Investigating Outer Hair Cell Motility with a Combination of External Alternating Electrical Field Stimulation and High-speed Image Analysis
Summary
A reliable method to investigate outer hair cell (OHC) motile responses, including electromotility, slow motility and bending, is described. OHC motility is elicited by stimulation with an external alternating electrical field, and the method takes advantage of high-speed image recording, LED-based illumination, and last generation image analysis software.
Abstract
OHCs are cylindrical sensorimotor cells located in the Organ of Corti, the auditory organ inside the mammalian inner ear. The name “hair cells” derives from their characteristic apical bundle of stereocilia, a critical element for detection and transduction of sound energy 1. OHCs are able to change shape —elongate, shorten and bend— in response to electrical, mechanical and chemical stimulation, a motor response considered crucial for cochlear amplification of acoustic signals 2.
OHC stimulation induces two different motile responses: i) electromotility, a.k.a fast motility, changes in length in the microsecond range derived from electrically-driven conformational changes in motor proteins densely packed in OHC plasma membrane, and ii) slow motility, shape changes in the millisecond to seconds range involving cytoskeletal reorganization 2, 3. OHC bending is associated with electromotility, and result either from an asymmetric distribution of motor proteins in the lateral plasma membrane, or asymmetric electrical stimulation of those motor proteins (e.g., with an electrical field perpendicular to the long axis of the cells) 4. Mechanical and chemical stimuli induce essentially slow motile responses, even though changes in the ionic conditions of the cells and/or their environment can also stimulate the plasma membrane-embedded motor proteins 5, 6. Since OHC motile responses are an essential component of the cochlear amplifier, the qualitative and quantitative analysis of these motile responses at acoustic frequencies (roughly from 20 Hz to 20 kHz in humans) is a very important matter in the field of hearing research 7.
The development of new imaging technology combining high-speed videocameras, LED-based illumination systems, and sophisticated image analysis software now provides the ability to perform reliable qualitative and quantitative studies of the motile response of isolated OHCs to an external alternating electrical field (EAEF) 8. This is a simple and non-invasive technique that circumvents most of the limitations of previous approaches 9-11. Moreover, the LED-based illumination system provides extreme brightness with insignificant thermal effects on the samples and, because of the use of video microscopy, optical resolution is at least 10-fold higher than with conventional light microscopy techniques 12. For instance, with the experimental setup described here, changes in cell length of about 20 nm can be routinely and reliably detected at frequencies of 10 kHz, and this resolution can be further improved at lower frequencies.
We are confident that this experimental approach will help to extend our understanding of the cellular and molecular mechanisms underlying OHC motility.
Protocol
Discussion
The experimental method presented here enables estimating OHC motile responses in the kHz range without any restriction to the cell’s movement. Different stimulation protocols, additional markers (microspheres), as well changes in the orientation of the cell with respect to the electric field, make it possible to investigate new aspects of OHC motility with a level of detail previously inaccessible. Other methods, e.g. those using photodiodes 9 or laser Doppler vibrometry 10, require a tight control…
Disclosures
The authors have nothing to disclose.
Acknowledgements
Work supported by National Institutes of Health Grants R01DC10146/R01DC010397, NIDCD P30 DC006276 Research Core, and HEI. Its content is solely responsibility of the authors and do not necessarily represent the official views of NIH or HEI. The authors declare no existing or potential conflict of interest.
Materials
| Name of the reagent | Company | Catalogue number | Comments (optional) |
| Leibovitz’s L-15 | Gibco | 21083 | |
| Collagenase (Type 4) | Sigma-Aldrich | C5138 | 1mg/mL in L-15 |
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