去极化
膜电位
突触小泡
生物物理学
超极化(物理学)
胞吐
小泡
林蛙
神经传递
受体电位
电生理学
神经科学
生物
化学
解剖
膜
受体
生物化学
核磁共振波谱
有机化学
作者
Mark A. Rutherford,William M. Roberts
标识
DOI:10.1073/pnas.0511005103
摘要
The ability to respond selectively to particular frequency components of sensory inputs is fundamental to signal processing in the ear. The frog ( Rana pipiens ) sacculus, which is used for social communication and escape behaviors, is an exquisitely sensitive detector of sounds and ground-borne vibrations in the 5- to 200-Hz range, with most afferent axons having best frequencies between 40 and 60 Hz. We monitored the synaptic output of saccular sensory receptors (hair cells) by measuring the increase in membrane capacitance (Δ C m ) that occurs when synaptic vesicles fuse with the plasmalemma. Strong stepwise depolarization evoked an exocytic burst that lasted 10 ms and corresponded to the predicted capacitance of all docked vesicles at synapses, followed by a 20-ms delay before additional vesicle fusion. Experiments using weak stimuli, within the normal physiological range for these cells, revealed a sensitivity to the temporal pattern of membrane potential changes. Interrupting a weak depolarization with a properly timed hyperpolarization increased Δ C m . Small sinusoidal voltage oscillations (±5 mV centered at −60 mV) evoked a Δ C m that corresponded to 95 vesicles per s at each synapse at 50 Hz but only 26 vesicles per s at 5 Hz and 27 vesicles per s at 200 Hz (perforated patch recordings). This frequency selectivity was absent for larger sinusoidal oscillations (±10 mV centered at −55 mV) and was largest for hair cells with the smallest sinusoidal-stimuli-evoked Ca 2+ currents. We conclude that frog saccular hair cells possess an intrinsic synaptic frequency selectivity that is saturated by strong stimuli.
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