Noise induces Ca2+ signaling waves and Chop/S-Xbp1 expression in the hearing cochlea
Yesai Park, … , Elliott H. Sherr, Dylan K. Chan
Yesai Park, … , Elliott H. Sherr, Dylan K. Chan
Published December 11, 2024
Citation Information: JCI Insight. 2025;10(2):e181783. https://doi.org/10.1172/jci.insight.181783.
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Research Article Otology

Noise induces Ca2+ signaling waves and Chop/S-Xbp1 expression in the hearing cochlea

Abstract

Exposure to loud noise is a common cause of acquired hearing loss. Disruption of subcellular calcium homeostasis and downstream stress pathways in the endoplasmic reticulum and mitochondria, including the unfolded protein response (UPR), have been implicated in the pathophysiology of noise-induced hearing loss. However, studies on the association between calcium homeostasis and stress pathways have been limited due to limited ability to measure calcium dynamics in mature-hearing, noise-exposed mice. We used a genetically encoded calcium indicator mouse model in which GCaMP6f is expressed specifically in hair cells or supporting cells under control of Myo15Cre or Sox2Cre, respectively. We performed live calcium imaging and UPR gene expression analysis in 8-week-old mice exposed to levels of noise that cause cochlear synaptopathy (98 db sound pressure level [SPL]) or permanent hearing loss (106 dB SPL). UPR activation occurred immediately after noise exposure, and the pattern of UPR activation was dependent on noise level, with the proapoptotic pathway upregulated only after 106 dB noise exposure. Spontaneous calcium transients in hair cells and intercellular calcium waves in supporting cells, which are present in neonatal cochleae, were quiescent in mature-hearing cochleae but reactivated upon noise exposure. Noise exposure of 106 dB was associated with more persistent and expansive intercellular Ca2+ signaling wave activity. These findings demonstrate a strong and dose-dependent association between noise exposure, UPR activation, and changes in calcium homeostasis in hair cells and supporting cells, suggesting that targeting these pathways may be effective to develop treatments for noise-induced hearing loss.

Authors

Yesai Park, Jiang Li, Noura Ismail Mohamad, Ian R. Matthews, Peu Santra, Elliott H. Sherr, Dylan K. Chan

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Figure 7

Live imaging of Myo15Cre-GCaMP6f adult cochlea.

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Live imaging of Myo15Cre-GCaMP6f adult cochlea. (A and B) In the adult c...
(A and B) In the adult cochlea, no spontaneous Ca2+ peak activity is seen in hair cells. Though an inner-sulcus supporting cell (SC, blue) with off-target expression of GCaMP6f responded to ATP (applied after the leftmost image) with a Ca2+ peak, neither an inner hair cell (IHC, white/black) nor an outer hair cell (OHC, red) was responsive. Time interval between successive images was 8 seconds. Scale bar: 20 μm. Representative video also shown in Supplemental Video 6. (CF) Noise-induced Ca2+ transients. In fluorescence traces from OHCs from cochleae exposed to 106 dB noise, cytosolic Ca2+ transients were observed. Rise time (time from baseline to half-maximum, in seconds) (D) and decay time (C) for 20 Ca2+ transients was plotted against OHC maximum size relative to baseline, demonstrating 2 populations of transients: “slow” transients (red) that were associated with OHC swelling and fragmentation, and “fast” transients (black) that were not. Individual traces of fast (E) and slow (F) OHC transients are shown, with insets depicting still images of these events corresponding to video shown in Supplemental Video 6. Traces are normalized to maximal peak amplitude and aligned at the time of spontaneous peak initiation (E) or the time of hair cell fragmentation (F). AU, arbitrary units.