Posts tagged hair cells
Articles and news from the latest research reports.
Innate ability to vocalize: Deaf or not, courting male mice make same sounds
Scientists have long thought mice might be a model for how humans learn to vocalize. But new research led by scientists at Washington State University Vancouver has found that, unlike humans and songbirds, mice do not learn to vocalize.
The results, published in the Journal of Neuroscience, point the way to a more finely focused, genetic tool for teasing out the mysteries of speech and its disorders.
To see if mice learn to vocalize, WSU neurophysiologist Christine Portfors destroyed the ear hair cells in more than a dozen newborn male mice. The cells convert sound waves into electrical signals processed by the brain, making hearing possible.
The deaf mice were then raised with hearing mice in a normal social environment.
Portfors and her fellow researchers, including WSU graduate student Elena Mahrt, used males because they are particularly exuberant vocalizers in the presence of females.
"We can elicit vocalization behavior in males really easily by just putting them with a female,” Portfors said. "They vocalize like crazy.”
And it turned out that it didn’t matter if the mouse was deaf or not. The researchers catalogued essentially the same suite of ultrasonic sounds from both the deaf and hearing mice. “It means that they don’t need to hear to be able to produce their sounds, their vocalizations,” Portfors said. “Basically, they don’t need to hear themselves. They don’t need auditory feedback. They don’t need to learn.”
The finding means mice are out as a model to study vocal learning. However, scientists can now focus on the mouse to learn the genetic mechanism behind communication disorders.
"If you don’t have learning as a variable, you can look at the genetic control of these things,” Portfors said. "You can look at the genetic control of the output of the signal. It’s not messed up by an animal that’s been in a particular learning situation.”
(Image: Fotolia)
For scientists who study the genetics of hearing and deafness, finding the exact genetic machinery in the inner ear that responds to sound waves and converts them into electrical impulses, the language of the brain, has been something of a holy grail.
Now this quest has come to fruition. Scientists at The Scripps Research Institute (TSRI) in La Jolla, CA, have identified a critical component of this ear-to-brain conversion—a protein called TMHS. This protein is a component of the so-called mechanotransduction channels in the ear, which convert the signals from mechanical sound waves into electrical impulses transmitted to the nervous system.
“Scientists have been trying for decades to identify the proteins that form mechanotransduction channels,” said Ulrich Mueller, PhD, a professor in the Department of Cell Biology and director of the Dorris Neuroscience Center at TSRI who led the new study, described in the December 7, 2012 issue of the journal Cell.
Not only have the scientists finally found a key protein in this process, but the work also suggests a promising new approach toward gene therapy. In the laboratory, the scientists were able to place functional TMHS into the sensory cells for sound perception of newborn deaf mice, restoring their function. “In some forms of human deafness, there may be a way to stick these genes back in and fix the cells after birth,” said Mueller.
TMHS appears to be the direct link between the spring-like mechanism in the inner ear that responds to sound and the machinery that shoots electrical signals to the brain. When the protein is missing in mice, these signals are not sent to their brains and they cannot perceive sound.
Specific genetic forms of this protein have previously been found in people with common inherited forms of deafness, and this discovery would seem to be the first explanation for how these genetic variations account for hearing loss.