A counterintuitive experiment has resulted in one of the longest recorded life-span extensions in any organism and opened a new door for anti-aging research in humans.There is still so much we don't know...
Scientists have known for several years that an extra copy of the SIR2 gene can promote longevity in yeast, worms and fruit flies.
That finding was covered widely and incorporated into anti-aging drug development programs at several biotechnology companies.
Now, molecular geneticists at the University of Southern California suggest that SIR2 instead promotes aging.
Their study, "Sir2 Blocks Extreme Life-Span Extension," appears in the Nov. 18 edition of the biology journal Cell. The lead author is Valter Longo, assistant professor in the Leonard Davis School of Gerontology and the USC College of Letters, Arts and Sciences.
Rather than adding copies of SIR2 to yeast, Longo's research group deleted the gene altogether.
The result was a dramatically extended life span - up to six times longer than normal - when the SIR2 deletion was combined with caloric restriction and/or a mutation in one or two genes, RAS2 and SCH9, that control the storage of nutrients and resistance to cell damage.
Human cells with reduced SIR2 activity also appear to confirm that SIR2 has a pro-aging effect, Longo said, although those results are not included in the Cell paper.
Since all mammals share key aging-related genes, the paper points to a new direction for human anti-aging research.
Longo proposes that SIR2 and possibly its counterpart in mammals, SIRT1, may block the organism from entering an extreme survival mode characterized by the absence of reproduction, improved DNA repair and increased protection against cell damage. Organisms usually enter this mode in response to starvation.
Longo proposes that SIR2 and possibly its counterpart in mammals, SIRT1, may block the organism from entering an extreme survival mode characterized by the absence of reproduction, improved DNA repair and increased protection against cell damage. Organisms usually enter this mode in response to starvation.
The long-lived organisms in Longo's experiment showed extraordinary resilience under stress.
"We hit them with oxidants, we hit them with heat," Longo said. "They are highly resistant to everything. What they're doing is basically saying, 'I cannot afford to age. I still have to generate offspring, but I don't have enough food to do it now."
Longo predicted that as molecular geneticists master the levers of aging, they will be able to design drugs that coax the body into entering chosen aspects of a starvation-response mode, such as stress resistance, even when food is plentiful.
If enough food is available, an organism might be programmed both to reproduce normally and to maximize its survival systems.
Longo urged caution in extrapolating the result to humans.
"We have been very successful with simple organisms," he said. "Naturally, mammals are complex, and it will be a great challenge to get major life-span extension."
A "really exciting" implication, Longo said, is that cells may be able to speed up their DNA repair efforts. All organisms have the ability to repair harmful mutations in their DNA, whether caused by age, radiation, diet or other environmental factors. Cancer often begins when DNA mutations outstrip a cell's ability to remain differentiated.
My body is still changing at what appears to be an unusually rapid rate for someone undergoing HRT. But it's difficult finding reliable metrics. Often, growth comes in spurts, so things like breast size aren't reliable. Measuring change of fat distribution is still very subjective, camera angles can change one's whole appearance.
Hmmm... time for another update of my blog photo soon, I think.
No comments:
Post a Comment