Microscope image of a C. elegans roundworm expressing a fluorescent hydrogen peroxide sensor in the body wall muscle cells, indicated in pink and yellow. A second fluorescent protein is expressed in the head region, shown in white. Image provided by Daniela Knoefler
One of the most popular theories is that the accumulation of oxygen radicals over time might be the underlying culprit in aging. Oxygen radicals are chemically reactive molecules that can damage cellular components such as lipids, proteins and nucleic acids, resulting in "oxidative stress."
The possible link between oxidative stress and aging has led to the proliferation of antioxidant products ranging from dietary supplements to anti-aging creams. However, the role of oxidative stress in aging is still controversial, and the effectiveness of these antioxidants is debatable.
In a paper to be published online July 19 in the journal Molecular Cell, University of Michigan molecular biologist Ursula Jakob and her co-workers measured reactive oxygen species in worms and identified the processes affected by oxidative stress.
Using the small roundworm C. elegans, a popular model organism for aging studies, they made several surprising observations. They found that these animals are forced to deal with very high levels of reactive oxygen species long before old age. High levels of reactive oxygen were found to accumulate during early development (i.e., the childhood of the worm).
Once these worms reached adulthood the levels of reactive oxygen declined, only to surge again later in life. Intriguingly, mutant worm variants that were destined to live a very long time were able to cope much better with reactive oxygen and recovered earlier than short-lived variants.
This finding suggests that the ability to deal with and recover from early oxidative stress might be a harbinger of the lifespan of the animals, according to the U-M researchers.
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