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功能性甘氨酸转运体2存在与缺失时的甘氨酸能传递:来自听觉脑干的经验教训

Glycinergic Transmission in the Presence and Absence of Functional GlyT2: Lessons From the Auditory Brainstem.

作者信息

Brill Sina E, Maraslioglu Ayse, Kurz Catharina, Kramer Florian, Fuhr Martin F, Singh Abhyudai, Friauf Eckhard

机构信息

Animal Physiology Group, Department of Biology, University of Kaiserslautern, Kaiserslautern, Germany.

Electrical & Computer Engineering, University of Delaware, Newark, DE, United States.

出版信息

Front Synaptic Neurosci. 2021 Feb 9;12:560008. doi: 10.3389/fnsyn.2020.560008. eCollection 2020.

DOI:10.3389/fnsyn.2020.560008
PMID:33633558
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7900164/
Abstract

Synaptic transmission is controlled by re-uptake systems that reduce transmitter concentrations in the synaptic cleft and recycle the transmitter into presynaptic terminals. The re-uptake systems are thought to ensure cytosolic concentrations in the terminals that are sufficient for reloading empty synaptic vesicles (SVs). Genetic deletion of glycine transporter 2 (GlyT2) results in severely disrupted inhibitory neurotransmission and ultimately to death. Here we investigated the role of GlyT2 at inhibitory glycinergic synapses in the mammalian auditory brainstem. These synapses are tuned for resilience, reliability, and precision, even during sustained high-frequency stimulation when endocytosis and refilling of SVs probably contribute substantially to efficient replenishment of the readily releasable pool (). Such robust synapses are formed between MNTB and LSO neurons (medial nucleus of the trapezoid body, lateral superior olive). By means of patch-clamp recordings, we assessed the synaptic performance in controls, in GlyT2 knockout mice (KOs), and upon acute pharmacological GlyT2 blockade. Via computational modeling, we calculated the reoccupation rate of empty release sites and replenishment kinetics during 60-s challenge and 60-s recovery periods. Control MNTB-LSO inputs maintained high fidelity neurotransmission at 50 Hz for 60 s and recovered very efficiently from synaptic depression. During 'marathon-experiments' (30,600 stimuli in 20 min), replenishment accumulated to 1,260-fold. In contrast, KO inputs featured severe impairments. For example, the input number was reduced to ~1 (vs. ~4 in controls), implying massive functional degeneration of the MNTB-LSO microcircuit and a role of GlyT2 during synapse maturation. Surprisingly, neurotransmission did not collapse completely in KOs as inputs still replenished their small 80-fold upon 50 Hz | 60 s challenge. However, they totally failed to do so for extended periods. Upon acute pharmacological GlyT2 inactivation, synaptic performance remained robust, in stark contrast to KOs. replenishment was 865-fold in marathon-experiments, only ~1/3 lower than in controls. Collectively, our empirical and modeling results demonstrate that GlyT2 re-uptake activity is not the dominant factor in the SV recycling pathway that imparts indefatigability to MNTB-LSO synapses. We postulate that additional glycine sources, possibly the antiporter Asc-1, contribute to replenishment at these high-fidelity brainstem synapses.

摘要

突触传递受再摄取系统控制,该系统可降低突触间隙中的递质浓度,并将递质循环回突触前终末。再摄取系统被认为可确保终末中的胞质浓度足以重新装载空的突触小泡(SVs)。甘氨酸转运体2(GlyT2)的基因缺失会导致抑制性神经传递严重受损并最终导致死亡。在此,我们研究了GlyT2在哺乳动物听觉脑干抑制性甘氨酸能突触中的作用。即使在持续高频刺激期间,当SVs的内吞作用和重新填充可能对快速释放池的有效补充有很大贡献时,这些突触仍能保持弹性、可靠性和精确性。这种强大的突触形成于斜方体内侧核(MNTB)和外侧上橄榄核(LSO)神经元之间。通过膜片钳记录,我们评估了对照组、GlyT2基因敲除小鼠(KOs)以及急性药理学阻断GlyT2后的突触功能。通过计算建模,我们计算了在60秒刺激期和60秒恢复期内空释放位点的重新占据率和补充动力学。对照MNTB-LSO输入在50 Hz频率下持续60秒保持高保真神经传递,并能非常有效地从突触抑制中恢复。在“马拉松实验”(20分钟内30,600次刺激)中,补充累积达到1,260倍。相比之下,KO输入表现出严重损伤。例如,输入数量减少到约1个(对照组约为4个),这意味着MNTB-LSO微电路发生了大量功能性退化,以及GlyT2在突触成熟过程中的作用。令人惊讶的是,KO中的神经传递并未完全崩溃,因为在50 Hz | 60秒刺激下,输入仍能将其少量递质补充80倍。然而,在较长时间内它们完全无法做到这一点。急性药理学失活GlyT2后,突触功能保持强大,这与KO形成鲜明对比。在马拉松实验中,补充为865倍,仅比对照组低约1/3。总体而言,我们的实验和建模结果表明,GlyT2的再摄取活性不是赋予MNTB-LSO突触抗疲劳能力的SV循环途径中的主导因素。我们推测,其他甘氨酸来源,可能是反向转运体Asc-1,有助于这些高保真脑干突触的补充。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9b70/7900164/358e2469fa25/fnsyn-12-560008-g0014.jpg
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