Parallel fiber (PF) synapses show pronounced and lasting facilitation during bursts of high-frequency activity. They typically connect to their target neurons via a single active zone (AZ), harboring few release sites (~2–8) with moderate initial vesicular release probability (~0.2–0.4). In light of these biophysical characteristics, it seems surprising that PF synapses can sustain facilitation during high-frequency periods of tens of action potentials (APs). Recent findings suggest an increase in the number of occupied release sites due to ultra-rapid (~180 s−1), Ca2+ dependent recruitment of synaptic vesicles (SVs) from replenishment sites as major presynaptic mechanism of this lasting facilitation. On the molecular level, Synaptotagmin 7 or Munc13s have been suggested to be involved in mediating facilitation at PF synapses. The recruitment of SVs from replenishment sites appears to be reversible on a slower time-scale, thereby, explaining that PF synapses rapidly depress and ultimately become silent during low-frequency activity. Hence, PF synapses show high-frequency facilitation (HFF) but low-frequency depression (LFD). This behavior is explained by regulation of the number of occupied release sites at the AZ by AP frequency.
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机译:平行纤维(PF)突触在高频活动爆发期间显示出明显且持久的促进作用。它们通常通过单个活动区(AZ)连接到其目标神经元,具有少量释放位点(〜2–8),初始囊泡释放率中等(〜0.2–0.4)。鉴于这些生物物理特征,令人惊讶的是,PF突触在数十个动作电位(AP)的高频期间可以维持促进作用。最近的发现表明,由于超快速(〜180 s −1 ),Ca 2 + 依赖性突触小泡(SVs)募集而导致的释放释放位点数量增加来自补给部位的这种持久促进的主要突触前机制。在分子水平上,Synaptotagmin 7或Munc13s被认为参与了PF突触的介导促进作用。从补给站募集SV似乎在较慢的时间范围内是可逆的,从而解释了PF突触在低频活动中迅速抑制并最终变得沉默。因此,PF突触显示高频促进(HFF)但低频抑制(LFD)。通过用AP频率调节AZ上释放释放位点的数量来解释此行为。
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