Researchers have discovered a gene that appears to be critical for maintaining a healthy sense of balance in mice. The study, led by a team at Washington University School of Medicine in St. Louis, appears in the April 1 issue of the journal Human Molecular Genetics and online March 24. “Loss of balance is a significant problem in the elderly because it can lead to dangerous falls and injuries,” says one of the study’s principal investigators, David M. Ornitz, M.D., Ph.D., professor of molecular biology and pharmacology at the School of Medicine. “Loss of balance also is a problem for astronauts following exposure to zero gravity. Now that we’ve discovered this new gene, we can begin to understand the mechanisms that allow the body to sense gravity and maintain balance.” From the Washington University School of Medicine :
Researchers discover gene that contributes to sense of balance
St. Louis, March 24, 2003 — Researchers have discovered a gene that appears to be critical for maintaining a healthy sense of balance in mice. The study, led by a team at Washington University School of Medicine in St. Louis, appears in the April 1 issue of the journal Human Molecular Genetics and online March 24.
“Loss of balance is a significant problem in the elderly because it can lead to dangerous falls and injuries,” says one of the study’s principal investigators, David M. Ornitz, M.D., Ph.D., professor of molecular biology and pharmacology at the School of Medicine. “Loss of balance also is a problem for astronauts following exposure to zero gravity. Now that we’ve discovered this new gene, we can begin to understand the mechanisms that allow the body to sense gravity and maintain balance.”
Balance is determined and regulated by the vestibular system, which is housed in the inner ear. To detect gravity, a cluster of particles called otoconia rests atop hair cells lining the inner ear. Like a water buoy guided by the movement of waves, otoconia are displaced as the body moves. As otoconia move, they shift the hair cells, which triggers the cells to send messages to the brain.
Studies suggest that otoconia are only produced during development, and that they progressively degrade throughout life. Scientists believe otoconia become eroded during normal aging, which can lead to balance disorders. But little is understood about how otoconia develop, and whether it may be possible to stimulate the production or regeneration of these particles.
Ornitz’s team genetically analyzed two strains of mice tilted (tlt) and mergulhador (mlh) known to have problems with balance. These mice walk with their heads tilted and have trouble orienting themselves in water but have no hearing problems. Moreover, they are missing their otoconia but have normal sensory hair cells. The team discovered that the two strains both have a mutation in the same previously unidentified gene, which the researchers named Otopetrin 1 or Otop1 (“oto” means “ear” and “petra” means “stone”).
“It’s possible that this is one of the genes that shuts down after development,” Ornitz says. “It also is possible that it is involved in a variety of vestibular disorders. If we can find a way to reactivate this gene, we may be able to help otoconia regenerate and thereby treat or prevent balance disorders.”
The study’s other principal investigators are Isolde Thalmann, Ph.D., research professor of otolaryngology, and Ruediger Thalmann, M.D., professor emiriti of otolaryngology. Postdoctoral fellow Belen Hurle, Ph.D., was first author. The School of Medicine team worked in collaboration with researchers at the University of S?o Paulo, Brazil.
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Hurle B, Ignatova E, Massironi SM, Mashimo T, Rios X, Thalmann I, Thalmann R, Ornitz DM. Non-syndromic vestibular disorder with otoconial agenesis in Tilted mice caused by mutations in otopetrin 1. Human Molecular Genetics, April 1, 2003.
Funding from the National Institutes of Health supported this research.
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