Abstract
BackgroundNoise-induced hearing loss represents a commonly diagnosed type of hearing disability, severely impacting the quality of life of individuals. The current work is aimed at assessing the effects of DNA methylation on noise-induced hearing loss.MethodsBlocking DNA methyltransferase 1 (DNMT1) activity with a selective inhibitor RG108 or silencing DNMT1 with siRNA was used in this study. Auditory brainstem responses were measured at baseline and 2 days after trauma in mice to assess auditory functions. Whole-mount immunofluorescent staining and confocal microcopy of mouse inner ear specimens were performed to analyze noise-induced damage in cochleae and the auditory nerve at 2 days after noise exposure.ResultsThe results showed that noise exposure caused threshold elevation of auditory brainstem responses and cochlear hair cell loss. Whole-mount cochlea staining revealed a reduction in the density of auditory ribbon synapses between inner hair cells and spiral ganglion neurons. Inhibition of DNA methyltransferase activity via a non-nucleoside specific pharmacological inhibitor, RG108, or silencing of DNA methyltransferase-1 with siRNA significantly attenuated ABR threshold elevation, hair cell damage, and the loss of auditory synapses.ConclusionsThis study suggests that inhibition of DNMT1 ameliorates noise-induced hearing loss and indicates that DNMT1 may be a promising therapeutic target.Graphical abstractGraphical Headlights• RG108 protected against noise-induced hearing loss• RG108 administration protected against noise-induced hair cell loss and auditory neural damage.• RG108 administration attenuated oxidative stress-induced DNA damage and subsequent apoptosis-mediated cell loss in the cochlea after noise exposure.
Highlights
Noise-induced hearing loss represents a commonly diagnosed type of hearing disability, severely impacting the quality of life of individuals
The results showed that noise exposure caused threshold elevation of auditory brainstem responses and cochlear hair cell loss
Whole-mount cochlea staining revealed a reduction in the density of auditory ribbon synapses between inner hair cells and spiral ganglion neurons
Summary
Noise-induced hearing loss represents a commonly diagnosed type of hearing disability, severely impacting the quality of life of individuals. Noise-induced hearing loss (NIHL) represents an important health challenge significantly affecting the quality of life of individuals and imposing a substantial burden on the society. Permanent NIHL is due to loss of cochlear hair cells (HCs), outer hair cells (OHCs) (Kurabi et al 2017; Le Prell et al 2007; Sha and Schacht 2017). Sensory HCs in the inner ear normally convert mechanical sound stimuli into receptor potentials, and HC damage is the primary event in hearing loss. Excessive noise results in irreversible damage to inner ear sensory HCs and induces irreversible hearing loss, because cochlear HCs are unable to spontaneously regenerate in adult mammalian organisms.
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