Advancing ‘transposon theory of aging’
- Date:
- September 16, 2016
- Source:
- Brown University
- Summary:
- A new study provides substantial new evidence that health becomes endangered when aging cells lose control of rogue elements of DNA called transposons.
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A new study in the Proceedings of the National Academy of Sciences provides substantial new evidence that health becomes endangered when aging cells lose control of rogue elements of DNA called transposons.
A new study increases and strengthens the links that have led scientists to propose the "transposon theory of aging." Transposons are rogue elements of DNA that break free in aging cells and rewrite themselves elsewhere in the genome, potentially creating lifespan-shortening chaos in the genetic makeups of tissues.
As cells get older, prior studies have shown, tightly wound heterochromatin wrapping that typically imprisons transposons becomes looser, allowing them to slip out of their positions in chromosomes and move to new ones, disrupting normal cell function. Meanwhile, scientists have shown that potentially related interventions, such as restricting calories or manipulating certain genes, can demonstrably lengthen lifespans in laboratory animals.
"In this report the big step forward is towards the possibility of a true causal relationship," said Dr. Stephen Helfand, Brown University professor of biology and senior author of a new study in the Proceedings of the National Academy of Sciences. "So far there have been associations and suggestions that to all of us make sense, but the difference in science is that you need the data to back up your opinion."
Many lines of evidence
The new results, led by faculty investigator Jason Wood, come from several experiments that are thorough and direct in connecting the dots among weakening heterochromatin, increased transposon expression, aging and lifespan.
In one set of experiments, the team visually caught transposable elements in the act of jumping around in fruit flies as they aged. They inserted special genetic snippets into fat body cells, the equivalent of human liver and fat cells in flies that would glow bright green when specific transposable elements move about in the genome. Under the microscope the scientists could see a clear pattern of how the glowing "traps" lit up more and more as the flies aged.
The increase in transposon activity was not steady as flies grew older. "Flies reach a certain age and then it takes off more exponentially," Wood said. The data show that the timeframe in which transposable element activity really begins to increase is tightly correlated with the time when the flies start to die.
Several experiments in the paper also show that that a key intervention already known to increase lifespan, a low-calorie diet, dramatically delays the onset of increased transposon activity.
To further explore the connection between transposon expression and lifespan, the team tested the effects of manipulating genes known to improve heterochromatin repression that are not only found in flies, but also in mammals. For example, increasing expression of the gene Su(var)3-9, which helps form heterochromatin, extended maximal fly lifespan from 60 to 80 days. Increasing expression of a gene called Dicer-2, which uses the small RNA pathway to suppress transposons, added significantly to lifespan as well.
Finally, they showed that an anti-HIV drug called 3TC, which inhibits activation of transposons and their movement into new positions in the genome, can restore some lifespan to flies that have a mutation that disables Dicer-2.
More to do
For all the new results, Helfand said it's still not quite time to declare outright that transposons are a cause of aging's health effects.
"They make a strong story," he said. "We're starting to put the flesh on the skeleton."
But new experiments are planned. For example, the team will purposely encourage expression of transposable elements to see if that undermines health and lifespan. Another approach could be to use the powerful CRISPR gene editing technique to specifically disable the ability of transposable elements to mobilize within the genome. If that intervention affected lifespan, it would be telling as well, Helfand said.
The team is also continuing to develop drug interventions in hopes of increasing its efficacy and learning more about its safety.
Brown is also leading a new $9.7 million grant with New York University and the University of Rochester to further advance the study of transposons in aging.
While transposons appear to be a significant factor in aging, Helfand and Wood said, they are likely to be only part of a broader set of processes that undermine health over time.
"There are lots of potential mechanisms that influence the aging process," Wood said. "There are a lot of things going on, but we think this is one of them."
In addition to Helfand and Wood, the paper's other authors are Brian Jones, Nan Jiang, Chengyi Chang, Suzanne Hosier, Priyan Wickremesinghe, Meyrolin Garcia, Davis Hartnett, Lucas Burhenn and Nicola Neretti.
The National Institutes of Health and the American Federation for Aging Research funded the research.
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Materials provided by Brown University. Note: Content may be edited for style and length.
Journal Reference:
- Jason G. Wood, Brian C. Jones, Nan Jiang, Chengyi Chang, Suzanne Hosier, Priyan Wickremesinghe, Meyrolin Garcia, Davis A. Hartnett, Lucas Burhenn, Nicola Neretti, Stephen L. Helfand. Chromatin-modifying genetic interventions suppress age-associated transposable element activation and extend life span inDrosophila. Proceedings of the National Academy of Sciences, 2016; 201604621 DOI: 10.1073/pnas.1604621113
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