Few Ca(V)1.3 channels regulate the exocytosis of a synaptic vesicle at the hair cell ribbon synapse

2005 | journal article; research paper. A publication with affiliation to the University of Göttingen.

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​Few Ca(V)1.3 channels regulate the exocytosis of a synaptic vesicle at the hair cell ribbon synapse​
Brandt, A. ; Khimich, D.   & Moser, T. ​ (2005) 
The Journal of neuroscience25(50) pp. 11577​-11585​.​ DOI: https://doi.org/10.1523/JNEUROSCI.3411-05.2005 

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Authors
Brandt, Andreas ; Khimich, Darina ; Moser, Tobias 
Abstract
Hearing relies on faithful sound coding at hair cell ribbon synapses, which use Ca2+-triggered glutamate release to signal with submillisecond precision. Here, we investigated stimulus-secretion coupling at mammalian inner hair cell (IHC) synapses to explore the mechanisms underlying this high temporal fidelity. Using nonstationary fluctuation analysis on Ca2+ tail currents, we estimate that IHCs contain similar to 1700 Ca2+ channels, mainly of Ca(V)1.3 type. We show by immunohistochemistry that the Ca(V)1.3 Ca2+ channels are localized preferentially at the ribbon-type active zones of IHCs. We argue that each active zone holds similar to 80 Ca2+ channels, of which probably < 10 open simultaneously during physiological stimulation. We then manipulated the Ca2+ current by primarily changing single-channel current or open-channel number. Effects on exocytosis of the readily releasable vesicle pool (RRP) were monitored by membrane capacitance recordings. Consistent with the high intrinsic Ca2+ cooperativity of exocytosis, RRP exocytosis changed nonlinearly with the Ca2+ current when varying the single-channel current. In contrast, the apparent Ca2+ cooperativity of RRP exocytosis was close to unity when primarily manipulating the number of open channels. Our findings suggest a Ca2+ channel-release site coupling in which few nearby Ca(V)1.3 channels impose high nanodomain [Ca2+] on release sites in IHCs during physiological stimulation. We postulate that the IHC ribbon synapse uses this Ca2+ nanodomain control of exocytosis to signal with high temporal precision already at low sound intensities.
Issue Date
2005
Publisher
Soc Neuroscience
Journal
The Journal of neuroscience 
ISSN
0270-6474

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