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  2. Proton-mediated block of Ca2+ channels during multivesicular release regulates short-term plasticity at an auditory hair cell synapse

Proton-mediated block of Ca2+ channels during multivesicular release regulates short-term plasticity at an auditory hair cell synapse

  • J Neurosci. 2014 Nov 26;34(48):15877-87. doi: 10.1523/JNEUROSCI.2304-14.2014.
Soyoun Cho 1 Henrique von Gersdorff 2
Affiliations

Affiliations

  • 1 The Vollum Institute, Oregon Health & Science University, Portland, Oregon 97239.
  • 2 The Vollum Institute, Oregon Health & Science University, Portland, Oregon 97239 vongersd@ohsu.edu.
Abstract

Synaptic vesicles release both neurotransmitter and protons during exocytosis, which may result in a transient acidification of the synaptic cleft that can block CA(2+) channels located close to the sites of exocytosis. Evidence for this effect has been reported for retinal ribbon-type synapses, but not for hair cell ribbon synapses. Here, we report evidence for proton release from bullfrog auditory hair cells when they are held at more physiological, in vivo-like holding potentials (Vh = -60 mV) that facilitate multivesicular release. During paired recordings of hair cells and afferent fibers, L-type voltage-gated CA(2+) currents showed a transient block, which was highly correlated with the EPSC amplitude (or the amount of glutamate release). This effect was masked at Vh = -90 mV due to the presence of a T-type CA(2+) current and blocked by strong pH buffering with HEPES or TABS. Increasing vesicular pH with internal methylamine in hair cells also abolished the transient block. High concentrations of intracellular CA(2+) buffer (10 mm BAPTA) greatly reduced exocytosis and abolished the transient block of the CA(2+) current. We estimate that this transient block is due to the rapid multivesicular release of ∼600-1300 H(+) ions per synaptic ribbon. Finally, during a train of depolarizing pulses, paired pulse plasticity was significantly changed by using 40 mm HEPES in addition to bicarbonate buffer. We propose that this transient block of CA(2+) current leads to more efficient exocytosis per CA(2+) ion influx and it may contribute to spike adaptation at the auditory nerve.

Keywords

auditory; calcium current; electrophysiology; exocytosis; hair cells; protons.

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