In vivo AAV9-Myo7a gene rescue restores hearing and cholinergic efferent innervation in inner hair cells
Andrew P. O’Connor, Ana E. Amariutei, Alice Zanella, Sarah A. Hool, Adam J. Carlton, Fanbo Kong, Mauricio Saenz-Roldan, Jing-Yi Jeng, Marie-José Lecomte, Stuart L. Johnson, Saaid Safieddine, Walter Marcotti
Andrew P. O’Connor, Ana E. Amariutei, Alice Zanella, Sarah A. Hool, Adam J. Carlton, Fanbo Kong, Mauricio Saenz-Roldan, Jing-Yi Jeng, Marie-José Lecomte, Stuart L. Johnson, Saaid Safieddine, Walter Marcotti
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Research Article Aging Neuroscience

In vivo AAV9-Myo7a gene rescue restores hearing and cholinergic efferent innervation in inner hair cells

Abstract

In the mammalian cochlea, sensory hair cells are crucial for the transduction of acoustic stimuli into electrical signals, which are then relayed to the central auditory pathway via spiral ganglion neuron (SGN) afferent dendrites. The SGN output is directly modulated by inhibitory cholinergic axodendritic synapses from the efferent fibers originating in the superior olivary complex. When the adult cochlea is subjected to noxious stimuli or aging, the efferent system undergoes major rewiring, such that it reestablishes direct axosomatic contacts with the inner hair cells (IHCs), which occur only transiently during prehearing stages of development. The trigger, origin, and degree of efferent plasticity in the cochlea remains largely unknown. Using functional and morphological approaches, we demonstrate that efferent plasticity in the adult cochlea occurs as a direct consequence of mechanoelectrical transducer current dysfunction. We also show that, different from prehearing stages of development, the lateral olivocochlear — but not the medial olivocochlear — efferent fibers are those that form the axosomatic synapses with the IHCs. The study also demonstrates that in vivo restoration of IHC function using AAV-Myo7a rescue reestablishes the synaptic profile of adult IHCs and improves hearing, highlighting the potential of using gene-replacement therapy for progressive hearing loss.

Authors

Andrew P. O’Connor, Ana E. Amariutei, Alice Zanella, Sarah A. Hool, Adam J. Carlton, Fanbo Kong, Mauricio Saenz-Roldan, Jing-Yi Jeng, Marie-José Lecomte, Stuart L. Johnson, Saaid Safieddine, Walter Marcotti

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Figure 7

Auditory brainstem response thresholds partially recover in Myo7afl/fl Myo15-cre+/– mice injected with AAV9-Myo7a.

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Auditory brainstem response thresholds partially recover in Myo7afl/fl M...
(A) Average ABR thresholds for click (left) and frequency-specific pure tone burst (right) stimuli recorded from Myo7afl/fl (black), Myo7afl/fl Myo15-cre+/– (red), and Myo7afl/fl Myo15-cre+/–AAV9-Myo7a (blue) mice at P48–P54. The number of mice used is shown near the data points. The dashed lines indicate the upper threshold limit used for this experiment (120 dB SPL). For click thresholds, statistical comparison is from 1-way ANOVA (Tukey’s post hoc test: P < 0.0001 between control and Myo7afl/fl Myo15-cre+/– without or with surgery; P = 0.0001 between Myo7afl/fl Myo15-cre+/– without and with surgery). For pure tone thresholds, statistical comparison is from 2-way ANOVA (Tukey’s post hoc test: P < 0.0001 for all comparisons). (B) Average ABR waveform responses at 12 kHz and using 2 stimulus intensities (95 and 110 dB SPL) relative to threshold from the 3 different mouse lines described in A. Continuous lines represent mean values, and shaded areas represent the SD. P1 and N1 indicate the positive and negative peaks of wave 1. (C) Same average ABR waveform responses as shown in B but only for the noninjected Myo7afl/fl Myo15-cre+/– and Myo7afl/fl Myo15-cre+/–AAV9-Myo7a mice to better highlight the size of wave 1. (D and E) Average amplitude (D) and latency (E) of wave 1 (from P1 to N1) for 3 conditions described in A. Please note that, due to wave 1 amplitude being zero in Myo7afl/fl Myo15-cre+/– mice (red), the latency could not be measured in E. Data in A, B, D, and E are shown as mean ± SD.