Posts tagged sensory hair cells
Articles and news from the latest research reports.
Now hear this: Researchers identify forerunners of inner-ear cells that enable hearing
Researchers at the Stanford University School of Medicine have identified a group of progenitor cells in the inner ear that can become the sensory hair cells and adjacent supporting cells that enable hearing. Studying these progenitor cells could someday lead to discoveries that help millions of Americans suffering from hearing loss due to damaged or impaired sensory hair cells.
“It’s well known that, in mammals, these specialized sensory cells don’t regenerate after damage,” said Alan Cheng, MD, assistant professor of otolaryngology. (In contrast, birds and fish are much better equipped: They can regain their sensory cells after trauma caused by noise or certain drugs.) “Identifying the progenitor cells, and the cues that trigger them to become sensory cells, will allow us to better understand not just how the inner ear develops, but also how to devise new ways to treat hearing loss and deafness.”
The research was published online Feb. 26 in Development. Cheng is the senior author. Former medical student Taha Jan, MD, and postdoctoral scholar Renjie Chai, PhD, share lead authorship of the study. Roel Nusse, PhD, a professor of developmental biology, is a co-senior author of the research.
The inner ear is a highly specialized structure for gathering and transmitting vibrations in the air. The auditory compartment, called the cochlea, is a snail-shaped cavity that houses specialized cells with hair-like projections that sense vibration, much like seaweed waving in the ocean current. These hair cells are responsible for both hearing and balance, and are surrounded by supporting cells that are also critical for hearing.
Twenty percent of all Americans, and up to 33 percent of those ages 65-74, suffer from hearing loss. Hearing aids and, in severe cases, cochlear implants can be helpful for many people, but neither address the underlying cause: the loss of hair cells in the inner ear. Cheng and his colleagues identified a class of cells called tympanic border cells that can give rise to hair cells and the cells that support them during a phase of cochlear maturation right after birth.
“Until now, these cells have had no clear function,” said Cheng. “We used several techniques to define their behavior in cell culture dishes, as well as in mice. I hope these findings will lead to new areas of research to better understand how our ears develop and perhaps new ways to stimulate the regeneration of sensory cells in the cochlea.”
Scientists prevent development of deafness in animals engineered to have Usher syndrome
Hearing impairment is the most common sensory disorder, with congenital hearing impairment present in approximately 1 in 1,000 newborns, and yet there is no physiological cure for children who are born deaf. Most cases of congenital deafness are due to a mutation in a gene that is required for normal development of the sensory hair cells in the inner ear that are responsible for detecting sound. To cure deafness caused by such mutations, the expression of the gene must be corrected, a feat that has been elusive until recently.
Rosalind Franklin University of Medicine and Science (RFUMS) Assistant Professor Michelle Hastings and her team, along with investigators at Louisiana State University Health Sciences Center in New Orleans, Louisiana and Isis Pharmaceuticals in Carlsbad, CA, have now found a way to target gene expression in the ear and rescue hearing and balance in mice that have a mutation that causes deafness in humans. The results of the study are reported in the paper, Rescue of hearing and vestibular function in a mouse model of human deafness, which was published February 4, 2013 in the journal Nature Medicine.
Dr. Hastings collaborated with research leaders across the country, including RFUMS colleagues Francine Jodelka and Anthony Hinrich, who were co-first authors on the study, as well as Dr. Dominik Duelli and Kate McCaffrey; co-first author Dr. Jennifer Lentz at Louisiana State University Health Sciences Center New Orleans, and Dr. Lentz’s research team, including Drs. Hamilton Farris and Nicolas Bazan and Matthew Spalitta; and Dr. Frank Rigo at Isis Pharmaceuticals. The collaboration led to the development of a novel therapeutic approach to treat deafness and balance impairment by injecting mice with a single dose of a small, synthetic RNA-like molecule, called an antisense oligonucleotide (ASO). The ASO was designed to specifically recognize and fix a mutation in a gene called USH1C, that causes Usher syndrome in humans. The ASO blocks the effect of the mutation, allowing the gene product to function properly, thereby preventing deafness.
Usher syndrome is the leading genetic cause of combined deafness and blindness in humans. Treatment of these Usher mice with the ASO early in life rescues hearing and cures all balance problems. “The effectiveness of the ASO is striking,” states Hastings. “A single dose of the drug to newborn mice corrects balance problems and allows these otherwise deaf mice to hear at levels similar to non-Usher mice for a large portion of their life,” she says.
Validating ASO efficacy in the Usher mice is an important step in the process of developing the strategy for human therapy. Dr. Lentz, who has been studying Usher syndrome for almost 10 years and engineered the mice to model the human disease, states, “Successfully treating a human genetic disease in this animal model brings the possibility of treating patients much closer.”
The results of the study demonstrate the therapeutic potential of this type of ASO in the treatment of deafness and provide evidence that congenital deafness can be effectively overcome by treatment early in development to correct gene expression.
"The discovery of an ASO-type drug that can effectively rescue hearing opens the door to developing similar approaches to target and cure other causes of hearing loss," says Dr. Hastings who has been awarded a grant from the National Institute of Health to further develop the ASOs for the treatment of deafness with Drs. Lentz, Rigo and Duelli.
(Source: eurekalert.org)
Mass. Eye and Ear Researchers Regenerate Sensory Hair Cells, Restore Hearing to Noise-Damaged Ears
Hearing loss is a significant public health problem affecting almost 50 million people in the United States alone. Sensorineural hearing loss is the most common form and is caused by the loss of sensory hair cells in the cochlea. Hair cell loss results from a variety of factors including noise exposure, aging, toxins, infections, and certain antibiotics and anti-cancer drugs. Although hearing aids and cochlear implants can ameliorate the symptoms somewhat, there are no known treatments to restore hearing, because auditory hair cells in mammals, unlike those in birds or fish, do not regenerate once lost. Auditory hair cell replacement holds great promise as a treatment that could restore hearing after loss of hair cells.
In the Jan. 10 issue of Neuron, Massachusetts Eye and Ear and Harvard Medical School researchers demonstrate for the first time that hair cells can be regenerated in an adult mammalian ear by using a drug to stimulate resident cells to become new hair cells, resulting in partial recovery of hearing in mouse ears damaged by noise trauma. This finding holds great potential for future therapeutic application that may someday reverse deafness in humans.
“Hair cells are the primary receptor cells for sound and are responsible for the sense of hearing,” explains senior author, Dr. Albert Edge, of Harvard Medical School and Mass. Eye and Ear. “We show that hair cells can be generated in a damaged cochlea and that hair cell replacement leads to an improvement in hearing.”
In the experiment, the researchers applied a drug to the cochlea of deaf mice. The drug had been selected for its ability to generate hair cells when added to stem cells isolated from the ear. It acted by inhibiting an enzyme called gamma-secretase that activates a number of cellular pathways. The drug applied to the cochlea inhibited a signal generated by a protein called Notch on the surface of cells that surround hair cells. These supporting cells turned into new hair cells upon treatment with the drug. Replacing hair cells improved hearing in the mice, and the improved hearing could be traced to the areas in which supporting cells had become new hair cells.
“The missing hair cells had been replaced by new hair cells after the drug treatment, and analysis of their location allowed us to correlate the improvement in hearing to the areas where the hair cells were replaced,” Dr. Edge said.
This is the first demonstration of hair cell regeneration in an adult mammal. “We’re excited about these results because they are a step forward in the biology of regeneration and prove that mammalian hair cells have the capacity to regenerate,” Dr. Edge said. “With more research, we think that regeneration of hair cells opens the door to potential therapeutic applications in deafness.”