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Christine Guilfoy
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Naked Mole-Rat Unfazed By Oxidative Stress
Physiology of aging is more complicated than oxidation, antioxidants
Virginia Beach,
VA (October 9, 2006) – The long-lived naked mole-rat shows much
higher levels of oxidative stress and damage and less robust repair
mechanisms than the short-lived mouse, findings that could change the
oxidative stress theory of aging.
The new study comparing the naked mole-rat, which has a
life span of 28 years, and the mouse, which has a lifespan of three years,
will be presented Oct. 8 at The American Physiological Society
conference, Comparative Physiology 2006: Integrating Diversity. The
results fly in the face of the oxidative stress theory of aging, which holds
that damage caused by oxidative stress is a significant contributor to the
aging process.
Under this theory, naked mole-rats should be better at
preventing or repairing oxidative stress than their much shorter-lived
cousin, the mouse. The study, “High oxidative damage levels in the
longest-living rodent, the naked mole-rat,” was done by Blazej Andziak and
Rochelle Buffenstein, of The City College of New York, Timothy P. O’Connor,
of Weill Medical College of Cornell University, and Asish P. Chaudhiri and
Holly Van Remmen of the University of Texas Health Science Center, San
Antonio. The study was presented during a poster session on October 8.
Don’t toss the oxidative stress theory of aging out the
window just yet, but prepare to modify it, said Buffenstein, the senior
author. Her team suspects that the naked mole-rat’s longevity stems from its
ability to defend against acute bouts of oxidative stress. That is, the kind
of oxidation that happens because of an unusual occurrence rather than the
kind that happens as a result of normal aerobic respiration.
For example, when hydrogen peroxide is added to a
culture containing naked mole-rat fibroblast cells, they remain viable and
appear to repair the acute damage more rapidly than shorter-lived animals,
explained Buffenstein.
What is old age?
We know that all organisms age and die. It’s such an
inevitable course of events that most of us spend more time thinking about
how to hide the wrinkles and gray hair than we do about what our cells are
actually doing to usher us to the end. Physiologists are looking at
molecules and cells to understand this process.
One way to look at aging is to compare closely related
organisms with different life spans. That’s why it made sense to compare
mole-rats and mice: They’re the same size and they’re rodents, but the
mole-rat lives to 28 years, about nine-times longer than the mouse.
“Mole-rats must have something happening at the
biochemical level to allow them to do this,” said Andziak, the study’s lead
author. Specifically, he wanted to see if oxidative stress could explain the
difference.
Oxidative stress occurs during metabolism when oxygen
(O2) splits into single oxygen atoms, known as free radicals.
These oxygen atoms may circulate by themselves, or combine with other atoms
and molecules to form reactive oxygen species (ROS). ROS can damage DNA,
lipids and proteins thus impairing normal cellular function. Antioxidants
help to neutralize ROS, thus restricting the potential of ROS to damage
biological molecules.
Mole-rat has more
oxidative stress
The study compared two-year-old naked mole-rats to
four-month-old mice. The researchers chose those ages so that the animals
would be equivalent ages relative to their maximum lifespans, Andziak said.
First, the researchers compared the ratio of reduced
glutathione, an antioxidant, to oxidized glutathione. As the body uses up
its reduced glutathione to fight oxidative stress, the pool of oxidized
glutathione increases. This ratio of reduced to oxidized glutathione is thus
an indicator of oxidative stress: the greater the ratio, the less oxidative
stress has occurred. The oxidative stress theory predicts that in naked
mole-rats this ratio will be higher than in mice.
When the researchers measured this ratio in the liver,
they found that the opposite was true. Mole-rats had less reduced
glutathione and thus a lower ratio, indicating the mole-rat experienced much
more oxidative stress. These results fit with the findings of a previous
study in which Andziak found that naked mole-rats did not have superior
antioxidant capacity when compared to mice. Mole-rats had much lower
activity of the ubiquitous antioxidant enzyme, cellular glutathione
peroxidase.
Mole-rat shows greater
oxidative damage
The researchers next looked at how much damage the
oxidation had caused. It is possible, they reasoned, that the mole-rat
suffers greater oxidative stress, but its physiology had somehow prevented
damage from occurring.
The researchers measured oxidative damage in lipids,
DNA and proteins and found that naked mole-rats showed much greater levels
of damage to each of these biological molecules, in all tissues assayed,
when compared to mice. The study found multiple signs of lipid damage: The
level of isoprostanes found in the urine was 10 times higher in the naked
mole-rat, the level of malondialdehyde in liver tissue was twice as high and
isoprostane levels in heart tissue was two-and-a-half times the level of the
mice.
The researchers found significantly more protein damage
in the kidney and in the heart. DNA damage was greater in the kidney and
liver.
“All of the classical measures of oxidative stress are
higher in the mole-rat,” Andziak concluded. “Given that naked mole-rats live
an order of magnitude longer than predicted based on their body size, our
findings strongly suggest that mechanisms other than attenuated oxidative
stress may explain the impressive longevity of this species.”
Next steps
The next step is to determine how the mole-rats manage
to live with the damage caused by oxidative stress. Buffenstein said she
suspects that the mole-rat is able to fend off the occasional oxidative
insult that can occur, and that may be more important than what happens with
the steady-state levels of oxidative stress that result from normal
metabolic activity.
Buffenstein theorizes that the naked mole-rats in her
laboratory suffer higher levels of oxidative stress than they would in their
natural underground habitat, where they encounter much lower levels of
oxygen. But this exposure at an early age may provide some protection
against acute oxidative stress and may be of considerable importance in
their resistance to bursts oxidative stressors throughout their lives, she
said.
“The naked mole-rat, with its surprisingly long
lifespan and remarkably delayed aging, seems like the perfect model to
provide answers about how we age and how to retard the aging process,”
Buffenstein said. “This animal may one day provide the clues to how we can
significantly extend life.”
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