Macromolecular and electrical coupling between inner hair cells in the rodent cochlea

2020 | journal article; research paper. A publication with affiliation to the University of Göttingen.

Jump to:Cite & Linked | Documents & Media | Details | Version history

Cite this publication

​Jean, P., Anttonen, T., Michanski, S., de Diego, A. M. G., Steyer, A. M., Neef, A., Oestreicher, D. ... Moser, T. (2020). ​Macromolecular and electrical coupling between inner hair cells in the rodent cochlea. Nature Communications11(1), . ​doi: https://doi.org/10.1038/s41467-020-17003-z 

Documents & Media

License

Published Version

Attribution 4.0 CC BY 4.0

Details

Authors
Jean, Philippe; Anttonen, Tommi ; Michanski, Susann; de Diego, Antonio M. G.; Steyer, Anna M.; Neef, Andreas ; Oestreicher, David; Kroll, Jana; Nardis, Christos; Pangršič, Tina ; Möbius, Wiebke ; Ashmore, Jonathan; Wichmann, Carolin ; Moser, Tobias 
Abstract
Inner hair cells (IHCs) are the primary receptors for hearing. They are housed in the cochlea and convey sound information to the brain via synapses with the auditory nerve. IHCs have been thought to be electrically and metabolically independent from each other. We report that, upon developmental maturation, in mice 30% of the IHCs are electrochemically coupled in ‘mini-syncytia’. This coupling permits transfer of fluorescently-labeled metabolites and macromolecular tracers. The membrane capacitance, Ca2+-current, and resting current increase with the number of dye-coupled IHCs. Dual voltage-clamp experiments substantiate low resistance electrical coupling. Pharmacology and tracer permeability rule out coupling by gap junctions and purinoceptors. 3D electron microscopy indicates instead that IHCs are coupled by membrane fusion sites. Consequently, depolarization of one IHC triggers presynaptic Ca2+-influx at active zones in the entire mini-syncytium. Based on our findings and modeling, we propose that IHC-mini-syncytia enhance sensitivity and reliability of cochlear sound encoding.
Issue Date
2020
Journal
Nature Communications 
Project
EXC 2067: Multiscale Bioimaging 
Working Group
RG Moser (Molecular Anatomy, Physiology and Pathology of Sound Encoding) 
RG Möbius 
RG Pangršič Vilfan (Experimental Otology) 
RG Wichmann (Molecular Architecture of Synapses) 
eISSN
2041-1723
Language
English

Reference

Citations


Social Media