Fusion pore flux controls the rise-times of quantal synaptic responses.

IF 3.3 2区 医学 Q1 PHYSIOLOGY Journal of General Physiology Pub Date : 2024-08-05 Epub Date: 2024-06-11 DOI:10.1085/jgp.202313484
Meyer B Jackson, Chung-Wei Chiang, Jinbo Cheng
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Abstract

The release of neurotransmitter from a single synaptic vesicle generates a quantal response, which at excitatory synapses in voltage-clamped neurons is referred to as a miniature excitatory postsynaptic current (mEPSC). We analyzed mEPSCs in cultured mouse hippocampal neurons and in HEK cells expressing postsynaptic proteins enabling them to receive synaptic inputs from cocultured neurons. mEPSC amplitudes and rise-times varied widely within and between cells. In neurons, mEPSCs with larger amplitudes had longer rise-times, and this correlation was stronger in neurons with longer mean rise-times. In HEK cells, this correlation was weak and unclear. Standard mechanisms thought to govern mEPSCs cannot account for these results. We therefore developed models to simulate mEPSCs and assess their dependence on different factors. Modeling indicated that longer diffusion times for transmitters released by larger vesicles to reach more distal receptors cannot account for the correlation between rise-time and amplitude. By contrast, incorporating the vesicle size dependence of fusion pore expulsion time recapitulated experimental results well. Larger vesicles produce mEPSCs with larger amplitudes and also take more time to lose their content. Thus, fusion pore flux directly contributes to mEPSC rise-time. Variations in fusion pores account for differences among neurons, between neurons and HEK cells, and the correlation between rise-time and the slope of rise-time versus amplitude plots. Plots of mEPSC amplitude versus rise-time are sensitive to otherwise inaccessible properties of a synapse and offer investigators a means of assessing the role of fusion pores in synaptic release.

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融合孔通量控制着量子突触反应的上升时间。
单个突触小泡释放神经递质会产生量子响应,在电压钳神经元的兴奋性突触中,这种量子响应被称为微型兴奋性突触后电流(mEPSC)。我们分析了培养小鼠海马神经元和表达突触后蛋白的 HEK 细胞中的 mEPSC。在神经元中,振幅较大的 mEPSC 上升时间较长,平均上升时间较长的神经元中这种相关性更强。在 HEK 细胞中,这种相关性很弱,而且不明确。人们认为支配 mEPSC 的标准机制无法解释这些结果。因此,我们开发了模型来模拟 mEPSCs,并评估它们对不同因素的依赖性。模型显示,较大囊泡释放的递质到达较远受体的扩散时间较长,但这并不能解释上升时间与振幅之间的相关性。相比之下,融合孔排出时间与囊泡大小的关系则很好地再现了实验结果。较大的囊泡会产生振幅较大的 mEPSCs,同时也需要更多的时间来失去其内容物。因此,融合孔通量直接决定了 mEPSC 的上升时间。融合孔的变化解释了神经元之间、神经元与 HEK 细胞之间的差异,以及上升时间与上升时间与振幅曲线图斜率之间的相关性。mEPSC 振幅与上升时间的曲线图对突触的其他不可触及的特性非常敏感,为研究人员提供了一种评估融合孔在突触释放中的作用的方法。
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来源期刊
CiteScore
6.00
自引率
10.50%
发文量
88
审稿时长
6-12 weeks
期刊介绍: General physiology is the study of biological mechanisms through analytical investigations, which decipher the molecular and cellular mechanisms underlying biological function at all levels of organization. The mission of Journal of General Physiology (JGP) is to publish mechanistic and quantitative molecular and cellular physiology of the highest quality, to provide a best-in-class author experience, and to nurture future generations of independent researchers. The major emphasis is on physiological problems at the cellular and molecular level.
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