionary new drugs that could vastly improve human
health in the twilight years.
Cells illustration (stock image).
Credit: © Anusorn / Adobe Stock
The work, from Assistant Professor of Chemical Engineering and
Materials Science Nick Graham and his team in collaboration with Scott
Fraser, Provost Professor of Biological Sciences and Biomedical
Engineering, and Pin Wang, Zohrab A. Kaprielian Fellow in Engineering,
was recently published in the Journal of Biological Chemistry.
"To drink from the fountain of youth, you have to figure out where
the fountain of youth is, and understand what the fountain of youth is
doing," Graham said. "We're doing the opposite; we're trying to study
the reasons cells age, so that we might be able to design treatments for
better aging."
What causes cells to age?
To achieve this, lead author Alireza Delfarah, a graduate student in
the Graham lab, focused on senescence, a natural process in which cells
permanently stop creating new cells. This process is one of the key
causes of age-related decline, manifesting in diseases such as
arthritis, osteoporosis and heart disease.
"Senescent cells are effectively the opposite of stem cells, which
have an unlimited potential for self-renewal or division," Delfarah
said. "Senescent cells can never divide again. It's an irreversible
state of cell cycle arrest."
The research team discovered that the aging, senescent cells stopped
producing a class of chemicals called nucleotides, which are the
building blocks of DNA. When they took young cells and forced them to
stop producing nucleotides, they became senescent, or aged.
"This means that the production of nucleotides is essential to keep
cells young," Delfarah said. "It also means that if we could prevent
cells from losing nucleotide synthesis, the cells might age more
slowly."
Graham's team examined young cells that were proliferating robustly
and fed them molecules labeled with stable isotopes of carbon, in order
to trace how the nutrients consumed by a cell were processed into
different biochemical pathways.
Scott Fraser and his lab worked with the research team to develop 3D
imagery of the results. The images unexpectedly revealed that senescent
cells often have two nuclei, and that they do not synthesize DNA.
Before now, senescence has primarily been studied in cells known as
fibroblasts, the most common cells that comprised the connective tissue
in animals. Graham's team is instead focusing on how senescence occurs
in epithelial cells, the cells that line the surfaces of the organs and
structures in the body and the type of cells in which most cancers
arise.
Graham said that senescence is most widely known as the body's
protective barrier against cancer: When cells sustain damage that could
be at risk of developing into cancer, they enter into senescence and
stop proliferating so that the cancer does not develop and spread.
"Sometimes people talk about senescence as a double-edged sword, that
it protects against cancer, and that's a good thing," Graham said. "But
then it also promotes aging and diseases like diabetes, cardiac
dysfunction or atherosclerosis and general tissue dysfunction," he said.
Graham said the goal was not to completely prevent senescence, because that might unleash cancer cells.
"But then on the other hand, we would like to find a way to remove
senescent cells to promote healthy aging and better function," he said.
Graham said that the team's research has applications in the emerging
field of senolytics, the development of drugs that may be able to
eliminate aging cells. He said that human clinical trials are still in
early stages, but studies with mice have shown that by eliminating
senescent cells, mice age better, with a more productive life span.
"They can take a mouse that's aging and diminishing in function,
treat it with senolytic drugs to eliminate the senescent cells, and the
mouse is rejuvenated. If anything, it's these senolytic drugs that are
the fountain of youth," Graham said.
He added that in order for successful senolytic drugs to be designed,
it was important to identify what is unique about senescent cells, so
that drugs won't affect the normal, non-senescent cells.
"That's where we're coming in -- studying senescent cell metabolism
and trying to figure out how the senescent cells are unique, so that you
could design targeted therapeutics around these metabolic pathways,"
Graham said.
Journal Reference:
- Alireza Delfarah, Sydney Parrish, Jason A. Junge, Jesse Yang, Frances Seo, Si Li, John Mac, Pin Wang, Scott E. Fraser, Nicholas A. Graham. Inhibition of nucleotide synthesis promotes replicative senescence of human mammary epithelial cells. Journal of Biological Chemistry, 2019; 294 (27): 10564 DOI: 10.1074/jbc.RA118.005806
Courtesy: ScienceDaily
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