“When hearing was lost, we saw rapid changes in motor areas in that control song, the bird’s equivalent of speech,” said senior author Richard Mooney, PhD, professor of neurobiology at Duke. “This study provided a laser-like focus on what happens in the living songbird brain, narrowed down to the particular cell type involved.”
The study was published in Neuron journal online on March 7, 2012.
Like humans, songbirds depend on hearing to learn their mating songs – males that sing poorly don’t attract mates, so hearing a song, learning it, and singing correctly are all critical for songbird survival. Songbirds also resemble humans and differ from most other animals in that their songs fall apart when they lose their hearing, and this feature makes them an ideal organism to study how hearing loss may affect the parts of the brain that control vocalization, Mooney said.
“I will go out on a limb and say that I think similar changes also occur in human brains after hearing loss, specifically in Broca’s area, a part of the human brain that plays an important role in generating speech and that also receives inputs from the auditory system,” Mooney said.
About 30 million Americans are hard of hearing or deaf. This study could shed light on why and how some people’s speech changes as their hearing starts to decline, Mooney said.
“Our vocal system depends on the auditory system to create intelligible speech. When people suffer profound hearing loss, their speech often becomes hoarse, garbled, and harder to understand, so not only do they have trouble hearing, they often can’t speak fluently any more,” Mooney said.
The nerve cells that showed changes after deafening send signals to the basal ganglia, a part of the brain that plays a role in learning and initiating motor sequences, including the complex vocal sequences that make up birdsong and speech.
Although other studies had looked at the effects of deafening on neurons in auditory brain areas, this is the first time that scientists have been able to watch how deafening affects connections between nerve cells in a vocal motor area of the brain in a living animal, said Katie Tschida, PhD, a postdoctoral research associate in the Mooney laboratory who led the study.
Using a protein isolated from jellyfish that can make songbird nerve cells glow bright green when viewed under a laser-powered microscope, they were able to determine that deafening triggered rapid changes to the tiny connections between nerve cells, called synapses, which are only one thousandth of a millimeter across.
“I was very surprised that the weakening of connections between nerve cells was visible and emerged so rapidly — over the course of days these changes allowed us to predict which birds’ songs would fall apart most dramatically,” Tschida said. “Considering that we were only tracking a handful of neurons in each bird, I never thought we’d get information specific enough to predict such a thing.”
The research was supported by the National Science Foundation and the National Institute on Deafness and Other Communication Disorders.
All photos taken by Katie Tschida, Duke Department of Neurobiology