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Model 'Teori
permainan' mengungkapkan saat-saat yang rentan untuk produksi energi sel-sel
kanker metastasis
'Game theory' model reveals vulnerable moments for metastatic cancer
cells' energy production
Date:
July 15,
2014
Source:
Johns Hopkins Medicine
Summary:
Cancer’s no game, but researchers are borrowing ideas
from evolutionary game theory to learn how cells cooperate within a tumor to
gather energy. Their experiments, they say, could identify the ideal time to
disrupt metastatic cancer cell cooperation and make a tumor more vulnerable to
anti-cancer drugs.
......................
Cancer's no game, but researchers at Johns Hopkins are
borrowing ideas from evolutionary game theory to learn how cells cooperate
within a tumor to gather energy. Their experiments, they say, could identify
the ideal time to disrupt metastatic cancer cell cooperation and make a tumor
more vulnerable to anti-cancer drugs.
"The
reality is that we still can't cure metastatic cancer that has spread from its
primary organ and game theory adds to our efforts to attack the problem,"
says Kenneth J. Pienta, M.D., the Donald S. Coffey Professor of Urology at the
Johns Hopkins Brady Urological Institute, and director of the Prostate Cancer
Program at the Johns Hopkins Kimmel Cancer Center. A description of the work
appears in a June 20 report in the journal Interface Focus.
Game theory
is a mathematical study of strategic decision-making, and has been widely used
to predict conflict and cooperation between individuals and even nations, but
increasingly is applied to forecasting cell-to-cell interactions in biology
with an ecological perspective. Tumors contain a variety of cells shifting
between cooperative-like to competitive-like states, said Ardeshir Kianercy,
Ph.D., a postdoctoral researcher in Pienta's lab. "To study tumor cells in
isolation is not enough," he noted. "It makes sense to study their
behavior and relationship with other cells and how they co-evolve
together."
In their
research, the Johns Hopkins scientists used mathematical and computer tools to
set up game parameters based on biological interactions between two types of tumor
cells, one oxygen-rich and the other oxygen-poor. Cells within a tumor engage
in different types of energy metabolism depending on how close they are to an
oxygen-rich blood supply. Tumor cells in oxygen-poor areas use the sugar
glucose to produce energy and, as part of the process, release a compound
called lactate. Oxygen-rich cells use this lactate in a different type of
energy metabolism process and, as a result, release glucose that can be used by
oxygen-poor cells to burn for their own energy.
Generally,
the process is an efficient partnership that can help a tumor thrive, but the
partnership is always changing as the tumor cells mutate. The mutation rate
influences the strength of the energy partnerships between the oxygen-rich and
oxygen-poor cells and levels of glucose and lactate production and uptake,
according to the scientists.
Applying
game theory calculations that accounted for the tumor cells' mutation rates and
potential glucose and lactate levels, the scientists found that within certain
ranges of mutation rates, "there are critical transitions when a tumor
suddenly switches between different types of energy metabolic strategies,"
Kianercy said. This switch in the playbook of energy production tactics may
happen when tumors progress and spread.
The
scientists think tumors might be especially vulnerable within this window of
strategy-switching, making it a potentially ideal time for clinicians to
disrupt the tumor's environment and wreck the partnership among its cells.
Some tumor
cells, for instance, may provoke the normal cells around them to release
lactate for fuel. A therapy that disrupts lactate transport to the tumor cells
during a critical transition "could push a tumor to a condition where
cells are not cooperating with each other," Kianercy explained. "And
if they become non-cooperative, they are most likely to stay in that state and
the tumor may become more vulnerable to anti-cancer therapies."
Pienta said
it isn't clear yet whether this type of metabolic cooperation occurs in all
tumors. But the game theory model used in the study gives scientists a new way
to understand how cancers may progress. "We ultimately want to test how we
can interrupt this process with therapies for cancer patients," he said.
Robert
Veltri, Ph.D., of the Brady Urological Institute was also involved in the
study, which was supported by the National Institutes of Health's National
Cancer Institute (U54CA143803).
Story
Source:
The above
story is based on materials provided by Johns Hopkins Medicine. Note: Materials may be edited
for content and length.
Journal
Reference:
- A. Kianercy, R. Veltri, K. J. Pienta. Critical transitions in a game theoretic model of tumour metabolism. Interface Focus, 2014; 4 (4): 20140014 DOI: 10.1098/%u200Brsfs.2014.0014
