Turning Off the "Aging Genes"
by Staff Writers Tel Aviv, Israel (SPX) Jan 03, 2014
Addit. INFO - by DON PORTER - I am Monitoring ALL activities in DNA, STEM CELL, GENE Research and Related, as interesting strides are being made worldwide !by Staff Writers Tel Aviv, Israel (SPX) Jan 03, 2014
Computer algorithm developed by TAU researchers identifies
genes that could be transformed to stop the aging process. Restricting calorie
consumption is one of the few proven ways to combat aging. Though the
underlying mechanism is unknown, calorie restriction has been shown to prolong
lifespan in yeast, worms, flies, monkeys, and, in some studies, humans.
Now Keren Yizhak, a doctoral student in Prof. Eytan Ruppin's
laboratory at Tel Aviv Univ's. Blavatnik School of Computer Science, and her
colleagues have developed a computer algorithm that predicts which genes can be
"turned off" to create the same anti-aging effect as calorie
restriction. The findings, reported in Nature Communications, could lead to the
development of new drugs to treat aging. Researchers from Bar-Ilan University
collaborated on the research.
"Most algorithms try to find drug targets that kill
cells to treat cancer or bacterial infections," says Yizhak. "Our
algorithm is the first in our field to look for drug targets not to kill cells,
but to transform them from a diseased state into a healthy one."
A digital
laboratory
Prof. Ruppin's lab is a leader in the growing field of genome-scale metabolic modeling or GSMMs. Using mathematical equations and computers, GSMMs describe the metabolism, or life-sustaining, processes of living cells. Once built, the individual models serve as digital laboratories, allowing formerly labor-intensive tests to be conducted with the click of a mouse.
Prof. Ruppin's lab is a leader in the growing field of genome-scale metabolic modeling or GSMMs. Using mathematical equations and computers, GSMMs describe the metabolism, or life-sustaining, processes of living cells. Once built, the individual models serve as digital laboratories, allowing formerly labor-intensive tests to be conducted with the click of a mouse.
Yizhak's algorithm, which she calls a "metabolic
transformation algorithm," or MTA, can take information about any two
metabolic states and predict the environmental or genetic changes required to
go from one state to the other.
"Gene expression" is the measurement of the
expression level of individual genes in a cell, and genes can be "turned
off" in various ways to prevent them from being expressed in the cell. In
the study, Yizhak applied MTA to the genetics of aging.
After using her custom-designed MTA to confirm previous
laboratory findings, she used it to predict genes that can be turned off to
make the gene expression of old yeast look like that of young yeast. Yeast is
the most widely used genetic model because much of its DNA is preserved in
humans.
Some of the genes that the MTA identified were already
known to extend the lifespan of yeast when turned off. Of the other genes she
found, Yizhak sent seven to be tested at a Bar-Ilan University laboratory. Researchers
there found that turning off two of the genes, GRE3 and ADH2, in actual,
non-digital yeast significantly extends the yeast's lifespan.
"You would expect about three percent of yeast's
genes to be lifespan-extending," said Yizhak. "So achieving a 10-fold
increase over this expected frequency, as we did, is very encouraging."
Hope for humans
Since MTA provides a systemic view of cell metabolism, it can also shed light on how the genes it identifies contribute to changes in genetic expression. In the case of GRE3 and ADH2, MTA showed that turning off the genes increased oxidative stress levels in yeast, thus possibly inducing a mild stress similar to that produced by calorie restriction.
Since MTA provides a systemic view of cell metabolism, it can also shed light on how the genes it identifies contribute to changes in genetic expression. In the case of GRE3 and ADH2, MTA showed that turning off the genes increased oxidative stress levels in yeast, thus possibly inducing a mild stress similar to that produced by calorie restriction.
As a final test, Yizhak applied MTA to human metabolic
information. MTA was able to identify a set of genes that can transform
40-to-70 percent of the differences between the old and young information from
four different studies. While currently there is no way to verify the results
in humans, many of these genes are known to extend lifespan in yeast, worms,
and mice.
Next, Yizhak will study whether turning off the genes
predicted by MTA prolongs the lifespan of genetically engineered mice.
One day, drugs could be developed to target genes in
humans, potentially allowing us to live longer. MTA could also be applied to
finding drug targets for disorders where metabolism plays a role, including
obesity, diabetes, neurodegenerative disorders, and cancer.
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