Conclusive evidence telomeres do not dictate aging and lifespan

X-Message-Number: 26786
From: "Basie" <>
Subject: Conclusive evidence telomeres do not dictate aging and lifespan
Date: Mon, 8 Aug 2005 14:50:44 -0400

Tiny Roundworm's Telomeres Help Scientists To Tease Apart Different Types Of 
Aging
The continual and inevitable shortening of telomeres, the protective "caps" 
at the end of all 46 human chromosomes, has been linked to aging and 
physical decline. Once they are gone, so are we. But there are more ways 
than one to grow old.

Researchers at Salk Institute for Biological Studies demonstrate for the 
first time that the roundworm Caenorhabditis elegans succumbs to the trials 
of old age although its telomeres are still long, and moves with a youthful 
spring in its crawl despite short telomeres, they report in PLoS Genetics, 
available online now.

In the past, preventing telomere shortening has often been portrayed as the 
key to preventing aging and living longer. In their study, Salk scientists 
Jan Karlseder, an assistant professor in the Regulatory Biology Laboratory, 
and Andrew Dillin, an assistant professor in the Molecular and Cell Biology 
Laboratory, provide a much more nuanced view of telomeres and the process of 
cellular and organismal aging.

"Some long-lived species like humans have telomeres that are much shorter 
than the telomeres in species like mice, which live only a few years. Nobody 
yet knows why. But now we have conclusive evidence that telomeres alone do 
not dictate aging and lifespan," says Karlseder.

Each time a cell divides, its telomeres get shorter, a process called 
replicative or cellular aging. Some have likened this progressive erosion of 
telomeres to a genetic biological clock that winds down over time, leading 
to a gradual decline in our mental and physical prowess. Yet, C. elegans, a 
tiny creature, which spends the better part of its adult life without a 
single dividing cell in its body, still shows signs of old age and 
eventually dies, raising intriguing questions.

Are telomeres in non-dividing cells eroding slowly over time? If so, will 
worms with longer telomeres live longer? If not, how do worm cells and by 
extension non-dividing human cells, such as nerve cells, keep track of their 
biological age? To answer these vexing questions, Karlseder, who is 
interested in telomeres, teamed up with Dillin, who studies lifespan and 
aging in C. elegans.

Researchers use this 1 millimeter-long soil roundworm that feeds on bacteria 
mainly because it is simple, easy to grow in bulk populations, and is quite 
convenient for genetic analysis.

When these scientists began their work almost nothing was known about worm 
telomeres. "We had to start at the very beginning. But now we know that C. 
elegans is the perfect model organism to study telomere biology since their 
regulation is similar to human telomeres," says first author Marcela Raices, 
a post-doctoral researcher in Karlseder's lab.

Many cells in our body keep dividing throughout life (e.g., those that line 
our digestive tract, blood, and immune cells) because they must be replaced 
over time. When these cells' telomeres reach a critically short length, 
however, they can no longer replicate. The cell's structure and function 
begin to fail as it enters this state of growth arrest, called replicative 
senescence.

"But even in very old people, blood cells, which divide continuously, don't 
have critically short telomeres. In humans and, as we know now, in worms, 
telomere length is certainly not a limiting factor for lifespan," says 
Karlseder.

The Salk team, which also included graduate student Hugo Maruyama, found 
that despite the close correlation of telomere length and cellular 
senescence in mammalian cells, worms with long telomeres were neither long 
lived, nor did worm populations with short telomeres exhibit a shorter life 
span. On the other hand, long-lived and short-lived mutant worms could have 
them either way without any effect on their lifespan. When Raices monitored 
telomere length over the full lifespan of worms and under stress, a 
situation reported recently at another laboratory to shorten telomeres in 
humans, she found absolutely no change.

"For successful aging you have to control both, aging in your dividing 
cells, which hinges on telomere maintenance, but also aging in your 
non-dividing cells. We thought that telomeres might play a role in the later 
but that's clearly not the case," says Dillin. "What is probably playing a 
role in the other half of aging is the insulin signaling pathway, proper 
mitochondrial function and dietary restriction," he reasons.

Several types of cells in our body, such as mature nerve cells in the brain, 
oocytes, skeletal and heart muscle cells don't actively divide but stay put 
just like the cells in adult worms.

"That makes our findings relevant for age-related decline in mental function 
and neurodegenerative diseases, such as Alzheimer's," says Karlseder. 
"Making people live longer is not enough, we want them to grow old healthy," 
he adds.

"To prevent accelerated aging in an organism, you need to have both proper 
telomere maintenance and those other genetic pathways intact," says Dillin. 
"If you wanted to develop a drug to combat aging it wouldn't be enough to 
target telomeres, you would also have to target these other genetic 
pathways."

http://www.salk.edu/news/releases/details.php?id=141



_____________________________________________________________________________________
Basie

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