Zombie cells central to the quest for active, vital old age
This microscope photo provided by the Mayo Clinic in August shows senescent myoblast cells. Senescent cells resist apoptosis, or programmed cell death, and characteristically get big and flat, with enlarged nuclei. (Dr. Xu Zhang, Mayo Clinic via Associated Press)
Estimated read time: 9-10 minutes
CINCINNATI — In an unfinished part of his basement, 95-year-old Richard Soller zips around a makeshift track encircling boxes full of medals he’s won for track and field and long-distance running.
Without a hint of breathlessness, he says: “I can put in miles down here.”
Steps away is an expensive leather recliner he bought when he retired from Procter and Gamble with visions of relaxing into old age. He proudly proclaims he’s never used it; he’s been too busy training for competitions, such as the National Senior Games.
Soller, who lives near Cincinnati, has achieved an enviable goal chased by humans since ancient times: Staying healthy and active in late life. It’s a goal that eludes so many that growing old is often associated with getting frail and sick. But scientists are trying to change that — and tackle one of humanity’s biggest challenges — through a little known but flourishing field of aging research called cellular senescence.
It’s built upon the idea that cells eventually stop dividing and enter a “senescent” state in response to various forms of damage. The body removes most of them. But others linger like zombies. They aren’t dead. But as the Mayo Clinic’s Nathan LeBrasseur puts it, they can harm nearby cells like moldy fruit corrupting a fruit bowl. They accumulate in older bodies, which mounting evidence links to an array of age-related conditions such as dementia, cardiovascular disease and osteoporosis.
But scientists wonder: Can the zombie cell buildup be stopped?
“The ability to understand aging — and the potential to intervene in the fundamental biology of aging — is truly the greatest opportunity we have had, maybe in history, to transform human health,” LeBrasseur says. Extending the span of healthy years impacts “quality of life, public health, socioeconomics, the whole shebang.”
With the number of people 65 or older expected to double globally by 2050, cellular senescence is “a very hot topic,” says Viviana Perez Montes of the National Institutes of Health. According to an Associated Press analysis of an NIH research database, there have been around 11,500 total projects involving cellular senescence since 1985, far more in recent years.
About 100 companies, plus academic teams, are exploring drugs to target senescent cells. And research offers tantalizing clues that people may be able to help tame senescence themselves using the strategy favored by Soller: exercise.
Although no one thinks senescence holds the key to super long life, Tufts University researcher Christopher Wiley hopes for a day when fewer people suffer fates like his late grandfather, who had Alzheimer’s and stared back at him as if he were a stranger.
“I’m not looking for the fountain of youth,” Wiley says. “I’m looking for the fountain of not being sick when I’m older.”
Mortal cells
Leonard Hayflick, the scientist who discovered cellular senescence in 1960, is himself vital at 94. He’s a professor of anatomy at the University of California, San Francisco, and continues to write, present and speak on the topic.
At his seaside home in Sonoma County, he leafs through a binder filled with his research, including two early papers that have been cited an astonishing number of times by other researchers. Before him on the living room table are numerous copies of his seminal book, “How and Why We Age,” in various languages.
This scientific renown didn’t come easily. He discovered cellular senescence by accident, cultivating human fetal cells for a project on cancer biology and noticing they stopped dividing after about 50 population doublings. This wasn’t a big surprise; cell cultures often failed because of things like contamination. What was surprising was that others also stopped dividing at the same point. The phenomenon was later called “the Hayflick limit.”
The finding, Hayflick says, challenged “60-year-old dogma” that normal human cells could replicate forever. A paper he authored with colleague Paul Moorhead was rejected by a prominent scientific journal, and Hayflick faced a decade of ridicule after it was published in Experimental Cell Research in 1961.
“It followed…
Read More: Zombie cells central to the quest for active, vital old age