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How A 'Sixth Sense' Helps Simone Biles Fly, And The Rest Of Us Walk

Simone Biles flies through the air while performing on the balance beam at the Olympics in Rio de Janeiro.
Dmitri Lovetsky
/
AP
Simone Biles flies through the air while performing on the balance beam at the Olympics in Rio de Janeiro.

A rare genetic disorder is helping scientists understand our mysterious ability to sense where we are in space, known as proprioception.

This "sixth sense" is what dancers and gymnasts rely on to tell them the exact position of their body and limbs at every moment. It also tells them how much force each muscle is exerting.

"The most beautiful demonstration of proprioception in action is Simone Biles when she is spinning and somersaulting through the air," says Carsten Bonnemann, a pediatrician and geneticist at the National institute of Neurological Disorders and Stroke.

Scientists have known about proprioception for more than a century. But they didn't realize how much people depend on it until they got a chance to study two young patients with a rare genetic disorder that leaves them completely lacking this sense.

The results of that study were published Wednesday in the New England Journal of Medicine.

One of the participants in the study was a 10-year-old girl named Damiana, who lives in San Diego.

She's "a happy and bubbly" kid who has no problems with senses like taste, hearing, sight and smell, Bonnemann says. But Damiana was born with a genetic mutation that left her with a limited sense of touch and no proprioception, he says.

When Damiana was younger, her condition baffled doctors, says her mother, Diana Sawyer.

"She was very late at doing everything," Sawyer says. Her daughter didn't start crawling until she was about 18 months old. And she still can walk only a few steps on her own.

Damiana was born with some abnormalities in her feet and hips, Sawyer says. And her spine was curved. But those problems didn't explain why her daughter had so much trouble with precise movements, like fastening a button.

Damiana's condition might have remained a mystery if Bonnemann hadn't seen her a few years ago while holding a clinic in San Diego.

He was puzzled by her symptoms and ordered a state-of-the-art genetic analysis. It turned up a mutation in a gene called PIEZO2, which allows certain cells to detect mechanical pressure.

Unfortunately, "I didn't know what PIEZO2 was, really," Bonnemann says.

Then one day Bonnemann heard about a colleague at the National Institutes of Health who knew a lot about PIEZO2. "It turns out he's in the same building, just a floor down," Bonnemann says. "So I sent him an email saying, 'Can you help me?' "

The colleague was Alex Chesler from the National Center for Complementary and Integrative Health. Chesler read the email from Bonnemann, "and 30 seconds later I was up in his office," he says.

Chesler had spent years studying PIEZO2 in mice. But he'd never had a good way to study its function in people.

So last year, Bonnemann, Chesler and a team of researchers invited Damiana and another patient with a similar PIEZO2 mutation to the NIH.

The visit was a revelation. Trying to understand proprioception from mouse experiments had been a bit like trying to understand Beethoven by reading sheet music, Chesler says. "But when I talked to the patients it was like going to the symphony," he says.

The researchers were able to show that the PIEZO2 gene is involved in certain kinds of touch sensation as well as proprioception. And they learned a lot about what proprioception makes possible by studying what the patients were unable to do.

"They've never run, they've never jumped," Chesler says, "because those kind of actions really require precise control over your limbs in space."

The scientists also discovered that both patients had found ways to compensate for their lack of body awareness — mostly by closely watching their own limbs as they move.

For example, the older patient, who is in college, has even learned to walk pretty well — as long as she can see what's she's doing.

"If you take away her vision, she literally crumples to the ground," he says. "And the same is true for reaching. When she reaches for an object under visual control she is actually quite precise doing that. If we cover her eyes, she gets completely off target."

Of course, gymnasts like Simone Biles also rely on vision during a routine, Bonnemann says. But it's the extra information from their "sixth sense" that makes a gold-medal performance possible.

Copyright 2020 NPR. To see more, visit https://www.npr.org.

Jon Hamilton is a correspondent for NPR's Science Desk. Currently he focuses on neuroscience and health risks.