Utility of red‐light ultrafast optogenetic stimulation of the auditory pathway

Utility of red‐light ultrafast optogenetic stimulation of the auditory pathway

Optogenetic stimulation of spiral ganglion neurons (SGNs) in the ear provides a future alternative to electrical stimulation used in current cochlear implants. Here, we employed fast and very fast variants of the red‐light‐activated channelrhodopsin (ChR) Chrimson (f‐Chrimson and vf‐Chrimson) to stu...

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Bibliographic Details
Published in:EMBO molecular medicine Vol. 13; no. 6; pp. e13391 - n/a
Main Authors: Bali, Burak, Lopez de la Morena, David, Mittring, Artur, Mager, Thomas, Rankovic, Vladan, Huet, Antoine Tarquin, Moser, Tobias
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 07-06-2021
EMBO Press
John Wiley and Sons Inc
Springer Nature
Subjects:
Acoustics
channelrhodopsin
Cochlea
cochlear implant
Cochlear implants
Deafness
dynamic range
Electrical stimuli
EMBO27
EMBO41
Firing rate
gating
Light
Localization
Neural coding
Physiology
Plasma
Spiral ganglion
temporal coding
Transplants & implants
gating
dynamic range
spiral ganglion
channelrhodopsin
cochlear implant
temporal coding
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Summary:Optogenetic stimulation of spiral ganglion neurons (SGNs) in the ear provides a future alternative to electrical stimulation used in current cochlear implants. Here, we employed fast and very fast variants of the red‐light‐activated channelrhodopsin (ChR) Chrimson (f‐Chrimson and vf‐Chrimson) to study their utility for optogenetic stimulation of SGNs in mice. The light requirements were higher for vf‐Chrimson than for f‐Chrimson, even when optimizing membrane expression of vf‐Chrimson by adding potassium channel trafficking sequences. Optogenetic time and intensity coding by single putative SGNs were compared with coding of acoustic clicks. vf‐Chrimson enabled putative SGNs to fire at near‐physiological rates with good temporal precision up to 250 Hz of stimulation. The dynamic range of SGN spike rate coding upon optogenetic stimulation was narrower than for acoustic clicks but larger than reported for electrical stimulation. The dynamic range of spike timing, on the other hand, was more comparable for optogenetic and acoustic stimulation. In conclusion, f‐Chrimson and vf‐Chrimson are promising candidates for optogenetic stimulation of SGNs in auditory research and future cochlear implants. Synopsis Identifying suitable channelrhodopsins is crucial for future optogenetic restoration of sound encoding by optical cochlear implants. Here, fast and very fast light‐activated Chrimsons were compared for their utility to optogenetically encode timing and intensity information in the auditory nerve. Very fast Chrimson increases temporal fidelity but confers lower light sensitivity of optogenetic auditory nerve fiber stimulation compared with fast Chrimson. Adding trafficking sequences of the inwardly rectifying potassium channel 2.1 improved plasma membrane expression of very fast Chrimson enabling shorter stimulus durations The dynamic range, based on the discharge rate, of optogenetic auditory nerve fiber stimulation was narrower than that of acoustic stimulation. The dynamic range, based on temporal precision of spiking, of optogenetic auditory nerve fiber stimulation was broader than that based on discharge rate. Graphical Abstract Identifying suitable channelrhodopsins is crucial for future optogenetic restoration of sound encoding by optical cochlear implants. Here, fast and very fast light‐activated Chrimson were compared for their utility to optogenetically encode timing and intensity information in the auditory nerve.
Bibliography:These authors contributed equally to this work
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ISSN:1757-4676
1757-4684
DOI:10.15252/emmm.202013391