Abstract
Noise induced hearing loss (NIHL) is a disease that affects millions of Americans. Identifying genetic pathways that influence recovery from noise exposure is an important step forward in understanding NIHL. The transcription factor Foxo3 integrates the cellular response to oxidative stress and plays a role in extending lifespan in many organisms, including humans. Here we show that Foxo3 is required for auditory function after noise exposure in a mouse model system, measured by ABR. Absent Foxo3, outer hair cells are lost throughout the middle and higher frequencies. SEM reveals persistent damage to some surviving outer hair cell stereocilia. However, DPOAE analysis reveals that some function is preserved in low frequency outer hair cells, despite concomitant profound hearing loss. Inner hair cells, auditory synapses and spiral ganglion neurons are all present after noise exposure in the Foxo3KO/KO fourteen days post noise (DPN). We also report anti-Foxo3 immunofluorescence in adult human outer hair cells. Taken together, these data implicate Foxo3 and its transcriptional targets in outer hair cell survival after noise damage. An additional role for Foxo3 in preserving hearing is likely, as low frequency auditory function is absent in noise exposed Foxo3KO/KOs even though all cells and structures are present.
Highlights
Noise induced hearing loss (NIHL) presents a significant social burden for millions of Americans[1]
To determine if cochlear function is protected by Forkhead Box O3 (FOXO3), we exposed Foxo3+/+ FVB/n and Foxo3KO/KO littermates for 30 minutes to an octave band of noise centered at 12 kHz and presented at 105 dB SPL
We show that the transcription factor FOXO3 is required for auditory function in all frequencies tested after noise exposure in mice
Summary
Noise induced hearing loss (NIHL) presents a significant social burden for millions of Americans[1]. Intense low frequency noise can drive the loss of outer hair cells[7], reducing acoustic amplification and raising thresholds[8]. Noise may drive neurite swelling and eliminate auditory synapses in high-frequency inner hair cells[10]. Some of this damage can be blocked by glutamatergic inhibitors[11], suggesting that excitotoxic signaling by inner hair cells plays a role. Administration of the NAD+ precursor nicotinamide riboside promotes sirtuin activity, and reduces NIHL threshold shifts and neurite degeneration in a Sirt3-dependent manner[16]. Taken together, these results suggest that genetic variation may partly underlie the diverse human susceptibility to NIHL13.
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