Study Examines Approaches for Long-Term Hearing Loss Treatment

Approximately 430 million people globally suffer from disabling hearing loss, and in the United States alone, around 37.5 million adults report difficulty hearing. Hearing loss can occur when any part of the ear or the nerves that transmit sound to the brain do not function properly.

For example, damage to the hair cells in the inner ear can lead to hearing loss. According to Dr. Amrita Iyer, a researcher at Baylor College of Medicine and lead author of a new study published in eLife, “these cells allow the brain to detect sounds.”

Hair cells are generated during normal development but this ability is progressively lost after birth as mammals mature. “When hair cells are lost in mature animals, the cells cannot be naturally regenerated, which can lead to permanent hearing loss,” Iyer explained. “In the current study, we looked closer into the possibility of promoting hair cell regeneration in mature animals using cell reprogramming. Our approach involved the overexpression of various transcription factor combinations.”

Transcription factors promote the expression of certain genes and prevent the expression of others. By changing the pattern of gene expression, the researchers hoped to lead cells to a state in which they would regenerate hair cells in mature animals similar to what happens during development.

“We compared the reprogramming efficiency of the hair cell transcription factor ATOH1 alone or in combination with two other hair cell transcription factors, GFI1 and POU4F3, in mouse non-sensory cells in the cochlea, the part of the inner ear that supports hearing,” Iyer said. “We did this at two timepoints – eight days after birth and 15 days after birth, assessing the extent of hair cell regeneration in mice.”

To study the structure of the hair cell bundles generated by reprogramming, Iyer collaborated with Dr. Yeohash Raphael’s lab at the University of Michigan to perform scanning electron microscopy imaging on the cochleae of mice conditionally overexpressing these transcription factors. The images clearly showed that the hair cell bundles were in accordance with what is observed on inner hair cells during development. Further studies showed that these cells also had some characteristics that suggested that they were capable of sensing sound.

“We found that although expressing ATOH1 with hair cell transcription factors GFI1 and POU4F3 can increase the efficiency of hair cell reprogramming in older animals compared to ATOH1 alone or GFI1 plus ATOH1, the hair cells generated by reprogramming at eight days of age – even with three hair cell transcription factors – are significantly less mature than those generated by reprogramming at postnatal day one,” Iyer said. “We suggest that reprogramming with multiple transcription factors is better able to access the hair cell differentiation gene regulatory network, but that additional interventions may be necessary to produce mature and fully functional hair cells.”

These findings are key to advancing the existing understanding of the mammalian inner ear hair cell regeneration process. From a therapeutic standpoint, transcription factor-mediated reprogramming and the underlying biology associated with its function may enable fine-tuning of current gene therapy approaches for long-term hearing loss treatment.

Article originally published on SciTechDaily