Kirischuk Sergei, Grantyn Rosemarie
Developmental Physiology, Johannes Müller Institute of Physiology, Humboldt University Medical School (Charité), 10117 Berlin, Germany.
J Physiol. 2003 May 1;548(Pt 3):753-64. doi: 10.1113/jphysiol.2002.037036. Epub 2003 Mar 14.
Neurotransmitter release in response to a single action potential has a precise time course. A significant fraction of the releasable vesicles is exocytosed synchronously, within a few milliseconds after the arrival of an action potential. If repeatedly activated, stimulus-locked phasic synchronous release declines, but synaptic transmission can be maintained through tonic asynchronous transmitter release. The desynchronisation of release during repetitive activation is generally attributed to a build-up of intraterminal Ca2+ concentration. However, the precise relationship between presynaptic Ca2+ level and asynchronous release rate at small central synapses has remained unclear. Here we characterise this relationship for single GABAergic terminals in rat collicular cultures. In the presence of tetrodotoxin, inhibitory postsynaptic currents (IPSCs) and presynaptic Ca2+ transients were recorded in response to direct presynaptic depolarisation of individual boutons. Repetitive stimulation indeed resulted in a shift from phasic to asynchronous neurotransmitter release. A clear dominance of the asynchronous release mode was observed after 10 pulses. The steady-state asynchronous release rate showed a third-power dependency on the presynaptic Ca2+ concentration, which is similar to that of evoked release. The Ca2+ sensor for asynchronous release exhibited a high affinity for Ca2+ and was far from saturation. These properties of the Ca2+ sensor should make the asynchronous release very sensitive to any modification of presynaptic Ca2+ concentration, including those resulting from changes in presynaptic activity patterns. Thus, asynchronous release represents a powerful but delicately regulated mechanism that ensures the maintenance of appropriate inhibition when the readily releasable pool of vesicles is depleted.
神经递质对单个动作电位的释放具有精确的时间进程。在动作电位到达后的几毫秒内,相当一部分可释放囊泡会同步胞吐。如果反复激活,刺激锁定的相位同步释放会下降,但突触传递可通过持续性异步递质释放得以维持。重复激活期间释放的去同步化通常归因于终末内Ca2+浓度的累积。然而,在小型中枢突触处,突触前Ca2+水平与异步释放速率之间的确切关系仍不清楚。在此,我们对大鼠视丘培养物中的单个GABA能终末的这种关系进行了表征。在存在河豚毒素的情况下,记录了对单个终扣进行直接突触前去极化时的抑制性突触后电流(IPSCs)和突触前Ca2+瞬变。重复刺激确实导致了从相位性递质释放向异步递质释放的转变。在10个脉冲后观察到异步释放模式明显占主导。稳态异步释放速率显示出对突触前Ca2+浓度的三次方依赖性,这与诱发释放的情况类似。用于异步释放的Ca2+传感器对Ca2+具有高亲和力且远未饱和。Ca2+传感器的这些特性应使异步释放对突触前Ca2+浓度的任何改变都非常敏感——包括那些由突触前活动模式变化导致的改变。因此,异步释放代表了一种强大但精细调节的机制,可确保在易释放囊泡池耗尽时维持适当的抑制作用。